Accepted papers to appear in an upcoming issue
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Highly efficient optical parametric amplifier tunablefrom near-IR to mid-IR for driving extreme nonlinearoptics in solids
Ekaterina Migal, Fedor Potemkin, and Viacheslav Gordienko
Doc ID: 308899 Received 10 Oct 2017; Accepted 20 Nov 2017; Posted 20 Nov 2017 View: PDF
Abstract: We have developed the robust optical parametric amplifier (OPA) based on three AGS crystals pumping by Cr:Forsterite GW femtosecond laser system and generating 150-fs pulses in dual bands 1.6-2.0 µm (signal wave) and 3.5-5.5 µm (idler wave). Introducing negative prechirp to the pump, combined efficiency in two waves more than 10% was achieved with signal energy up to 110 μJ around 1.9 µm and idler energy up to 43 μJ in the vicinity of 4 μm. Operation parameters of the system (intensity up to 90 TW/cm2) makes OPA a promising tool for driving nonlinear optical phenomena including generation of optical harmonics and laser-induced extreme states of matter in solids and liquids. As a proof of principal, we generated high harmonics and sum frequencies in 5 mm thick polycrystalline ZnSe.
Flexible design method for freeform lenses with an arbitrary lens contour
Karel Desnijder, Peter Hanselaer, and Youri Meuret
Doc ID: 308074 Received 04 Oct 2017; Accepted 19 Nov 2017; Posted 20 Nov 2017 View: PDF
Abstract: A method is presented that allows to design freeform lenses with an arbitrary contour in a flexible and robust manner. The method is based on the generation of two equi-flux grids representing the source and target beams, with two separate curl-free mappings from an equi-spatial rectangular grid. Because the source and target grids are generated independently from one another, one can map arbitrary complex source beams with a certain contour onto arbitrary complex target beams within another contour, with high convergence probability. The method is illustrated by calculating a triangular freeform lens that reshapes a triangular beam from a Lambertian source into a uniform pentagonal irradiance distribution on a target plane.
Efficient diode-pumped Er:KLu(WO4)2 laser at ~1.61 µm
Josep Maria Serres, Pavel Loiko, Venkatesan Jambunathan, Xavier Mateos, Vladimir Vitkin, Antonio Lucianetti, Tomas Mocek, Magdalena Aguilo, Francesc Diaz, Uwe Griebner, and Valentin Petrov
Doc ID: 309941 Received 25 Oct 2017; Accepted 19 Nov 2017; Posted 20 Nov 2017 View: PDF
Abstract: We report on an efficient diode-pumped continuous-wave Erbium-doped monoclinic double tungstate laser. It is based on a 1 at.% Er3+:KLu(WO4)2 (Er:KLuW) crystal cut along the Ng optical indicatrix axis. The Er:KLuW microchip laser, diode-pumped at 0.98 µm, generates 268 mW at 1.610 µm with a slope efficiency of 30%. The output is linearly polarized (E || Nm) and the laser beam is nearly diffraction-limited. Spectroscopic properties of Er3+ in KLuW are also presented. The maximum σSE = 3.0×10-20 cm2 is at ~1.535 µm for E || Nm. The microchip Er:KLuW laser outperforms the commercial Er,Yb:glass.
Photo-Bleaching Mechanism of BAC-Si in Bismuth/Erbium Co-Doped Optical Fiber
Mingjie Ding, Jie FANG, Yanhua Luo, Wenyu WANG, and Gang-Ding Peng
Doc ID: 308104 Received 02 Oct 2017; Accepted 18 Nov 2017; Posted 20 Nov 2017 View: PDF
Abstract: Photo-bleaching of silica related bismuth active center (BAC-Si) in bismuth/erbium co-doped optical fiber is investigated.By analyzing dynamic spectral characteristics of BAC-Si, the photo-bleaching of BAC-Si is linked to the escape of an excited electron from the bismuth site in BAC-Si.This mechanism of BAC-Si bleaching linked to an escaping excited electron is further confirmed with both the photo-bleaching experiments by different laser pump wavelengths and a potential energy model describing the loss of an excited electron.In addition, the temperature effect on the photo-bleaching, which is in good agreement with the above findings, is observed and discussed.
Modeling the sensitivity dependence of silicon-photonics-based ultrasound detectors
Shai Tsesses, Daniel Aronovich, Assaf Grinberg, Evgeny Hahamovich, and Amir Rosenthal
Doc ID: 307071 Received 13 Sep 2017; Accepted 17 Nov 2017; Posted 20 Nov 2017 View: PDF
Abstract: With recent advances in optical technology, interferometric sensing has grown into a highly versatile approach for ultrasound detection, with many interferometric detectors relying on optical waveguides to achieve high levels of sensitivity and miniaturization. In this letter, we establish a practical model for assessing the sensitivity of silicon-photonics waveguides to acoustic waves. The analysis is performed for different polarizations, waveguide dimensions, and acoustic wave types. Our model was validated experimentally, by measuring the sensitivities of the two polarization modes in a silicon strip waveguide. Both the experimental results and theoretical prediction show that the TM polarization achieves a higher sensitivity and suppression of surface acoustic waves compared to the TE polarization.
Experimental study of the mode instabilities onset threshold in high power FA-LPF lasers
Marie-Alicia Malleville, Romain Dauliat, Aurélien Benoit, Baptiste Leconte, dia darwich, Rémi du Jeu, Raphael Jamier, Kay Schuster, and Philippe Roy
Doc ID: 308250 Received 29 Sep 2017; Accepted 16 Nov 2017; Posted 16 Nov 2017 View: PDF
Abstract: We report here on an experimental investigation of the temporal behavior of transverse mode instabilities into “Fully Aperiodic Large-Pitch Fibers” (FA-LPFs) operated in high-power CW laser configuration. To ensure an effective transverse single-mode emission into FA-LPFs, a perfect index-matching between the active core and the background cladding materials (∆n=0) is required. The original design of such fibers enables an effective transverse single-mode emission by strengthening the HOMs delocalization out of the gain region even for high heat load levels, consequently leading to the improvement of the beam spatial quality. The study was conducted over fibers of various gain region diameters – from 58 to 100 µm for a refractive index mismatch ∆n of about +8×10-5. The emitted beam is characterized using both M² measurements and time traces to study the changeover of a stable temporal behavior to an unstable one.
Characterization of two ultrashort laser pulses using interferometric imaging of self-diffraction
Christoph Leithold, Jan Reislöhner, Holger Gies, and Adrian Pfeiffer
Doc ID: 307026 Received 12 Sep 2017; Accepted 16 Nov 2017; Posted 20 Nov 2017 View: PDF
Abstract: Non-collinear pulse characterization methods can be applied to over-octave spanning waveforms, but geometrical effects in the nonlinear medium like beam smearing and critical sensitivity to beam alignment hinder their accurate application. Here, a method is introduced for the temporal and spatial characterization of two pulses by interferometric, spectrally resolved imaging of self-diffraction. Geometrical effects are resolved by the method and therefore do not limit the accuracy. Two methods for quantitative pulse retrieval are presented. One method is analytical and very fast, the other method is iterative and more robust if applied to noisy data.
Effects of defocus and other quadratic errors on OTF
Kevin Liang and Miguel Alonso
Doc ID: 309409 Received 18 Oct 2017; Accepted 15 Nov 2017; Posted 20 Nov 2017 View: PDF
Abstract: Even for the simplest nontrivial aberration, defocus, and for a circular pupil, there is no theoretical closed-form expression for the optical transfer function (OTF). By using a simple approximation for the error at the pupil, we provide a simple yet accurate approximation for the OTF of a defocused system. We then generalize this approach to generic quadratic aberrations, including astigmatism.
Radiation Induced-Birefringence Variations in Polarization Maintaining Fibers
Yuanhong Yang, Hui Li, Lin Lu, Fuling Yang, and Wei Jin
Doc ID: 308149 Received 29 Sep 2017; Accepted 14 Nov 2017; Posted 20 Nov 2017 View: PDF
Abstract: Gamma radiation induced birefringence (RIB) variations in a solid core photonic crystal polarization maintaining fiber (Pc-PMF) and a Panda PMF (Pa-PMF) are investigated. Experiments show that the birefringence of the fibers changes approximately linearly with radiation dose over the range from 0 to 400 Krad(Si), with negative slope coefficients of 8.91×10¯¹⁰/Krad(Si) and 4.38×10¯⁹/Krad(Si)for the Pc-PMF and Pa-PMF, respectively. Models of RIB variations for the two fibers are established and the theoretical results agree well with the experimental ones
The Variable Stripe Length method: influence of stripe lengths choice on measured optical gain
Doc ID: 310025 Received 27 Oct 2017; Accepted 14 Nov 2017; Posted 15 Nov 2017 View: PDF
Abstract: The Variable Stripe Length (VSL) method is a very popular tool to measure the optical gain in thin film active devices. However, along the last decade experimental and theoretical evidences have been reported that cast doubts upon its reliability and that seriously discourage its application. Continuing in the path of finding new arguments against its use, this letter soundly demonstrates that the particular choice of stripe lengths in the VSL measurements profoundly influences the optical gains retrieved by this method. Thus, a single set of VSL data may render gain values differing tens of cm-1. The observed gain variability is ascribed to a combination of unavoidable experimental noise and incorrect assumptions in the analytical treatment (small-signal approximation).
Phase transition through the splitting of self-dual spectral singularity in optical potentials
Vladimir Konotop and Dmitry Zezyulin
Doc ID: 305835 Received 28 Aug 2017; Accepted 13 Nov 2017; Posted 16 Nov 2017 View: PDF
Abstract: We consider optical media which feature antilinear symmetries. We show that: (i) spectral singularities of such media (if any) are always self-dual, i.e., correspond to CPA-lasers; (ii) under the change of a system's parameter the self-dual spectral singularity may split into a pair of isolated complex conjugate eigenvalues, which corresponds to an unconventional and overlooked in the most of previous studies scenario of the phase transition (known as PT-symmetry breaking in systems obeying parity-time symmetry); (iii) if the antilinear symmetry is local, i.e., does not involve any spatial reflection, then no spectral singularity is possible. Our findings are illustrated with several examples including a PT-symmetric bilayerand other complex potentials discussed in recent literature.
Nonlinearity-aware 200-Gbit/s discrete multi-tone transmission for C-band short-reach optical interconnects with a single packaged EML
Lu Zhang, Xuezhi Hong, Xiaodan Pang, Oskars Ozolins, Aleksejs Udalcovs, Richard Schatz, Changjian Guo, Junwei Zhang, FREDRIK NORDWALL, Klaus Engenhardt, Urban Westergren, Sergei Popov, GUNNAR JACOBSEN, shilin xiao, Weisheng Hu, and Jiajia Chen
Doc ID: 306205 Received 01 Sep 2017; Accepted 13 Nov 2017; Posted 15 Nov 2017 View: PDF
Abstract: We experimentally demonstrate the transmission of 200-Gbit/s discrete multi-tone (DMT) at soft-FEC limit in an intensity-modulation direct-detection system with a single C-band packaged distributed feedback laser and traveling-wave electro absorption modulator (DFB-TWEAM), digital-to-analog converter (DAC) and photodiode. The bits and power loaded DMT signal is transmitted over 1.6 km standard single mode fiber (SSMF) with a net rate of 166.7-Gbit/s, achieving an effective electrical spectrum efficiency of 4.93 bit/s/Hz. Meanwhile, net rates of 174.2-Gbit/s and 179.5-Gbit/s are also demonstrated over 0.8km SSMF and in optical back-to-back case, respectively. The feature of the packaged DFB-TWEAM is presented. The nonlinearity-aware digital signal processing algorithm for channel equalization is mathematically described, which improves the signal-to-noise ratio up to 4 dB.
Chirped-pulse-based broadband RF channelization implemented by mode-locked laser and dispersion
Wenhui Hao, Yitang Dai, FEIFEI YIN, Yue Zhou, Jianqiang Li, Jian Dai, Wangzhe Li, and Kun Xu
Doc ID: 307824 Received 25 Sep 2017; Accepted 13 Nov 2017; Posted 15 Nov 2017 View: PDF
Abstract: Based on mode-locked laser and dispersion, a wideband radio frequency (RF) channelized receiver that can easily support hundreds of channels is proposed. By mixing a long-duration chirped pulse train and its own delayed copy, an equivalent RF local oscillation (LO) is produced which can down-convert the modulated signal to zero-intermediate-frequency (IF). The LO frequency can be changed by simply setting the delay between the two paths. Channelized receiving of broadband RF signals can be realized by parallel delay line arrays. Meanwhile, the using of in-phase/quadrature (I/Q) demodulation avoids the extra optical or electrical filtering as well as image interference. A receiver with channel spacing of 100 MHz, covering spectrum from DC to 18.4 GHz is experimentally demonstrated. The performances including signal-to- noise ratio (SNR), frequency response, spurious-free dynamic range (SFDR) and image rejection are analyzed.
Detuned Brillouin Amplification of OTDR Signals With Enhanced Signal-to-Noise Ratio
Egor Liokumovitch, Daniel Gotliv, and Shmuel Sternklar
Doc ID: 308043 Received 26 Sep 2017; Accepted 13 Nov 2017; Posted 15 Nov 2017 View: PDF
Abstract: The technique known as external Brillouin amplification of Rayleigh scattering (eBARS) is characterized in the detuning regime. When employed as an amplifier of OTDR signals, it is shown that the SNR is significantly improved for optimum pump-Stokes detuning, leading to enhanced nanostrain sensitivity. This effect is due to the Brillouin bandwidth dependence on the Stokes power.
All-fiber 2-order optical vortex generation based on strong modulated long-period grating in 4-mode fiber
Wu Hang, She Gao, Bingsen Huang, Yuanhua Feng, xincheng huang, Weiping Liu, and Zhaohui Li
Doc ID: 308683 Received 10 Oct 2017; Accepted 13 Nov 2017; Posted 15 Nov 2017 View: PDF
Abstract: We propose an effective all-fiber method to generate high-order optical vortex (OV) via twisting a strong modulated long period fiber grating (LPFG) written in a four-mode fiber (4MF). With special design and optimization of the procedures of CO2-laser irradiation, an LPFG with strong period deformation is achieved in the 4MF. Based on this LPFG, we can directly convert the linear polarization (LP) fiber fundamental mode (LP01) to the high order LP core mode (LP21) with efficiency of 99.7 percent, and then, transform the LP21 mode into high-order OV mode (±2 order). It is the first time, to the best of our knowledge, ±2-order OV modes are experimentally generated with just one fiber grating in an all-fiber-system. © 2017 Optical Society of America
Multilayered analog optical differentiating device: performance analysis on structural parameters
Wenhui Wu, Wei Jiang, Jiang Yang, Shaoxiang Gong, and Yungui Ma
Doc ID: 307048 Received 13 Sep 2017; Accepted 13 Nov 2017; Posted 20 Nov 2017 View: PDF
Abstract: Analogy optical devices with the function of mathematical computation have recently gained strong research interests due to the potential application as accelerating hardware in traditional electronic computers. The performance of these wavefront-processing devices is primarily decided by the accuracy of the engineered angular scattering spectra usually using artificial optical structures. In this paper, we address this issue through the performance analysis of an analog second-order optical differentiator made of dielectric (Si-SiO2) multilayer films that enable analytical discussions and also a combined design. The performance could be optimized according to the Fourier spectrum width of the incident light whose wavefront represents the input function. Based on this, we propose different optical differentiating devices that work for different wave input conditions. Rescaling of the Fourier spectrum intensity is suggested to enhance the fabrication and measurement error tolerance of the device. The minimum number of multilayers is also discussed in order to improve the practical feasibility. The current results are thought instrumental in guiding the design and implementation of analogy optical computation devices.
Experimental Generation of Linearly Chirped 350 GHz-band Pulses with beyond 60 GHz Bandwidth
Hangkai Zhang, Shiwei Wang, Shi Jia, Xianbin Yu, Xiaofeng Jin, Shilie Zheng, Hao Chi, and Xianmin Zhang
Doc ID: 306548 Received 07 Sep 2017; Accepted 13 Nov 2017; Posted 20 Nov 2017 View: PDF
Abstract: We present in this paper experimental generation of linear frequency modulated (LFM) THz pulses with large bandwidth by using an optical interferometer based photonic scheme and cutting-edge THz transceiver technology. The LFM pulses exhibiting a bandwidth in excess of 60 GHz centered at 350 GHz are successfully generated in the experiment, which represents the first demonstration of large time-bandwidth products (TBWP) in the THz region above 300 GHz, to the best of our knowledge. The achieved TBWP of up to 527 features a range resolution better than 1 cm and has great potential in many prospective applications such as high resolution radar sensing and imaging.
Diffraction symmetry of binary Fourier elements with feature sizes on the order of the illumination wavelength and effects of fabrication errors
Kevin Heggarty, Julien LE MEUR, Andreas Bacher, patrick Meyrueis, and Giang-Nam Nguyen
Doc ID: 297604 Received 08 Jun 2017; Accepted 13 Nov 2017; Posted 14 Nov 2017 View: PDF
Abstract: When building spot array binary Fourier Diffractive Optical Elements (DOEs) having feature sizes on the order of the wavelength, we noticed remarkable variations in the experimental diffraction efficiency compared to the simulation results. Even with the use of a high-cost Electron Beam Lithography and the rigorous Fourier Modal Method simulations, there appear to be no publications, to our knowledge, showing close agreement in diffraction efficiency between simulation and experimental results. In this letter, we show that the diffraction symmetry of binary Fourier DOEs can be an efficient and consistent metric for evaluating the limit of the Thin Element Approximation and the effects of fabrication errors.
Direct writing of plane-by-plane tilted fiber Bragg gratings using a femtosecond laser
Andreas Ioannou, Antreas Theodosiou, Christophe Caucheteur, and Kyriacos Kalli
Doc ID: 307520 Received 21 Sep 2017; Accepted 13 Nov 2017; Posted 14 Nov 2017 View: PDF
Abstract: In this letter, we report a flexible, plane-by-plane direct write inscription method for the development of tailored, tilted fiber Bragg gratings (TFBGs) using a femtosecond laser. Compared to UV- or femtosecond-laser inscription based on phase masks, interferometric or point by point methods, the presented approach is far more flexible and offers several advantages. Laser inscription is made through the fiber coating while the grating planes are controlled to minimize birefringence, with precise control over the wavelength location and strength of cladding modes. 10th order gratings were produced in the C+L bands so that higher order gratings could be studied at shorter wavelengths. In particular, we show that the refractometric sensitivity depends on the grating order, ranging from ~28 nm/RIU at ~1510 nm to ~13 nm/RIU at ~1260 nm.
Widely tunable optical parametric oscillation in a Kerr microresonator
Noel Sayson, Karen Webb, Stephane Coen, Miro Erkintalo, and Stuart Murdoch
Doc ID: 308086 Received 27 Sep 2017; Accepted 13 Nov 2017; Posted 14 Nov 2017 View: PDF
Abstract: We report on the first experimental demonstration of widely-tunable parametric sideband generation in a Kerr microresonator. Specifically, by pumping a silica microsphere in the normal dispersion regime, we achieve the generation of phase-matched four-wave mixing sidebands at large frequency detunings from the pump. Thanks to the role of higher-order dispersion in enabling phase matching, small variations of the pump wavelength translate into very large and controllable changes in the wavelengths of the generated sidebands: we experimentally demonstrate over 720 nm of tunability using a low-power continuous-wave pump laser in the C-band. We also derive simple theoretical predictions for the phase-matched sideband frequencies, and discuss the predictions in light of thediscrete cavity resonance frequencies. Our experimentally measured sideband wavelengths are in very good agreement with theoretical predictions obtained from our simple phase matching analysis.
Partially coherent diffraction-free vertex beams with Bessel-mode structure
Andrey Ostrovsky, Joaquín García, Carolina Rickenstorff, and Miguel Angel Olvera
Doc ID: 308573 Received 04 Oct 2017; Accepted 13 Nov 2017; Posted 14 Nov 2017 View: PDF
Abstract: A new family of partially coherent beams carrying optical vortices is introduced. Any member of this family represents an incoherent superposition of fully coherent Bessel modes with the same helical wave front and is notable for its diffraction-free propagation. It is shown analytically and experimentally that such beams can be approximately generated in the Fourier-transforming optical system with a computer-controlled liquid-crystal spatial light modulator.
Hilbert's Hotel in polarization singularities
Gregory Gbur and yangyundou wang
Doc ID: 308893 Received 11 Oct 2017; Accepted 13 Nov 2017; Posted 14 Nov 2017 View: PDF
Abstract: We demonstrate theoretically how the creation of polarization singularities by the evolution of a fractional nonuniform polarization optical element involves the peculiar mathematics of countably infinite sets in the form of ``Hilbert's Hotel.' Two distinct topological processes can be observed depending on the structure of the fractional optical element.
Raman Dissipative Soliton Fiber Laser Pumped by an ASE Source
Weiwei Pan, Lei Zhang, Jiaqi Zhou, Xuezong Yang, and Yan Feng
Doc ID: 309046 Received 13 Oct 2017; Accepted 13 Nov 2017; Posted 14 Nov 2017 View: PDF
Abstract: Mode locking of Raman fiber laser with an amplified spontaneous emission pump source is investigated for performance improvement. Raman dissipative solitons with pulse duration of 48 ps at a repetition rate of 2.47 MHz are generated by utilizing nonlinear polarization rotation and all-fiber Lyot filter. A signal to noise ratio as high as 85 dB is measured in radio-frequency spectrum, which suggests excellent temporal stability. Multiple pulse operation with unique random static distribution is observed for the first time at higher pump power in mode locked Raman fiber lasers.
Topological cascade laser for frequency combgeneration in PT -symmetric structures
Laura Pilozzi and Claudio Conti
Doc ID: 307825 Received 27 Sep 2017; Accepted 12 Nov 2017; Posted 13 Nov 2017 View: PDF
Abstract: The cascade of resonant PT -symmetric topologicalstructures is shown to emit laser light with a frequencycombspectrum. We consider optically active topologicallattices supporting edge-modes at regularly spacedfrequencies. When the amplified resonances in the PT -broken regime match the edge modes of the topologicalgratings, we predict the emission of discrete laserlines. A proper design enables to engineer the spectralfeatures for specific applications. Topological protectionmakes the system very well suited for a novel generationof compact frequency comb emitters for spectroscopy,metrology and quantum information.
Two-mode surface plasmon lasing in hexagonal arrays
Vasco Tenner, Michiel de Dood, and Martin van Exter
Doc ID: 297731 Received 25 Aug 2017; Accepted 12 Nov 2017; Posted 13 Nov 2017 View: PDF
Abstract: We demonstrate surface-plasmon lasing in hexagonal metal hole arrays with a semiconductor gain medium. The device can be tuned between two laser modes, with distinct wavelengths, spatial distributions and polarization patterns by changing the size of the optically pumped area. One of the modes exhibits a six-fold polarization pattern, while the mode observed for larger pump spots has a rotationally symmetric polarization pattern. We explain the mode tuning by the differences of in-plane and radiative out-of-plane losses of the modes. The spatial and polarization properties of the modes are conveniently described by a sum of vectorial OAM beams with orbital, spin and total angular momentum j = l+s.
Jones matrix microscopy from a single shot measurement
M. Sreelal, VINU RV, and Rakesh Singh
Doc ID: 309464 Received 18 Oct 2017; Accepted 12 Nov 2017; Posted 15 Nov 2017 View: PDF
Abstract: Quantitative measurement of Jones matrix elements is crucial for the study of light polarization with wide range of applications. Here, we propose and experimentally demonstrate a novel method of Fourier space sharing to determine spatially resolved all four elements of the Jones matrix from a single intensity frame. This is achieved by applying holography approach and making use of two triangular polarization Sagnac interferometers in the sample and reference arms. The proposed technique is flexible to adjust carrier frequencies in order to meet the varying demand of different anisotropic samples. Jones matrix microscopy system is developed and applied for transparent samples. Experimental implementation of the proposed technique is demonstrated by determining the Jones matrix elements of commercially available known samples and liquid crystal droplets.
Ultra-compact polarization-independent directional couplers utilizing subwavelength structures
Yaocheng Shi and Hongnan Xu
Doc ID: 309214 Received 16 Oct 2017; Accepted 11 Nov 2017; Posted 13 Nov 2017 View: PDF
Abstract: Ultra-compact polarization-independent directional couplers are proposed and demonstrated on the Silicon-On-Insulator (SOI) platform. By using the subwavelength structures in the coupling region, the coupling strength is greatly enhanced only for TE polarization, so that the coupling strength could be equivalent between TE and TM polarizations. Both complete coupling and 3-dB splitting have been demonstrated. The polarization independent coupling length is only ~ 3.75 μm. The measured excess losses and polarization dependence losses are < ~ 1 dB and < ~ 0.5 dB.
Single travelling wave-like Fabry-Perot resonator based add-drop filters for wavelength multiplexing
Qingzhong Huang, Qiang Liu, and Jinsong Xia
Doc ID: 312557 Received 03 Nov 2017; Accepted 10 Nov 2017; Posted 14 Nov 2017 View: PDF
Abstract: We have proposed and studied a novel channel add-drop filter (ADF) based on a single Fabry-Perot resonator. The resonator consists of two mode-conversion Bragg grating reflectors separated by a wide waveguide that laterally coupled to two narrow waveguides. It behaves like a travelling-wave resonator where fields are coupled to the buses in one direction. Compact and narrowband ADFs are achieved with dropping efficiencies higher than 95%, as shown by the three-dimensional finite-difference time-domain simulations. In addition, the proposed device is applied to realize an eight-channel add-drop multiplexer in the C-band by cascading the ADFs with adjusted channel wavelengths.
A self-tuning optical resonator
Joanna Zielinska and Morgan Mitchell
Doc ID: 309076 Received 13 Oct 2017; Accepted 10 Nov 2017; Posted 13 Nov 2017 View: PDF
Abstract: We demonstrate a nonlinear optical resonator that tunes itself onto resonance with an input beam. In a monolithic Fabry-Perot cavity implemented in rubidium-doped periodically-poled potassium titanyl phosphate, an intensity-dependent refractive index produces line-pulling by multiple free-spectral ranges (FSRs). In this condition, the cavity passively maintains optical resonance in the face of FSR-scale excursions of the drive laser frequency: when one resonant operating-point becomes unstable, the resonator rapidly transitions to another resonant operating point. We demonstrate stable second-harmonic generation with no active feedback to laser or cavity. The self-tuning effect appears to be supported by a very strong, previously unreported optical nonlinearity.
All-fiber interferometer-based repetition-rate stabilization of mode-locked lasers to 10¯¹⁴-level frequency instability and 1-fs-level jitter over 1-s
Dohyeon Kwon and Jungwon Kim
Doc ID: 309718 Received 30 Oct 2017; Accepted 09 Nov 2017; Posted 13 Nov 2017 View: PDF
Abstract: We report on all-fiber Michelson interferometer-based repetition-rate stabilization of femtosecond mode-locked lasers down to 1.3×10¯¹⁴ frequency instability and 1.4-fs integrated jitter in 1-s time scale. The use of a compactly packaged 10-km-long SMF-28 fiber link as a timing reference allows the scaling of phase noise down to -80 dBc/Hz at 1-Hz Fourier frequency. We also tested a 500-m-long low-thermal-sensitivity fiber as a reference and found that, compared to standard SMF-28 fiber, it can mitigate the phase noise divergence by ~10 dB/dec in the 0.1 – 1 Hz Fourier frequency range. These results suggest that the use of a longer low-thermal-sensitivity fiber may achieve sub-fs integrated timing jitter with sub-10¯¹⁴–level frequency instability in repetition-rate by a simple and robust all-fiber-photonic method.
Steering optical comb frequencies by rotating the polarization state
Yanyan Zhang, Xiao-Fei Zhang, Lulu Yan, Pan Zhang, bingjie rao, Wei Han, wenge guo, Shou-Gang Zhang, and Haifeng Jiang
Doc ID: 310117 Received 30 Oct 2017; Accepted 09 Nov 2017; Posted 13 Nov 2017 View: PDF
Abstract: We demonstrate a new approach to steer the frequencies of a nonlinear-polarization-rotation mode-locked laser, where a specially designed intra-cavity electrooptic modulator tunes the polarization state of the laser signal. Not only does this approach result in the broadband associated with high performance, but it also results in large dynamic range associated with good robustness. Our experimental results show that frequency control dynamic ranges are at least one order of magnitude than these of the previous ultra-fast frequency control techniques, reaching hundreds hertz and hundreds megahertz for repetition rate ( fr) and carrier envelop offset frequency ( fceo), respectively.
Experimental demonstration of critical coupling of whispering gallery mode cavities on Bloch surface wave platform
Babak Vosoughi Lahijani, Habib Badri Ghavifekr, Richa Dubey, Myun-Sik Kim, Ismo Vartiainen, Matthieu Roussey, and Hans Peter Herzig
Doc ID: 308726 Received 06 Oct 2017; Accepted 09 Nov 2017; Posted 13 Nov 2017 View: PDF
Abstract: We experimentally demonstrate critical coupling of whispering gallery mode (WGM) disk resonators implemented on a Bloch surface wave platform using scanning near-field optical microscopy. The studied structure is a 60-nm-thick TiO2 WGM disk cavity (radius of 100 μm) operating within the C-band telecommunication wavelengths. An extinction ratio of 26 dB and a quality factor of 2,200 are measured. Such a high extinction ratio verifies the critical coupling of the WGM resonator. This result paves the way to planar optical signal processing devices based on the proposed geometry, for which critical coupling condition is a guarantee of optimum performance.
Direct write micro/nano optical fibers by near-field melt electrospinning
Qinnan Chen, Xuecui Mei, Zhe Shen, Dezhi Wu, Yang Zhao, Lingyun Wang, Xiaojun Chen, Gonghan He, zhe yu, Ke Fang, and Daoheng Sun
Doc ID: 308151 Received 29 Sep 2017; Accepted 09 Nov 2017; Posted 09 Nov 2017 View: PDF
Abstract: A simple fabrication method of micro/nano optical fibers (MNOFs) by near-field melt electrospinning (NMES) was proposed in this paper. Single fibers with diameter ranging from 500nm to 6μm were direct written by near-field electrospinning melt Poly(methyl methacrylate) (PMMA). The morphology and transmission characteristics of single PMMA MNOFs were experimentally measured. Results showed that PMMA MNOFs have the advantages of smooth surfaces, uniform diameters, and low loss. As an example of one-step fabrication for MNOF devices, a planar helical MNOF structure was direct written and optically characterized. To demonstrate the versatility of NMES process, combined with microfluidic technique, a liquid refractive index sensing chip has been fabricated and tested. Our work has already showed the proposed fabrication method has great potential in direct-writing patterned optical devices and heterogeneous integrated devices.
Single-shot, real-time carrier-envelope phase measurement and tagging based on stereographic above-threshold ionization at short-wave Infrared wavelengths
Yinyu Zhang, Philipp Kellner, Daniel Adolph, DANILO ZILLE, Philipp Wustelt, Daniel Würzler, Slawomir Skruszewicz, Max Möller, A SAYLER, and Gerhard Paulus
Doc ID: 308653 Received 11 Oct 2017; Accepted 09 Nov 2017; Posted 09 Nov 2017 View: PDF
Abstract: A high-precision, single-shot and real-time carrier-envelope phase (CEP) measurement at 1.8 µm laser wavelength based on stereographic photoelectron spectroscopy is presented. A precision of the CEP measurement of 120 mrad for each and every individual laser shot for a 1-kHz pulse train with randomly varying CEP is demonstrated. Simultaneous to the CEP measurement, the pulse lengths are characterized by evaluating the spatial asymmetry of the measured above-threshold ionization (ATI) spectra of Xenon and referenced to a standard pulse-duration measurement based on frequency-resolved optical gating (FROG). The validity of the CEP measurement is confirmed by implementing phase-tagging for a CEP-dependent measurement of ATI in Xe with high energy resolution.
Design of nanowire-induced nanocavities in photonic crystal disks
Sylvain Sergent, Hideaki Taniyama, and Masaya Notomi
Doc ID: 308295 Received 26 Oct 2017; Accepted 08 Nov 2017; Posted 08 Nov 2017 View: PDF
Abstract: We propose a novel type of nanowire-induced nanocavity based on photonic crystal disks and we investigate its design by three-dimensional finite-difference time-domain calculations. We detail the confinement principle used in such a cavity and discuss the influence of geometric and material parameters on the cavity performance. We finally report on an optimized design presenting a quality factor Q = 7.2×10^4, a mode volume as small as Vm = 2.2 (λ/nrNW)^3 and a large confinement factor of the electric field energy in the NW Γ = 65%, which shows good prospects for the realization of efficient nanowire-based nanolasers operating in the ultraviolet and visible ranges.
A hybrid unidirectional meta-coupler for vertical incidence to a high-refractive-index waveguide in telecom wavelength
Chensheng Gong, Sailing He, and Jianhao Zhang
Doc ID: 308591 Received 16 Oct 2017; Accepted 08 Nov 2017; Posted 08 Nov 2017 View: PDF
Abstract: A hybrid unidirectional meta-coupler for vertical incidence to a high-refractive-index waveguide in telecom wavelength is demonstrated. Phase gradient plasmonic metasurfaces composed of periodic MIM structure are used for phase matching. Three designs are given for devices working around 0.85μm, 1.31μm and 1.55μm. The simulated coupling efficiencies are all around 70% and the 1 dB coupling bandwidths are 29nm, 82nm and 105nm, respectively. Back reflections in the waveguide are also estimated to be lower than 5%. Our approach paves the way for the applications of optical metasurfaces to planar lightwave.
Great photoluminescence enhancement in Al-sputtered Zn0.78Mg0.22O films
YONGHUI ZHOU, Shanshan Chen, Xinhua Pan, and Zhizhen Ye
Doc ID: 309199 Received 17 Oct 2017; Accepted 08 Nov 2017; Posted 09 Nov 2017 View: PDF
Abstract: Zn0.78Mg0.22O thin films were grown on a-plane sapphire substrates by plasma-assisted molecular beam epitaxy. Compared with ZnO, the crystal quality of Zn0.78Mg0.22O thin films degrades significantly, which results in a low internal quantum efficiency (ηint). Besides improving the quality of Zn0.78Mg0.22O, an effective way to enhance the internal quantum efficiency and the UV emission of Zn0.78Mg0.22O by sputtering Al nanoparticles has been used. Taking advantage of the resonant coupling between UV emission of Zn0.78Mg0.22O film and Al nanoparticle surface plasmons (SPs), a 59-fold enhancement of the UV emission and a 3.5-fold enhancement of ηint have been achieved under the optimized sputtering time. Moreover, the enhancement ratio is stable after two months. It paves a facile way in fabricating high-efficiency UV optoelectronic devices.
Full-C-band Si Photonic Crystal Waveguide Modulator
Yosuke Terada, Keisuke Kondo, Ryotaro Abe, and Toshihiko Baba
Doc ID: 309778 Received 23 Oct 2017; Accepted 08 Nov 2017; Posted 09 Nov 2017 View: PDF
Abstract: The slow-light effect in silicon lattice-shifted photonic crystal waveguide (LSPCW) Mach-Zehnder modulators allows compact phase shifters while limiting the working spectrum Δλ. We optimized the structural parameters of the LSPCW and extended Δλ to cover the full C-band in exchange for moderately decreasing the group index ng. We obtained Δλ = 42 nm with ng = 8–9 in a fabricated device and observed 25-Gbps eye opening in the 200-μm modulator in the full C-band.
Quantification of laser-induced damage growth using fractal analysisQuantification of laser-induced damage growth using fractal analysis
Matthieu Veinhard, Odile Bonville, Roger Courchinoux, Romain Parreault, Jean-Yves Natoli, and Laurent Lamaignère
Doc ID: 307217 Received 21 Sep 2017; Accepted 08 Nov 2017; Posted 09 Nov 2017 View: PDF
Abstract: Lateral and longitudinal laser damage growth under subsequent irradiations at 351 nm in the nanosecond range from micrometric to millimetric scales is presented herein. Atypical behavior has been observed, showing the growth in the longitudinal direction whereas the lateral growth does not evolve. We propose the use of fractal analysis to describe the evolution of the bulk damage morphology. Results indicate first a dependence between the damage fractal dimension and the laser parameters, such as the fluence and the pulse duration. Next, it seem from observations that the damage morphology modifications drive the growth rate changes.
REDUCING LIGHT SCATTERING IN HIGH REFLECTION COATINGS THROUGH OMNIDIRECTIONALLY DESTRUCTIVE INTERFERENCE AT FULLY CORRELATED INTERFACES
Jinlong Zhang, han wu, Hongfei Jiao, Sven Schröder, Marcus Trost, Zhanshan Wang, and Xinbin Cheng
Doc ID: 308439 Received 03 Oct 2017; Accepted 07 Nov 2017; Posted 08 Nov 2017 View: PDF
Abstract: Light scattering in quarter-wave high reflection (QWHR) coatings with fully correlated interfaces was reduced by adding Fabry-Perot (FP) cavity structures on top of the multilayer. The properly designed FP cavity can induce destructive interference for fully correlated interfaces and reduce the scattering loss. Compared to QWHR coatings, adding one FP cavity could decrease the scattering at the near specular angles, and two FP cavities have the potential to reduce light scattering in a broad angular range. A low-scattering HR (LSHR) coating using two FP cavities has been realized to suppress light scattering omnidirectionally. The numerical scattering calculation illustrated that the total scattering loss of the LSHR was about two times less than that of the QWHR coatings. The measured angle resolved scattering of the LSHR coating showed a good correspondence to the numerical calculation although there exists small deviation in a limited angular range.
Refractionless propagation of discretized light
Doc ID: 308819 Received 10 Oct 2017; Accepted 07 Nov 2017; Posted 09 Nov 2017 View: PDF
Abstract: Light refraction, i.e. the bending of the path of a light wave at the interface between two different dielectric media, is ubiquitous in optics. Refraction arises from the different speed of light and is unavoidable in continuous media according to Snell's Law. Here we show rather counterintuitively that omnidirectional refractionless propagation can be observed for discretized light crossing a tilted interface separating two homogeneous waveguide lattices.
1.25 GHz sine wave gating InGaAs/InP single-photon detector with monolithically integrated readout circuit
Wen-Hao Jiang, Jianhong Liu, Y. Liu, Ge Jin, Jun Zhang, and Jian-Wei Pan
Doc ID: 304580 Received 10 Aug 2017; Accepted 07 Nov 2017; Posted 07 Nov 2017 View: PDF
Abstract: InGaAs/InP single-photon detectors (SPDs) are the key devices for applications requiring near-infrared single-photon detection. Gating mode is an effective approach to synchronous single-photon detection. Increasing gating frequency and reducing size are important challenges for the design of such detector system. Here we present for the first time an InGaAs/InP SPD with 1.25 GHz sine wave gating using a monolithically integrated readout circuit (MIRC). The MIRC has a size of 15 mm × 15 mm and implements the miniaturization of quenching electronics for high-frequency sine wave gating. In the MIRC, low-pass filters and a low-noise radio frequency amplifier are integrated based on the technique of low temperature co-fired ceramic, which can effectively reduce the parasitic capacitance and extract weak avalanche signals. We then characterize the key parameters of InGaAs/InP SPD to verify the functionality of MIRC, and the SPD exhibits excellent performance with 27.5 % photon detection efficiency, 1.2 kcps dark count rate, and 9.1 % afterpulse probability at 2 K and 100 ns hold-off time. With this MIRC, one can further design miniaturized high-speed InGaAs/InP SPDs highly required for practical applications.
A photonics-based multi-function analog signal processor based on a polarization division multiplexing Mach-Zehnder modulator
Shilong Pan and Yamei Zhang
Doc ID: 304769 Received 18 Aug 2017; Accepted 06 Nov 2017; Posted 07 Nov 2017 View: PDF
Abstract: A photonics-based multi-function analog signal processor based on an optical polarization division multiplexing (PDM) dual-parallel Mach-Zehnder modulator (DPMZM) is proposed and demonstrated, which can implement simultaneously photonic microwave phase shifting, up-/down-conversion and filtering with excellent tunability. An experiment is carried out. Down-converted and up-converted phase shifters with phases continuously tuned from -180 to 180 degree over 0-11 GHz and 11-33 GHz are implemented. Based on the frequency-mixed phase shifter, a 4-tap microwave photonic filter (MPF) that has the capability to select a frequency-mixed component is built. The proposed approach features multi-function, scalable independent channels, wide bandwidth and high tunability, which can find applications in beamforming networks, RF frontends, and radio over fiber systems.
Effects of defocus on the transfer function of coherence scanning interferometry
Rong Su, MATTHEW THOMAS, Richard Leach, and Jeremy Coupland
Doc ID: 304940 Received 17 Aug 2017; Accepted 06 Nov 2017; Posted 07 Nov 2017 View: PDF
Abstract: Coherence scanning interferometry (CSI) offers three dimensional (3D) measurement of surface topography with high precision and accuracy. Defocus within the interferometric objective lens, however, is commonly present in CSI measurements, and reduces both the resolving power of the imaging system and the ability to measure tilted surfaces. This paper extends the linear theory of CSI to consider the effects of defocus on the 3D transfer function and the point spread function in an otherwise ideal CSI instrument. The results are compared with measurements of these functions in a real instrument. This work provides further evidence for the validity of the linear systems theory of CSI.
Spatiotemporal diffraction-free pulsed beams infree-space of the Airy and Bessel type
Doc ID: 305329 Received 22 Aug 2017; Accepted 06 Nov 2017; Posted 07 Nov 2017 View: PDF
Abstract: We investigate the dynamics of spatiotemporal optical waves with one transverse dimension that are obtained as the intersections of the dispersion cone with a plane. We show that, by appropriate spectral excitations, the three different types of conic sections (elliptic, parabolic, and hyperbolic) can lead to optical waves of the Bessel, Airy, and modified Bessel type, respectively. We find closed form solutions that accurately describe the wave dynamics and unveil their fundamental properties.
On-chip Brillouin purification for frequency comb-based coherent optical communications
Amol Choudhary, Mark Pelusi, David Marpaung, Takashi Inoue, Khu Vu, Pan Ma, Duk-Yong Choi, Stephen Madden, Shu Namiki, and Benjamin Eggleton
Doc ID: 306263 Received 05 Sep 2017; Accepted 06 Nov 2017; Posted 07 Nov 2017 View: PDF
Abstract: In this paper, we for the first time harness on-chip Brillouin scattering for narrowband amplification and spectral purification of frequency comb lines for coherent optical communications. A parametrically-generated optical frequency comb with a low carrier to noise power ratio was filtered through narrowband Brillouin amplification utilizing the same comb as the re-circulated optical pump. This was achieved on a photonic chip to enable successful transmission of an advanced modulation format signal: 64-level quadrature amplitude modulation (QAM). 96 Gigabits/second data was modulated on two polarizations on multiple comb-lines across 1532.9-1557.5 nm demonstrating the scalability of this concept for operation in wavelength division multiplexing applications. The small form-factor of the photonic chip reduces the polarization drifts when compared to optical fibers and paves the way for photonic integration.
On Babinet’s Principle and Diffraction Associated with an Arbitrary Particle
Bingqiang Sun, Ping Yang, George Kattawar, and Michael Mishchenko
Doc ID: 307984 Received 26 Sep 2017; Accepted 06 Nov 2017; Posted 07 Nov 2017 View: PDF
Abstract: Babinet’s principle is widely used to compute the diffraction by a particle. However, the diffraction by a 3-D object is not totally the same as that simulated with Babinet’s principle. This letter uses a surface integral equation to exactly formulate the diffraction by an arbitrary particle and illustrates the condition for the applicability of Babinet’s principle. The present results may serve to close the debate on the diffraction formalism.
Fiber-optic radio frequency transfer based on active phase noise compensation using a carrier suppressed double-sideband signal
Jiapeng Zhang, Guiling Wu, Tiancheng Lin, and Jianping Chen
Doc ID: 306605 Received 08 Sep 2017; Accepted 06 Nov 2017; Posted 08 Nov 2017 View: PDF
Abstract: In this letter, we propose a fiber-optic radio frequency (RF) transfer based on active phase noise compensation adopting a carrier suppressed double-sideband (CSDSB) signal. The forward CSDSB signal is generated based on the transmitted RF signal at the local site to discriminate from the backward RF signal. The forward and backward signals are transmitted over the same fiber with the same wavelength to guarantee the bidirectional propagation symmetry. The impact of backscattering is efficiently suppressed by electrical filtering at sites. A 1 GHz signal transfer over a 40 km optical link is performed in laboratory. The results show that the proposed scheme can improve the short term stability from 1.9e-13 /s to 3.9e-14 /s in contrast to the scheme with backscattering while reaching a long term stability of 2.0e-16 /10000s.
Generation of uniformly oriented in-plane magnetization with near-unity purity in 4π microscopy
Xiangping Li, Sicong Wang, and Yao-Yu Cao
Doc ID: 305222 Received 21 Aug 2017; Accepted 06 Nov 2017; Posted 09 Nov 2017 View: PDF
Abstract: In this Letter, we numerically demonstrate the all-optical generation of uniformly oriented in-plane magnetization with near-unity purity (more than 99%) under a 4π microscopic configuration. This is achieved through focusing two counter-propagating vector beams consisting of coherently configured linear and radial components. Based on the Richards and Wolf diffraction theory, constructive and destructive interferences of the focal field components can be tailored under the 4π configuration to generate high-purity uniformly polarized transverse and longitudinal electric-field components in the center of the focal region. Consequently, near-unity purity in-plane magnetization with a uniform orientation within the focal volume defined by the full width at half maximum can be created through the inverse Faraday effect. In addition, it reveals that the purity of the in-plane magnetization is robust against the numerical aperture of the focal lens. This result expands the flexibility of magnetization manipulations through light and holds great potentials in all-optical magnetic recording and spintronics.
Perfect Broad-Band Invisibility in Isotropic Media with Gain and Loss
Farhang Loran and Ali Mostafazadeh
Doc ID: 305770 Received 28 Aug 2017; Accepted 06 Nov 2017; Posted 13 Nov 2017 View: PDF
Abstract: We offer a simple route to perfect omnidirectional invisibility in a spectral band of desired width which is based on the observation that in two dimensions a complex potential v(x,y) is invisible for incident plane waves with a wavenumber not exceeding a preassigned value α provided that its Fourier transform with respect to y, which we denote by $\tilde v(x,K_y)$, vanishes for $K_y ≤ 2α$. We can fulfil this condition for potentials modelling the permittivity profile of an optical slab. Such a slab is perfectly invisible for any transverse electric wave whose wavenumber is in the range [0,α]. Our results also apply to transverse magnetic waves propagating in a medium with a relative permittivity that is a smooth bounded function with a positive real part.
Wavefront-sensing with a thin diffuser
Marc Guillon, Pascal Berto, and Herve Rigneault
Doc ID: 308993 Received 11 Oct 2017; Accepted 05 Nov 2017; Posted 09 Nov 2017 View: PDF
Abstract: We propose and implement a broadband, compact, and low-cost wavefront sensing scheme by simply placing a thin diffuser in the close vicinity of a camera. The local wavefront gradient is determined from the local translation of the speckle pattern. The translation vector map is computed thanks to a fast diffeomorphic image registration algorithm and integrated to reconstruct the wavefront profile. The simple translation of speckle grains under local wavefront tip/tilt is ensured by the so-called ``memory effect' of the diffuser. Quantitative wavefront measurements are experimentally demonstrated both for the few first Zernike polynomials and for phase-imaging applications requiring high resolution. We finally provided a theoretical description of the resolution limit that is supported experimentally.
A Fan-Beam Steering Device Using a Photonic Crystal Slow-Light Waveguide with Surface Diffraction Grating
Keisuke Kondo, Tomoki Tatebe, Shoji Hachuda, Hiroshi Abe, Fumio Koyama, and Toshihiko Baba
Doc ID: 309774 Received 23 Oct 2017; Accepted 05 Nov 2017; Posted 06 Nov 2017 View: PDF
Abstract: Compact non-mechanical beam steering devices are desired not only for current common applications but also for advanced applications such as light detection and ranging. We use a Si photonic crystal slow-light waveguide with a diffraction grating, which radiates the guided mode to free space and steers a fan beam by sweeping the wavelength. Due to its large angular dispersion, slow light enhances the steering range without degrading the beam quality, resulting in more resolution points. We fabricated 600-μm devices and observed a ⁰ steering range and a beam divergence of 0. ⁰, which resulted in 100 resolution points.
Enhancement of bulk second-harmonic generation from silicon nitride films by material composition
Kalle Koskinen, Robert Czaplicki, Abdallah Slablab, Tingyin Ning, Artur Hermans, Bart Kuyken, Vinita Mittal, Ganapathy Senthil Murugan, Tapio Niemi, Roel G. Baets, and Martti Kauranen
Doc ID: 307991 Received 26 Sep 2017; Accepted 05 Nov 2017; Posted 07 Nov 2017 View: PDF
Abstract: We present a comprehensive tensorial characterization of second-harmonic generation from silicon nitride films with varying composition. The samples were fabricated using plasma-enhanced chemical vapor deposition, and the material composition was varied by the reactive gas mixture in the process. We found a six-fold enhancement between the lowest and highest second-order susceptibility, with the highest value of approximately 5 pm/V from the most silicon-rich sample. Moreover, the optical losses were found to be sufficiently small (below 6 dB/cm) for applications. The tensorial results show that all samples retain in-plane isotropy independent of silicon content, highlighting the controllability of the fabrication process.
Micro-Scale Roughening of Glass Substrates Using Carbon Nanotube-Driven Templates for Enhancements in White Luminescence Characteristics
Jin Woo Jang, Oh Hyeon Kwon, Jun Sik Kim, Yuri Kim, and Yong Soo Cho
Doc ID: 308041 Received 27 Sep 2017; Accepted 05 Nov 2017; Posted 07 Nov 2017 View: PDF
Abstract: A novel way of roughening the surface of a glass substrate using a carbon nanotube (CNT)-driven template is introduced to enhance white luminescence characteristics of a printed (Ba,Sr,Ca)2SiO4:Eu2+ yellow silicate phosphor layer. The distribution of closed pores in the template layer induces the selective etching and the micro-scale roughening. As a result, a substantial improvement of ~22.5% in the luminous efficacy was achieved when both sides of the substrate were roughened. This is attributed to the reductions of both the total internal reflection of rays at the glass–air interface and the specular reflection at the phosphor-glass interface.
All-optical control of ultrahigh-Q silica microcavities with iron oxide nanoparticles
Song Zhu, Lei Shi, Shixing Yuan, xinbiao xu, and Xinliang Zhang
Doc ID: 306923 Received 11 Sep 2017; Accepted 04 Nov 2017; Posted 06 Nov 2017 View: PDF
Abstract: The first all-optical control scheme of ultrahigh-quality (Q)-factor silica microcavities, which can maintain their Q factors over 108 during the tuning process, is proposed and experimentally demonstrated. For silica microcavities, the resonance tunability is very important and also challenging for many applications. However, almost all previous works on resonance tuning deteriorate the Q factors of silica microcavities at different levels, and evidently these schemes are not suitable for applications in which ultrahigh Q factors are required. In this work, based on the proposed silica microbottle cavity and iron oxide nanoparticles, we realize all-optical control of the silica microcavity and maintain its Q factor of around 1.2108 during the tuning process. A tuning range of 85.9 GHz (0.68 nm) and a tuning sensitivity of 13.6 GHz/mW are obtained, and it is possible to realize full tunability by bridging the azimuthal free spectral range using six adjacent q-series modes. Moreover, all-optical control of the reflection spectrum is also carried out. This work will broaden the applications of ultrahigh-Q silica microcavities in nonlinear optics, microwave photonics, cavity optomechanics and cavity quantum electrodynamics.
Two-dimensional tunable orbital angular momentum generation using a vortex fiber
Guobin Ren, Youchao Jiang, ya shen, Yao Xu, Wenxing Jin, Yue Wu, Wei Jian, and Shuisheng Jian
Doc ID: 305813 Received 29 Aug 2017; Accepted 03 Nov 2017; Posted 06 Nov 2017 View: PDF
Abstract: We demonstrate the two-dimensional tunable orbital angular momentum (OAM) generation in a vortex fiber. The LP₁₁ mode generated by an all fiber fused coupler is coupled into a vortex fiber. Because the vector modes of the LP₁₁ mode group in the vortex fiber are no longer degenerate, the mode status will change between linearly polarized modes (LPMs) and complex OAM modes periodically during propagation. The generated OAM can be tuned smoothly by filtering the mixed mode with different polarization directions or changing the wavelength at a certain polarization direction. The two dimensional turning of OAM from l=-1 to l=+1 is experimentally demonstrated in an all fiber OAM generator.
Nonlinear optical susceptibility of two-dimensional WS₂ measured by Hyper Rayleigh Scattering
Gregory Forcherio, jeremy riporto, Jeremy Dunklin, Yannick Mugnier, ronan Le Dantec, Luigi Bonacina, and Donald Roper
Doc ID: 308235 Received 28 Sep 2017; Accepted 03 Nov 2017; Posted 06 Nov 2017 View: PDF
Abstract: Hyper Rayleigh Scattering (HRS) was used to measure second-order nonlinear susceptibility, χ^(2), for liquid exfoliated WS2 monolayers. It is the first reported use of concentration-dependent HRS measurements to characterize the bulk-like χ^(2) of a two-dimensional (2D) material. Concentration-dependent HRS signal from a 1064 Nd:YAG laser indicated the first hyperpolarizability for 42 nm WS2 monolayers was 4.90±0.30x10^-25 esu using para-nitroaniline (pNA) as an external reference. The corresponding value of χ_xxx^(2) was calculated to be 460±28 pm V^-1. This was within 46% of independent density functional theory (DFT) predictions. Agreement with theory was improved over related microscopy-based approaches. These results support use of HRS to implement 2D materials into nonlinear frequency mixing applications.
Time reflection and refraction of graphene plasmons at a temporal discontinuity
Galaad Altares Menendez and Bjorn Maes
Doc ID: 308602 Received 05 Oct 2017; Accepted 03 Nov 2017; Posted 06 Nov 2017 View: PDF
Abstract: A dynamical change of material properties induces a special type of reflection and refraction at a temporal discontinuity. Here we study the interaction of graphene plasmons with single and double temporal discontinuities or shocks, leading to controlled in-plane scattering. We analytically determine the Fresnel-like coefficients for graphene plasmons at these boundaries, and validate our results by rigorous numerical simulations. Temporally controlled doping of two-dimensional materials such as graphene thus leads to a new mechanism for planar and compact plasmonic devices.
Zero-OAM laser printing of chiral nanoneedles
Sergey Syubaev, Alexey Porfirev, Alexey Zhizhchenko, Oleg Vitrik, Sergey Kudryashov, Sergey Fomchenkov, Svetlana Khonina, and Aleksandr Kuchmizhak
Doc ID: 309140 Received 13 Oct 2017; Accepted 03 Nov 2017; Posted 06 Nov 2017 View: PDF
Abstract: Laser irradiation of various materials including metals, polymers and semiconductors with vortex beams was previously shown to ``twist' transiently molten matter providing the direct easy-to-implement way to obtain chiral surface relief. Specifically for metals, this effect was attributed to transfer of an optical angular momentum (OAM) carried by a vortex beam. In this Letter, we report the formation of twisted metallic nanoneedles on the surface of silver and gold films under their irradiation by a zero-OAM laser beam with a spiral-shaped intensity distribution. Our comparative experiments clearly demonstrate, for the first time, that the formation of the chiral nanoneedles on the noble-metal films is mainly governed by the temperature-gradient induced chiral thermocapillary mass transfer, rather that the OAM-driven rotation of the molten matter.
Schottky Graphene/Silicon Photodetector Based on Hollow-Core Photonic Crystal Fiber
Vahid Ahmadi, Mitra Hosseinifar, and Majid Ebnali-Heidari
Doc ID: 309239 Received 23 Oct 2017; Accepted 03 Nov 2017; Posted 06 Nov 2017 View: PDF
Abstract: This paper presents a new family of Schottky graphene/silicon photodetector (PD) based on hollow-core photonic crystal fibers (HPCF), working at both optical communication and room temperature. The proposed structure takes the advantage of plasmonic HPCF in slow-light regime and also the absorption mechanism is based on internal photoemission effect (IPE). The main feature of this structure is that the enhanced electric field is strongly localized in the hollow-core of the guided core mode with the surface plasmon modes at the surface metal wires embedded in the photonic crystal (PhC) structure. For the proposed graphene/silicon Schottky PD, numerical simulation predicts responsivity of ~0.39 A/W, and CW sensitivity of -59dBm, that reveals substantial improvements compared to that of typical metal/Si Schottky PDs.
Non-invasive characterization of optical fibers
Sören Schmidt, Tobias Tieß, Siegmund Schroeter, Anka Schwuchow, Matthias Jaeger, Hartmut Bartelt, Andreas Tünnermann, and Herbert Gross
Doc ID: 307689 Received 21 Sep 2017; Accepted 03 Nov 2017; Posted 03 Nov 2017 View: PDF
Abstract: Capillary optical fibers with hole diameters of several micrometers are important for novel plasmonic applications and medical diagnosis. In order to ensure the optical functionality of these fibers, the diameter of the capillary hole needs to be realized with high accuracy. Here, we introduce a novel and noninvasive methodology to characterize optical fibers and discuss it for the assessment of capillaries. To this end, the diffraction pattern produced by a coherent side-illumination technique of the fiber is analyzed. A numerical parameter retrieval allows us to characterize thecapillary hole diameter with an accuracy of approximately 100 nm for radii in between several hundreds of nanometers and several tens of micrometers.
Broadband rotary joint for high-speed ultrahigh-resolution endoscopic OCT imaging at 800 nm
Hyeon-Cheol Park, Jessica Mavadia-Shukla, Wu Yuan, Milad Alemohammad, and Xingde Li
Doc ID: 307560 Received 20 Sep 2017; Accepted 03 Nov 2017; Posted 03 Nov 2017 View: PDF
Abstract: We report the development of a broadband rotary joint for high-speed ultrahigh-resolution endoscopic optical coherence tomography (OCT) imaging in the 800 nm spectral range. This rotary joint features a pair of achromatic doublets in order to achieve broadband operation for a 3-dB bandwidth over 150 nm. The measured one-way throughput of the rotary joint is greater than 80% while the fluctuation of the double-pass coupling efficiency during 360° rotation is less than +/-5 % at a near video-rate speed of 20 revolutions/second (rps). The rotary joint is used in conjunction with a diffractive-optics-based endoscope and 800 nm spectral domain OCT (SD-OCT) system, and achieved an ultrahigh axial resolution of ~2.4 μm in air. The imaging performance is demonstrated by three-dimensional (3D) circumferential imaging of a mouse colon in vivo.
High reflective Mo/Be/Si multilayers for the EUV lithography
Nikolay Chkhalo, Sergey Gusev, Andrei Nechay, Dmitri Pariev, Vladimir Polkovnikov, Nikolay Salashchenko, Franz Schäfers, Mewael Sertsu, Andrey Sokolov, Mikhail Svechnikov, and Dmitry Tatarsky
Doc ID: 306455 Received 07 Sep 2017; Accepted 03 Nov 2017; Posted 07 Nov 2017 View: PDF
Abstract: The effect of Be interlayers on the reflection coefficients of Mo/Si multilayer mirrors in the EUV (extreme ultraviolet) region is reported. Samples were studied using a laboratory and synchrotron based reflectometry, and high resolution transmission electron microscopy. The samples under study have reflection coefficients above 71% at 13.5 nm and more than 72% at 12.9 nm in normal incidence mode. Calculations show that by optimizing the thickness of the Be interlayer, it should be possible to increase the reflection coefficient by another 0.5-1%. These results are of considerable interest for EUV lithography.
High performance Ge-on-Si photodetector with optimized DBR location
Zhiping Zhou and Jishi Cui
Doc ID: 308936 Received 12 Oct 2017; Accepted 03 Nov 2017; Posted 09 Nov 2017 View: PDF
Abstract: We investigated the Ge-on-Si photodetectors’ performance enhancement by optimizing the photodetector length, therefore, the location of the Distributed Bragg reflector (DBR). Since the unabsorbed signal light in the photodetector is oscillating between the germanium and silicon layers, but the DBR is on the silicon layer, the optimized location of the DBR will result shorter devices, with increased bandwidth, reduced dark current, and maintaining the responsivity. The 5 μm long photodetector with optimized DBR location shows responsivity of 0.72 A/W, and at least 31.7 GHz 3 dB bandwidth. The dark current is only 7 nA.
Focusing light through dynamical samples using fast continuous wavefront optimization
Baptiste Blochet, Laurent Bourdieu, and Sylvain Gigan
Doc ID: 307630 Received 20 Sep 2017; Accepted 02 Nov 2017; Posted 03 Nov 2017 View: PDF
Abstract: We describe a fast closed-loop optimization wavefront shaping system able to focus light through dynamic scattering media. A MEMS-based spatial light modulator (SLM), a fast photodetector and FPGA electronics are combined to implement a closed-loop optimization of a wavefront with a single mode optimization rate of 4.1 kHz. The system performances are demonstrated by focusing light through colloidal solutions of TiO2 particles in glycerol with tunable temporal stability.
Cross-correlation photothermal optical coherence tomography with high effective resolution
Peijun Tang, Shaojie Liu, Jun Bo Chen, Zhiling Yuan, Bingkai Xie, Jianhua Zhou, and Zhilie Tang
Doc ID: 307886 Received 25 Sep 2017; Accepted 02 Nov 2017; Posted 03 Nov 2017 View: PDF
Abstract: We developed a cross-correlation photothermal optical coherence tomography (CC-PTOCT) system for photothermal imaging with high lateral and axial resolution. The CC-PTOCT system consists of a phase- sensitive OCT system, a modulated pumping laser and a digital cross-correlator. The pumping laser was used to induced the photothermal effect in the sample, which caused a slight phase modulation of the OCT signals. A spatial phase differentiation method was employed to reduce phase accumulation. The noise brought by the phase differentiation method and the strong background noise were suppressed efficiently by the cross-correlator, which was utilized to extract the photothermal signals from the modulated signals. By combining cross-correlation technique with spatial phase differentiation can improve both lateral and axial resolution of the PT-OCT imaging system. Clear photothermal images of blood capillaries of a mouse ear in vivo was successfully obtained with high lateral and axial resolution. The experimental results demonstrated that this system can enhance the effective transverse resolution, effective depth-resolution and contrast of PT-OCT image effectively, which will aid the ongoing development of the accurate 3D functional imaging.
Integrated broadband Ce:YIG/Si Mach Zehnder opticalisolators with over 100nm tuning range
Duanni Huang, Paolo Pintus, Yuya Shoji, Paul Morton, Tetsuya Mizumoto, and John Bowers
Doc ID: 304738 Received 14 Aug 2017; Accepted 02 Nov 2017; Posted 03 Nov 2017 View: PDF
Abstract: We demonstrate integrated optical isolators withbroadband behavior for the standard silicon on insulatorplatform. We achieve over 20dB of optical isolationacross 18nm of optical bandwidth. The isolator iscompletely electrically controlled, and does not require apermanent magnet. Furthermore, we demonstrate theability to tune the central operating wavelength of theisolator across 100nm, which covers the entire S + Ctelecom bands. These devices show promise forintegration in optical systems in which broadbandisolation is needed, such as wavelength multiplexedsystems or optical sensors.
Experimental Demonstration of a Single Silicon Ring Resonator with an ultra wide FSR and tuning range
ang li and Wim Bogaerts
Doc ID: 307167 Received 20 Sep 2017; Accepted 02 Nov 2017; Posted 03 Nov 2017 View: PDF
Abstract: We present an experimental realization of a pseudo single mode silicon ring resonator with an ultra-wide free spectral range (FSR) and tuning range. The device is a single microring resonator with an tunable reflector integrated inside. The reflector is designed to have zero reflection for only one resonance of the ring, while all other resonance wavelength will suffer strong reflection. Given that reflection inside a ring resonator leads to resonance splitting and degradation of the extinction ratio (ER), we obtain a ring resonator where only a single resonance has a large ER, while all others have a very low ER. The large ER resonance can be continuously tuned using metal heaters to achieve a broad tuning range over 55~nm with 16~mW power injected to the phase shifter.
Effect of pulse asymmetry and nonlinear chirp on the accuracy of ultrafast pulsed laser interferometry
Lei Shao, John Lawall, and Jason Gorman
Doc ID: 307558 Received 22 Sep 2017; Accepted 02 Nov 2017; Posted 03 Nov 2017 View: PDF
Abstract: Ultrafast pulsed laser interferometry (PLI) can measure picometer displacements at sub-nanosecond time scales, such as acoustic waves and vibrations in microstructures. In this letter, the effects of pulse characteristics on the accuracy of PLI are investigated through measurements and modeling. The results show that the effective wavelength of PLI, λeff, varies significantly as a function of overlap between the interfering pulses due to pulse asymmetry and nonlinear chirp. This variation presents a serious limitation on the accuracy of PLI if unaddressed. However, it is shown that a continuous wave laser interferometer can be used to determine λeff with an uncertainty near 0.01 %, making it possible to use PLI for accurate displacement measurements.
Extreme ultraviolet light source at megahertz repetition rate based on high harmonic generation inside a modelocked thin-disk laser oscillator
François Labaye, Maxim Gaponenko, Valentin Wittwer, Andreas Diebold, Clement Paradis, Norbert Modsching, Loïc Merceron, Florian Emaury, Ivan Graumann, Christopher Phillips, Clara Saraceno, Christian Kraenkel, Ursula Keller, and Thomas Sudmeyer
Doc ID: 298279 Received 03 Jul 2017; Accepted 01 Nov 2017; Posted 01 Nov 2017 View: PDF
Abstract: We demonstrate a compact XUV source based on high harmonic generation (HHG) driven directly inside the cavity of a modelocked thin-disk laser (TDL) oscillator. The laser is directly diode-pumped at a power of only 51 W and operates at a wavelength of 1034 nm and 17.4 MHz repetition rate. We drive HHG in a high-pressure xenon gas jet with an intracavity peak intensity of 2.8×10¹³ W/cm² and 320 W of intracavity average power. Despite the high-pressure gas jet, the laser operates at high stability. We detect harmonics up to the 17th order (60.8 nm, 20.4 eV) and estimate a flux of 2.6×10⁸ photons/s for the 11th harmonic (94 nm, 13.2 eV). Due to the power-scalability of the thin-disk concept, this class of compact XUV sources has the potential to become a versatile tool for areas such as attosecond science, XUV spectroscopy, and high-resolution imaging.
Tailoring axial intensity of laser beams with a heart-shaped hole
Yulong Wang, LiJuan Xie, Jia-Sheng Ye, wenfeng sun, Xinke Wang, Shengfei Feng, Peng Han, Qiang kan, and Yan Zhang
Doc ID: 306521 Received 07 Sep 2017; Accepted 01 Nov 2017; Posted 01 Nov 2017 View: PDF
Abstract: We demonstrated a simple heart-shaped hole to tailor the axial intensity of a collimated laser beam. This hole is transformed from a soft-boundary one, which avoids the difficulty in fabricating the soft-boundary mask designed by apodization method, as well as the interference problem caused by the pixel structure of the SLM. When a collimated light passes through this hole, its axial intensity oscillates less than 11% within a certain distance, while the fluctuation after the circular aperture is up to 200%. We compared the propagation of beams after this hole and a circular aperture experimentally and theoretically. The results show that this hole is a useful tool to get the laser beam with uniform axial intensity.
Monolithic III-Nitride Photonic Integration Toward Multifunctional Devices
Xumin Gao, zheng shi, Yan Jiang, Shuai Zhang, Chuan Qin, Jialei Yuan, Yuhuai Liu, Peter Grünberg, and yongjin wang
Doc ID: 307016 Received 14 Sep 2017; Accepted 01 Nov 2017; Posted 01 Nov 2017 View: PDF
Abstract: The multiple functionalities of III-nitride semiconductors enable the integration with different components into a multicomponent system with enhanced functions. Here, we propose to fabricate and characterize a monolithic InGaN photonic circuit of transmitter, waveguide and receiver on an III-nitride-on-silicon platform. Both the transmitter and the receiver, sharing identical InGaN/GaN multiple-quantum-well structure and same fabrication procedure, work to emit light and detect light independently. The 8-μm-wide and 200-μm-long InGaN waveguide couples the modulated light from the transmitter and sends the guided light to the receiver, leading to a formation of in-plane light transmission system. The induced photocurrent at the receiver is highly sensitive to the light output of the transmitter. Multi-dimensional light transmissions are experimentally demonstrated at 200 Mb/s. These multifunctional photonic circuits open feasible approaches to the development of III-nitride multicomponent system with integrated functions for comprehensive applications in the visible region.
Doubly-positive functions in coherent and partially coherent optics
Doc ID: 308678 Received 10 Oct 2017; Accepted 01 Nov 2017; Posted 03 Nov 2017 View: PDF
Abstract: A function is said to be doubly-positive if it is everywherenon-negative and the same holds true for itsFourier transform. Examples and properties are discussedtogether with procedures to devise classes ofsuch functions. Applications to coherent and partiallycoherent fields are outlined.
Bit-rate-transparent optical RZ-to-NRZ format conversion based on linear spectral phase filtering of the RZ signal
Reza Maram and Jose Azana
Doc ID: 302837 Received 29 Sep 2017; Accepted 01 Nov 2017; Posted 06 Nov 2017 View: PDF
Abstract: We propose a novel and simple design for all-optical bit-rate-transparent return-to-zero (RZ)-to-non-RZ (NRZ) telecommunication data format conversion based on linear spectral phase filtering of the RZ signal. The proposed concept is numerically analyzed and experimentally validated through successful format conversion of a 640 Gbit/s coherent RZ signal into the equivalent NRZ time-domain data using a simple phase filter realized by a commercial optical waveshaper.
Chip-Scale Optical Vortex Lattice Generator on Silicon Platform
Jian Wang and Jing Du
Doc ID: 306976 Received 14 Sep 2017; Accepted 01 Nov 2017; Posted 07 Nov 2017 View: PDF
Abstract: An optical vortex (OV) with an isolated field singularity, has been extensively studied in a variety of fields. OV lattice with a network of optical vortices, may find more advanced applications in widespread areas such as optical metrology, optical manipulation, quantum processing, etc. OV lattice generated by traditional approaches relies on a number of bulky diffractive optical elements with large volume and long working distance. Here we present a simple and compact on-chip OV lattice emitter on silicon photonics platforms. The principle relies on three-plane-wave interference. We design, fabricate and demonstrate an on-chip OV lattice emitter consisting of three parallel waveguides with etched tilt gratings. The tilt gratings facilitate flexible light emission in a wide range of directions, enabling the generation of OV lattice above the silicon chip. The demonstrated on-chip OV lattice emitter may open a door to generate, manipulate and detect OV lattice using photonic integrated circuits.
Femtosecond laser pumped plasmonically enhanced NIR random laser based on engineered scatterers
Venkata Siva Gummaluri, Radhika Nair, Sivarama Krishnan, and Vijayan C
Doc ID: 309446 Received 18 Oct 2017; Accepted 31 Oct 2017; Posted 03 Nov 2017 View: PDF
Abstract: In this letter, we report on the design, fabrication and implementation of a novel plasmon-mode-driven low-threshold near infra-red (NIR) random laser (RL) in 850-900 nm range based on plasmonic ZnS@Au core-shell scatterers. Plasmon modes in NIR region are used for nanoscale scatterer engineering of ZnS@Au core-shell particles to enhance scattering, as against pristine ZnS. This plasmonic scattering enhancement coupled with femtosecond laser pumping is shown to cause a three-fold lasing threshold reduction from 325 μJ/cm2 to 100 μJ/cm2 and a mode Q factor enhancement from 200 to 540 for ZnS@Au based RL, as compared to pristine ZnS based RL. Local field enhancement due to plasmonic ZnS@Au scatterers, as evidenced in the Finite-Difference Time-Domain (FDTD) simulation, further adds to this enhancement. This work demonstrates a novel scheme of plasmonic mode coupling in NIR region and femtosecond excitation in a random laser photonic system, overcoming the inherent deficiencies of weak absorption of gain media and poor scattering cross sections of dielectric scatterers for random lasing in NIR spectrum.
Subharmonic anti-phase dynamics in coupled mode-locked semiconductor lasers
Sudarshan Sivaramakrishnan and Herbert Winful
Doc ID: 306808 Received 12 Sep 2017; Accepted 31 Oct 2017; Posted 03 Nov 2017 View: PDF
Abstract: We show that coupled mode-locked semiconductor lasers can operate in a subharmonic regime in which the two lasers pulsate in an anti-phase manner at one-half the fundamental mode-locking frequency of the solitary lasers. In the subharmonic mode each pulse has almost twice the energy carried by the isolated lasers in the fundamental mode-locked regime and is also significantly shorter in duration. Depending on the unsaturated gain and coupling strength the lasers can also exhibit bistability, perfect synchronization, delayed synchronization and three-halves harmonic mode locking. The observed behaviors are robust and persist in the presence of noise.
Improved lateral resolution with an annular vortex depletion beam in STED microscopy
Bin Wang, Jinmeng Shi, Tianyue Zhang, Xiaoxuan Xu, Yao-Yu Cao, and Xiangping Li
Doc ID: 308122 Received 27 Sep 2017; Accepted 31 Oct 2017; Posted 01 Nov 2017 View: PDF
Abstract: We report on the experimental demonstration of improved lateral resolution in stimulated emission depletion (STED) microscopy using an annular depletion beam configuration. A tight and finely tuned doughnut focal spot can be created by annular vortex illumination. Its application in STED microscopy for enhanced lateral resolution is systematically investigated by imaging 40 nm fluorescent beads. An improved resolution with more than 20% reduced effective point spread function of the imaging system determined by the full width at half maximum compared to that of the conventional STED is achieved. The proposed scheme also demonstrates its resolving capability for biological samples. The principle holds great potentials in the research fields of biological super-resolution imaging as well as STED-based nano-lithography and high-density optical data storage.
Giant self-induced transparency of intense few-cycle terahertz pulses in n-doped silicon
Oleg Chefonov, Andrey Ovchinnikov, Sergey Romashevskiy, XIN CHAI, Tsuneyuki Ozaki, Andrei Savel'ev, M.B. Agranat, and Vladimir Fortov
Doc ID: 309208 Received 17 Oct 2017; Accepted 31 Oct 2017; Posted 01 Nov 2017 View: PDF
Abstract: The results of high-field terahertz transmission experiments on n-doped silicon (carrier concentration of 8.7×10^16 cm^-3) are presented. We use terahertz pulses with electric field strengths up to 3.1 MV/cm and a pulse duration of 700 fs. Huge transmittance enhancement of ~90 times is observed with increasing of the terahertz electric field strengths within the range of 1.5-3.1 MV/cm.
Two-Dimensional Microbend Sensor Based on Long Period Fiber Gratings in an isosceles triangle arrangement 3-Core Fiber
song wang, Weigang Zhang, LEI CHEN, Yanxi Zhang, Pengcheng Geng, Yun-Shan Zhang, Tieyi Yan, Lin Yu, Wei Hu, and Yan-Ping Li
Doc ID: 307219 Received 15 Sep 2017; Accepted 30 Oct 2017; Posted 01 Nov 2017 View: PDF
Abstract: To realize the 2D microbend sensor, we designed and fabricated two non-orthogonal long period fiber gratings in our lab made isosceles triangle arranged 3-core optical fiber. To mark two directions without crosstalk, we write two different periods of LPFG in each of the two external cores and central core, which induce a strong asymmetric refractive index arrangement in fiber cross-section. Theoretical and experimental results verify that the resonant wavelength originates from the tunneling between the LP01 core mode in center core and in external core. In the confirmation experiments, the proposed sensor can distinguish multiple bending directions and experiences a maximum sensitivity of 3. 4 nm/m-1 with the bending range of 0–0.588m-1.
On-chip wavelength locking for photonic switches
Akhilesh Khope, Takako Hirokawa, Andrew Netherton, Mitra Saeidi, Yujie Xia, Nicolas Volet, Clint Schow, Roger Helkey, Luke Theogarajan, Adel Saleh, John Bowers, and Rod Alferness
Doc ID: 305974 Received 06 Sep 2017; Accepted 30 Oct 2017; Posted 30 Oct 2017 View: PDF
Abstract: We present an on-chip wavelength reference with a partial drop ring resonator and germanium photo-detector. This approach can be used in ring resonator-based wavelength-selective switches where absolute wavelength alignment is required. We use the temperature dependence of heater resistance as a temperature sensor. Additionally, we discuss locking speed, statistical variation of heater resistances and tuning speed of the switches.
Modified calculation method of relative sensitivity for fluorescence intensity ratio thermometry
Leipeng Li, Yuan Zhou, feng qin, Yangdong Zheng, Hua Zhao, and Zhiguo Zhang
Doc ID: 307331 Received 18 Sep 2017; Accepted 30 Oct 2017; Posted 30 Oct 2017 View: PDF
Abstract: The calculation method of relative sensitivity (Sr) for fluorescence intensity ratio (FIR) thermometry is discussed, taking the 3F3–3H6 and 3H4–3H6 transitions of Tm3+ ion as examples. The value of Sr is calculated using its original definition, and is found to largely deviate from the result obtained using the conventional method that is widely used at present. This deviation is found to stem from the neglect of an offset. A modified expression for Sr is proposed, which shows the true performance of the FIR technology and makes it possible to precisely compare the Sr values obtained using various methods.
Cr3+-doped Bi2Ga4O9-Bi2Al4O9 solid-solution phosphors: crystal-field modulation and lifetime-based temperature sensing
Daqin Chen, Xiao Chen, Xiaoyue Li, Hai Guo, Shen Liu, and Xinyue Li
Doc ID: 306350 Received 04 Sep 2017; Accepted 30 Oct 2017; Posted 06 Nov 2017 View: PDF
Abstract: Cr3+-doped Bi2Ga4O9-Bi2Al4O9 solid-solution phosphors were fabricated to explore their possible application in fluorescence-lifetime-based temperature sensing. The present samples exhibited 2E→4A2 R-line emissions associated with 4T2→4A2 phonon sideband emissions of Cr3+ in the wavelength range of 600~850 nm upon the excitation of visible light. Through modifying Ga/Al ratio in the solid-solution hosts, Cr3+ crystal-field was easily tuned from intermediate to strong, being beneficial to modulate energy gap between 2E and 4T2 thermally coupled emitting-states. As a result, linearly temperature-sensitive fluorescence lifetime was achieved in the Cr3+-doped Bi2Ga4O9-Bi2Al4O9 solid-solutions with high Ga/Al ratio, enabling conveniently and accurately determine temperature with high relative sensitivity of 2.13~3.26 %K-1.
Butterfly-inspired micro-concavity array film for color conversion efficiency improvement of quantum-dot-based light emitting diodes
Shudong Yu, Baoshan Zhuang, Junchi Chen, Zongtao li, Longshi Rao, Binhai Yu, and Yong Tang
Doc ID: 307096 Received 25 Sep 2017; Accepted 30 Oct 2017; Posted 06 Nov 2017 View: PDF
Abstract: Inspired by Papilio Blumei butterfly, a microstructured quantum-dot (QD) film with micro-concavity array (MCA) on both surfaces is proposed to enhance color conversion efficiency (CCE) of QD-based white light emitting diodes in this paper. The diameter, aspect ratio and pitch of MCA are optimized in the optical simulations. Both the simulation and experimental results show that the scattering and double reflection effects are the key to the CCE improvement of QD films. The results show that the CCEs are increased from 19.98% to 21.59% and 21.78% (350 mA) for single-side microstructured QD film and double-side microstructured QD film configurations, respectively. Therefore, the proposed microstructured QD film will be a promising alternative to conventional QD layer in illumination and display applications.
Dual-Wavelength Digital Holography with Low-Coherence Light Source based on Quantum Dot Film
Jae-Yong Lee, Sungbin Jeon, JINSANG LIM, Se-Hwan Jang, No-Cheol Park, and Young-Joo Kim
Doc ID: 307998 Received 26 Sep 2017; Accepted 30 Oct 2017; Posted 09 Nov 2017 View: PDF
Abstract: This letter proposes a dual-wavelength, low-coherence digital holography system with a single light source, which utilizes a quantum dot (QD) film as a wavelength converter. By changing the size of QDs, the proposed method yields higher and more uniform illumination easily of any target wavelength, compared with bandpass-filtered light-emitting diodes (LEDs). Fabrication parameters of QD film for better conversion efficiency are discussed. Using this light source with the dual-wavelength reconstruction method extends the efficiency and range of nanoscale three-dimensional height measurements.
Magnetron sputtering deposited WTe2 for ultrafast thulium-doped fiber laser
Jintao Wang, Zike Jiang, hao chen, Jiarong Li, Jinde Yin, Jinzhang Wang, Tingchao He, Peiguang Yan, and Shuangchen Ruan
Doc ID: 307822 Received 25 Sep 2017; Accepted 29 Oct 2017; Posted 06 Nov 2017 View: PDF
Abstract: Ultrafast pulse generation was demonstrated in thulium doped fiber laser mode locked by magnetron sputtering deposited WTe2 with the modulation depth, non-saturable loss and saturable intensity of 31%, 34.3% and 7.6 MW/cm2, respectively. Stable soliton pulses emitting at 1915.5 nm were obtained with pulse duration of 1.25 ps, a 3 dB spectral bandwidth of 3.13 nm, an average output power of 39.9 mW, and signal-to-noise ratio (SNR) of 95 dB. To our knowledge, this is the first demonstration of WTe2-based SA in fiber lasers at 2 μm regime.
Generation of 70-fs pulses at 2.86 μm from a mid-infrared fiber laser
Robert Woodward, Darren Hudson, Alex Fuerbach, and Stuart Jackson
Doc ID: 307405 Received 20 Sep 2017; Accepted 29 Oct 2017; Posted 30 Oct 2017 View: PDF
Abstract: We propose and demonstrate a simple route to few-optical-cycle pulse generation from a mid-infrared fiber laser through nonlinear compression of pulses from a holmium-doped fiber oscillator using a short length of chalcogenide fiber and a grating pair. Pulses from the oscillator with 265 fs duration at 2.86 μm are spectrally broadened through self-phase modulation in step-index As₂S₃ fiber to 140 nm bandwidth, and then re-compressed to 70 fs (7.3 optical cycles). These are the shortest pulses from a mid-infrared fiber system to date, and we note that our system is compact, robust and uses only commercially available components. The scalability of this approach is also discussed, supported by numerical modeling.
Broadband mode switch based on a three-dimensional waveguide Mach–Zehnder interferometer
Quandong Huang, Wei Jin, and Kin Chiang
Doc ID: 306757 Received 08 Sep 2017; Accepted 29 Oct 2017; Posted 30 Oct 2017 View: PDF
Abstract: We propose a mode switch that operates on modulating the optical phases of a three-dimensional balanced four-arm waveguide Mach–Zehnder interferometer. We design and fabricate the device with polymer material to achieve thermo-optic switching between any two of the E11, E21, E12, and E22 modes of the waveguide. Our experimental device shows an extinction ratio higher than 14 dB and a switching time shorter than 3.7 ms, measured with the E11 mode switched to any of the other modes at 1550 nm. This mode switch can operate over a wide range of wavelengths with weak polarization dependence and could be used in reconfigurable fiber-based mode-division-multiplexing systems, where mode routing is required.
Calibrated phase-shifting digital holography based on dual-camera system
Peng Xia, Qinghua Wang, Shien Ri, and Hiroshi Tsuda
Doc ID: 303667 Received 31 Jul 2017; Accepted 28 Oct 2017; Posted 01 Nov 2017 View: PDF
Abstract: A calibrated phase-shifting digital holography system based on the sampling Moiré technique is proposed. Two synchronized cameras are used in this system. One is to record the conventional holograms which include the object information, and the another is to record the interference fringes to analyze phase-shifting errors. An algorithm for improving the quality of the reconstructed images is proposed. In this study, the effectiveness of the proposed system and algorithm is demonstrated in four-step phase-shifting digital holography. The quality of the reconstructed images is greatly improved from both the numerical simulation and experiment.
Controllable symmetric and asymmetric spin splitting of Laguerre-Gaussian beams assisted by surface plasmon resonance
Wenguo Zhu, Linqing Zhuo, Mengjiang Jiang, Heyuan Guan, JianHui Yu, Yunhan Luo, Huihui Lu, Jun Zhang, and Zhe Chen
Doc ID: 308010 Received 27 Sep 2017; Accepted 28 Oct 2017; Posted 30 Oct 2017 View: PDF
Abstract: The spin splitting of light beams carrying orbital angular momentum (OAM) are investigated in attenuated internal reflection in Kretschmann configuration. The excitation of surface plasmon resonance (SPR) can significantly enhance the OAM-induced Imbert–Fedorov (IF) shift and the OAM-dependent spin splitting. The cooperation effect of these two shifts will result in an asymmetric spin splitting, which varies with the incident angle and polarization state. Specially, at the SPR angle, the OAM-induced IF shift vanishes, and the OAM-dependent spin splitting will cause a symmetric spin splitting. However, when the incident beam is horizontally polarized, the OAM-induced IF shift predominates, thus the two spin components of the reflected will not be split, instead, they will be shifted together. This flexible control of the optical spin splitting can find applications in quantum information and precision metrology.
Discovery of high-gain stimulated polariton scattering near 4 THz from lithium niobate
YU-CHUNG CHIU, TSONG-DONG WANG, GANG ZHAO, and Yen-Chieh Huang
Doc ID: 307976 Received 27 Sep 2017; Accepted 27 Oct 2017; Posted 27 Oct 2017 View: PDF
Abstract: Lithium Niobate is the most popular material for THz-wave generation via stimulated polariton scattering, previously known to have a gain peak near 2 THz. Here we report the discovery of another phase-matched gain peak near 4 THz in lithium niobate, which greatly extends the useful gain spectrum of lithium niobate. Despite of the relatively high 4-THz absorption in lithium niobate, the 4-THz stimulated polariton scattering becomes dominant over the 2-THz one in an intensely pumped short lithium niobate crystal due to less diffraction-induced absorption and mode-area mismatch. We also demonstrate a signal-seeded off-axis THz parametric oscillator that generates 1.4 nJ at 4.2 THz from Lithium Niobate with 17.5 mJ pump energy.
In-situ laser measurement of oxygen concentration and flue gas temperature utilizing chemical reaction kinetics
Jan Viljanen, Juha Toivonen, and Tapio Sorvajärvi
Doc ID: 309552 Received 19 Oct 2017; Accepted 27 Oct 2017; Posted 01 Nov 2017 View: PDF
Abstract: Combustion research requires detailed localized information on the dynamic combustion conditions to improve the accuracy of the simulations and hence improve the performance of the combustion processes. We have applied chemical reaction kinetics of potassium to measure local temperature and O2 concentration in flue gas. Excess of free atomic potassium is created into the measurement volume by photofragmenting precursor molecule such as KCl or KOH that are widely released from solid fuels. The decay of the induced potassium concentration is followed with an absorption measurement using a narrow linewidth diode laser. The temperature and O2 concentration are solved from the decay curve features using equations obtained from calibration measurements in temperature range of 800-1000 °C and in O2 concentrations of 0.1-21 %. Local flue gas temperature and O2 concentration were recorded in real time during devolatilization, char burning and ash cooking phases of combustion in single particle reactor with 5 Hz repetition rate. The method can be further extended to other target species and applications where the chemical dynamics can be disturbed with photofragmentation.
Robust Terahertz Polarizers with High Transmittance at Selected Frequencies through Si Wafer Bonding Technologies
Ting-Yang Yu, Nai-Chen Chi, Hsin-Cheng Tsai, Shiang-Yu Wang, Chih Wei Luo, and Kuan-Neng Chen
Doc ID: 310093 Received 26 Oct 2017; Accepted 27 Oct 2017; Posted 30 Oct 2017 View: PDF
Abstract: Terahertz (THz) polarizers with robust structure and high transmittance are demonstrated using 3D-IC technologies. Cu wire-grid polarizer is sealed and well protected by Si bonded wafers through low temperature eutectic bonding method. Deep reactive-ion etching (DRIE) is used to fabricate the Anti-reflection (AR) layers on outward surfaces of bonded wafers. The extinction ratio (ER) and transmittance of polarizers are between 20dB to 33dB and 13dB to 27dB for 10μm and 20μm pitch wire-grid and 100% at central frequency, depending on frequency and AR layer thickness. The process of polarizer fabrication is simple from mature semiconductor manufacturing techniques that leads to high yield, low cost, and potential for THz applications.
Wide-Field Interferometric Measurement of Nonstationary Complex Coherence Function
Roxana Rezvani Naraghi, Heath Gemar, Mahed Batarseh, Andre Beckus, George Atia, Sergey Sukhov, and Aristide Dogariu
Doc ID: 305765 Received 30 Aug 2017; Accepted 26 Oct 2017; Posted 03 Nov 2017 View: PDF
Abstract: Spatial coherence function (SCF) is a complex function of two spatial coordinates that in general carries more information than the bare intensity distribution. A fast and quantitatively accurate measurement of the SCF is extremely important for a range of applications in optical sensing and imaging. Here, we demonstrate an efficient two-step procedure for measuring the full-field complex coherence function. The measurement relies on an optimized design of a wavefront shearing interferometer that is able to characterize spatially inhomogeneous fields over an extended angular domain. The precision of our coherence measurement is confirmed by the excellent agreement with numerical estimation based on Fresnel calculations. We demonstrate that the sensitivity and the measurement range afforded by our instrument permits to reliably describe the differences in the complex coherence functions that are due to subtle modifications in the shape, position, and orientation of radiation sources.
Linear autocorrelation of partially coherent XUV laser pulses: a quantitative analysis
Andréa Le Marec, Olivier Larroche, and Annie Klisnick
Doc ID: 306454 Received 06 Sep 2017; Accepted 26 Oct 2017; Posted 30 Oct 2017 View: PDF
Abstract: A quantitative interpretation method is described for experiments involving the linear autocorrelation of par- tially coherent extreme-ultraviolet (XUV) pulses, gener- ated by either x-ray free-electron lasers or plasma-based XUV lasers. A recently published modeling method for partially coherent pulses is numerically implemented in that specific case. Analytical expressions for the statistical root-mean-square average of the fringe visibility curves are derived. The method yields unambigu- ous informations on both the coherence time and the pulse duration, and should provide a valuable data interpretation tool.
Ultra-compact waveguide crossing for mode-division multiplexing optical network
Chunlei Sun, Yu Yu, and Xinliang Zhang
Doc ID: 306748 Received 08 Sep 2017; Accepted 24 Oct 2017; Posted 30 Oct 2017 View: PDF
Abstract: We propose and experimentally demonstrate an ultra-compact multimode waveguide crossing which can process two modes simultaneously. The symmetric Y-junction is introduced to split the high-order mode into fundamental ones, easing the subsequent processing. The footprint of the proposed crossing is as compact as 21 µm × 21 µm. The measured results show insertion loss of ~1.82 dB for TE0 mode and ~0.46 dB for TE1 mode at 1550 nm, as well as crosstalk of < -18 dB from 1510 to 1600 nm.
Intensity Noise Coupling in Soliton Fiber Oscillators
chenchen wan, Thomas Schibli, Peng Li, Carlo Bevilacqua, Axel Ruehl, and Ingmar Hartl
Doc ID: 301071 Received 01 Sep 2017; Accepted 24 Oct 2017; Posted 16 Nov 2017 View: PDF
Abstract: We present an experimental and numerical study on the spectrally resolved pump-to-output intensity noise coupling in soliton fiber oscillators. In our study we observe a strong pump noise coupling to the Kelly sidebands while the coupling to the soliton pulse is damped. This behavior is observed in Erbium-doped as well as Holmium-doped fiber oscillators and confirmed by numerical modeling. It can be seen as a general feature of laser oscillators where soliton pulse formation is dominant. We show that spectral blocking of the Kelly-sidebands outside the laser cavity can improve the intensity noise performance of the laser dramatically
Bismuth-doped All Fiber Mode-locked Laser Operating at 1340nm
Naresh Kumar Thipparapu, Chunyu GUO, Andrey Umnikov, Pranabesh Barua, Austin TARANTA, and Jayanta Sahu
Doc ID: 309157 Received 13 Oct 2017; Accepted 23 Oct 2017; Posted 25 Oct 2017 View: PDF
Abstract: We demonstrate a 1340nm mode-locked Bismuth (Bi)-doped fiber laser without any saturable absorber. The effect of pump power on pulse width is studied and a variation from 1.5 to 3ns is reported. The output of the mode-locked Bi-doped fiber laser (ML-BDFL) is further amplified using a master oscillator power amplifier (MOPA) configuration and a peak power of 1.15W is achieved. Soliton bunching is observed and a true pulse width of 1.2ps is reported from the measured autocorrelation trace. Stable operation of the mode-locked laser is verified from the RF spectrum with a fundamental repetition rate of 6.3MHz, and SNR of 65dB.
Realization of Complementary medium using dielectric photonic crystals
Tao Xu, Anan Fang, Ziyuan Jia, Liyu Ji, and Zhihong Hang
Doc ID: 307924 Received 25 Sep 2017; Accepted 22 Oct 2017; Posted 27 Oct 2017 View: PDF
Abstract: By exploiting the scaling invariance of photonic band diagrams, a complementary photonic crystal slab structure is realized by stacking two uniformly scaled double-zero-index dielectric photonic crystal slabs together. Space cancellation effect in complementary photonic crystals is demonstrated in both numerical simulations and microwave experiments. The refractive index dispersion of double-zero-index dielectric photonic crystal is experimentally measured. Using pure dielectrics, our photonic crystal structure will be an ideal platform to explore various intriguing properties related to complementary medium.
Highly nonlinear yttrium-aluminosilicate optical fiber with high intrinsic stimulated Brillouin scattering threshold
Matthew Tuggle, Courtney Kucera, Thomas Hawkins, Dakota Sligh, Antoine Runge, Anna Peacock, John Ballato, and Peter Dragic
Doc ID: 305740 Received 29 Aug 2017; Accepted 20 Oct 2017; Posted 25 Oct 2017 View: PDF
Abstract: Highly nonlinear (high-NA small-mode-area) optical fibers also possessing intrinsically high stimulated Brillouin scattering (SBS) threshold are described. More specifically, silica clad, yttrium-aluminosilicate core fibers are shown to exhibit an intrinsically low Brillouin gain coefficient between 0.125 and 0.139x 10^-11 m/W, and a Brillouin gain linewidth of up to 500 MHz. Losses on the order of 0.7 dB/m were measured, resulting from impurities in the precursor materials. Nonlinear refractive index values are determined to be similar to that of silica, but significant measurement uncertainty is attributed to the need to estimate dispersion curves since their direct measurement could not be made. The interest for highly nonlinear optical fibers with a low intrinsic Brillouin gain coefficient is expected to continue, especially with the growing developments of narrow-linewidth high energy laser systems.
Extinction by a homogeneous spherical particle in an absorbing medium
Michael Mishchenko, Gorden Videen, and Ping Yang
Doc ID: 308269 Received 29 Sep 2017; Accepted 20 Oct 2017; Posted 30 Oct 2017 View: PDF
Abstract: We use a recent computer implementation of the first-principles scattering theory to compute far-field extinction by a spherical particle embedded in an absorbing unbounded host. Our results show that the suppressing effect of increasing absorption inside the host medium on the ripple structure of the extinction efficiency factor as a function of size parameter is similar to the well-known effect of increasing absorption inside a particle embedded in a nonabsorbing host. However, the accompanying effects on the interference structure of the extinction efficiency curves are diametrically opposite. As a result, sufficiently large absorption inside the host medium can cause negative particulate extinction. A simple physical explanation of the phenomenon of negative extinction is offered. Yet further research is needed to clarify when this phenomenon is physically meaningful and when it becomes an artefact of pushing the far-field scattering formalism beyond its range of validity.
Optical Image Cloning based on Electromagnetic Induced Absorption
Ulices A., Shamaila Manzoor, and Luis de Araujo
Doc ID: 307157 Received 15 Sep 2017; Accepted 18 Oct 2017; Posted 01 Nov 2017 View: PDF
Abstract: We investigate both theoretically and experimentally optical image cloning via Electromagnetic Induced Absorption (EIA). We demonstrate the transfer of small 2D real images imprinted onto a strong coupling beam to a weak probe beam in a rubidium vapor cell. We show that, through EIA, the coupling beam's image is cloned beyond the usual diffraction, with a potential improvement in spatial resolution of the cloned image by a factor of 3 in comparison to that of the original coupling beam. Optical cloning through EIA is based on position selective nonlinear absorption, and it does not rely on spatial modulation of the refractive index.
Asynchronous and synchronous dual-wavelength pulse generation in a passively mode-locked fiber laser with a mode-locker
Guoqing Hu, Yingling Pan, Xin Zhao, Siyao Yin, Meng Zhang, and Zheng Zheng
Doc ID: 306978 Received 18 Sep 2017; Accepted 18 Oct 2017; Posted 03 Nov 2017 View: PDF
Abstract: The evolution from asynchronous to synchronous dual-wavelength pulse generation in a passively mode-locked fiber laser is experimentally investigated by tailoring the intracavity dispersion. Through tuning the intracavity-loss-dependent gain profile and the birefringence-induced filter effect, asynchronous dual-wavelength soliton pulses can be generated until the intracavity anomalous dispersion is reduced to ~8 fs/nm. The transition from asynchronous to synchronous pulse generation is then observed at an elevated pump power in the presence of residual anomalous dispersion, and it is shown that pulses are temporally synchronized at the mode-locker in the cavity. Spectral sidelobes are observed and could be attributed to the four-wave-mixing effect between dual–wavelength pulses at the carbon nanotube mode-locker. These results could provide further insight into the design and realization of such dual-wavelength ultrafast lasers for different applications such as dual-comb metrology as well as better understanding of the inter-pulse interactions in such dual-comb lasers.
High quality factor double Fabry-Perot plasmonic nanoresonator
Baptiste FIX, Julien Jaeck, Patrick Bouchon, sébastien héron, benjamin vest, and Riad Haidar
Doc ID: 308258 Received 29 Sep 2017; Accepted 17 Oct 2017; Posted 27 Oct 2017 View: PDF
Abstract: Fabry-Perot like resonances have been widely describedin nanoantennas. In the original Fabry-Perotresonator, a third mirror can be added, resulting in amultimirror interferometer. However, in the case ofcombination of nanoantennas, it has been reported thateach cavity behaves independently. Here, we evidencethe interferences between two FP absorbing nanoantennasthrough a common mirror, which has a strongimpact on the optical behavior. While the resonancewavelength is only slightly shifted, the level of absorptionreaches nearly 100 %. Moreover, the quality factorincreases up to factor 7 and can be chosen by geometricdesign over a range from 11 to 75. We demonstratethanks to a simple analytical model that this couplingcan be ascribed to a double FP cavity resonance, withthe unique feature that each cavity is separately coupledto the outer medium.
Third-order nonlinearity OPO: Schmidt Mode Decomposition And Tripartite Entanglement
Carlos González Arciniegas, Nicolas Treps, and Paulo Nussenzveig
Doc ID: 306089 Received 04 Sep 2017; Accepted 16 Oct 2017; Posted 17 Oct 2017 View: PDF
Abstract: We investigate quantum properties of light in optical parametric oscillators (OPOs) based on four-wave mixing gain in media with third-order non-linearities. In spite of other competing χ(3) effects, such as phase modulation, bipartite and tripartite entanglement are predicted above threshold. These findings are relevant for recent implementations of CMOS-compatible on-chip OPOs
Spatially Multiplexed Orbital Angular Momentum-Encoded Photon and Classical Channels in a Free-space Optical Communication Link
Yongxiong Ren, Cong Liu, Kai Pang, Jiapeng Zhao, Yinwen Cao, Guodong Xie, Long Li, Peicheng Liao, Zhe Zhao, Moshe Tur, Robert Boyd, and Alan Willner
Doc ID: 303043 Received 11 Sep 2017; Accepted 16 Oct 2017; Posted 23 Oct 2017 View: PDF
Abstract: We experimentally demonstrate spatial multiplexing of an orbital angular momentum (OAM)-encoded single photon and a classical Gaussian beam with a different wavelength and orthogonal polarization. Data rates as large as 100 MHz are achieved by encoding on two different OAM states by employing a combination of independently modulated laser diodes and helical phase holograms. The influence of OAM mode spacing, encoding bandwidth, and interference from the co-propagating Gaussian beam on registered photon counts and quantum bit-error-rates is investigated. Our results show that the deleterious effects of intermodal crosstalk effects on system performance become less important for OAM mode spacing Δ≥ 2 (and corresponds to a crosstalk value of less than -18.5dB). The use of OAM domain can additionally offer at least 10.4 dB isolation besides that provided by wavelength and polarization, leading to a further suppression of interference from the classical channel.
Three-Dimensional Patterned Graphene Oxide-Quantum Dot Microstructures via Two-Photon Crosslinking
Chun-Yu Lin, Hsin-Yu Chang, Te-Fu Yeh, Hsisheng Teng, and Shean-Jen Chen
Doc ID: 307973 Received 28 Sep 2017; Accepted 16 Oct 2017; Posted 01 Nov 2017 View: PDF
Abstract: The two-photon crosslinking of graphene oxide-quantum dots (GOQDs) adopts rose Bengal as the photoactivator to induce the GOQD assembly process. Based on the Förster resonance energy transfer mechanism with oxygen as the crosslinking medium, three-dimensional patterned GOQD microstructures with near diffraction-limit spatial resolution have been fabricated and analyzed by a multiphoton excited fabrication instrument/microscope.
Position-resolved Raman spectra from a laser-trapped single airborne chemical droplet
aimable kalume, Eric Zhu, Chuji Wang, Joshua Santarpia, and Yongle Pan
Doc ID: 307235 Received 15 Sep 2017; Accepted 16 Oct 2017; Posted 09 Nov 2017 View: PDF
Abstract: It could be very useful to detect and monitor the molecules and molecular reactions located in different positions within a micro-sized particle as they respond to various micro-local environments. In this letter, a particular optical trap using two focusing counter-propagating hollow beams was able to stably trap both absorbing and non-absorbing particles in air for long time observation. A technique that can measure the Raman spectra from different submicron positions of a laser-trapped single airborne particle was developed. Spontaneous and stimulated Raman scattering (SRS) spectra originated from different positions of a diethyl phthalate droplet were recorded, and the strong Raman scattering signals are results of cavity-enhanced effects and the localized strong light illumination.
Analytical registration of vertical image drifts in parallel beam tomographic data
Malte Storm, Felix Beckmann, and Christoph Rau
Doc ID: 304177 Received 09 Aug 2017; Accepted 12 Oct 2017; Posted 12 Oct 2017 View: PDF
Abstract: Reconstructing tomographic images of high resolution, as in X-ray microscopy or transmission electron microscopy, is often limited by the stability of stages or sample drifts, which requires an image alignment prior to reconstruction. Feature--based image registration is routinely used to align images, but this technique relies on strong features in the sample or the application of for example gold tracer particles. In this letter, we present an analytic approach for achieving the vertical registration based on the inherent properties of the data acquired for tomographic reconstruction. It is computationally cheap to implement and can be easily integrated into existing reconstruction pipelines.
Phase-shifting digital holographic microscopy by using a multi-camera setup
Carlos Trujillo and Jorge Garcia-Sucerquia
Doc ID: 303697 Received 01 Aug 2017; Accepted 12 Oct 2017; Posted 16 Oct 2017 View: PDF
Abstract: In this letter, the use of two-coupled Mach-Zehnder interferometers to obtain four π/2 phase-shifted interferograms is introduced. Multi-camera systems in phase-shifting interferometry have been reported in the past to obtain phase-shifted interferograms without using any active shifter device, but these proposals make use of polarizers, diffracting gratings or other optical elements that increase the complexity of the setup. In this proposal, a simple multi-camera setup using no more than beam splitters and mirrors is implemented to obtain in a single shot the needed phase-shifted interferograms in the different output channels of the setup. This proposal is validated in digital holographic microscopy to visualize a biological sample of onion cells.
An inclined emitting slotted single mode laser with 1.7 degree vertical divergence angle for PIC applications
Yejin Zhang, Yanmei Su, Hongwei Qu, Yu Bi, Jiaoqing Pan, Hongyan Yu, Yang Zhang, Jie Sun, Ming Chong, and xinyan sun
Doc ID: 306547 Received 06 Sep 2017; Accepted 11 Oct 2017; Posted 30 Oct 2017 View: PDF
Abstract: In this letter, a new type of single mode slotted laser used for on-chip light source in photonic integrated circuits is proposed. An inclined light beam with a low vertical divergence angle can be directly coupled into the surface grating of the silicon to form an integrated light source. Experimentally, an III-V laser with a 54.6 degree inclined angle and a vertical divergence angle of 1.7 degree is achieved by introducing a kind of specially distributed micro-structure. The side mode suppression ratio is better than 45 dB and the continuous wave output power reaches 6.5 mW at room temperature. We report the inclined emitting micro-structured single mode laser with a low divergence angle for the first time.
Output power enhancement of self-frequency-doubled laser by selective excitation of inequivalent active centers in La2CaB10O19 (Nd:LCB) crystal
Qiannan Fang, Haohai Yu, Huaijin Zhang, Guochun Zhang, Jiyang Wang, and Yicheng Wu
Doc ID: 307037 Received 13 Sep 2017; Accepted 10 Oct 2017; Posted 12 Oct 2017 View: PDF
Abstract: We demonstrate the enhancement of the self-frequency-doubled laser with the Nd3+ doped lanthanum calcium borate La2CaB10O19 (Nd:LCB) crystals by selective excitation of its inequivalent activge centers. When the Nd3+ ions located in the Ca2+ sites were excited in the Nd:LCB crystal, the fundamental laser at the wavelength of 1066 nm was successfully realized which can keep the self-frequency-doubled wavelength away from the self-absorption peak of Nd3+ ions at about 5 nm. By optimizing the key parameters, the maximum output power of 801 mW was achieved with the frequency-doubling at the wavelength of 533 nm and the enhancement of output power was about 7.8 times compared with the results by excitation of Nd3+ ions in the La3+ sites. Up to now, this output power of self-frequency-doubled laser represents for the highest one in the Nd:LCB crystal and the efficient emission at 533 nm should have promising applications in the visible range, such as laser displays, optical data storage, laser printing, etc.. Meanwhile, the selective excitation of inequivalent active ions and the enhancement of self-frequency-doubled laser may provide some inspirations for the investigation of multi-functional materials.
Transfer of chirality from light to a Disperse Red 1molecular glass surface
Leila Mazaheri, Olivier Lebel, and Jean-Michel Nunzi
Doc ID: 305696 Received 30 Aug 2017; Accepted 05 Oct 2017; Posted 23 Oct 2017 View: PDF
Abstract: Chiral structures and materials interact with light in well-documented ways, but light can also interact with achiralmaterials to generate chirality by inscribing itsasymmetric configuration on photoresponsive materials,such as azobenzene derivatives. While it is possible tothusly generate both bidimensional (2D) andtridimensional (3D) chirality, 2D chirality is especiallyattractive because of its non-reciprocity. Herein, 2Dchirality is induced on the surface of a glass-formingDisperse Red 1 derivative by irradiation with a singlelaser beam, yielding crossed spontaneous surface reliefgratings (SSRG) with different pitches. Azimuth rotationsup to 10° have been observed, and the absence of 3Dchirality has been confirmed. This method thus allowsgenerating non-reciprocal planar chiral objects by asimple, single irradiation process on a thin film of amaterial that can easily be processed over large areas oronto small objects.
Experimental measurement of supercontinuum coherence in tellurite photonic crystal fiber
Yuji Zhang, Daniel Kane, and Fiorenzo Omenetto
Doc ID: 305881 Received 01 Sep 2017; Accepted 25 Sep 2017; Posted 30 Oct 2017 View: PDF
Abstract: Spectral and coherence evolution were measured for supercontinuum generated in a 2.7-cm highly nonlinear tellurite photonic crystal fiber. Numerical simulations were performed based on the generalized nonlinear Schrödinger equation with noise. The measurements show coherence degradation first occurs after soliton fission, and then spreads to longer wavelengths as the average power of supercontinuum increases. The solitonic coherence shows much slower degradation than the overall coherence.