Two-photon laser-induced fluorescence of sodium in multiphase combustion

Keke Zhu; Stuart J. Barkley; Chloe E. Dedic; Travis R. Sippel; James B. Michael

doi:10.1364/AO.392710

Applied Optics
Vol. 59,
Issue 18,
pp. 5632-5641
(2020)
•https://doi.org/10.1364/AO.392710

Two-photon laser-induced fluorescence of sodium in multiphase combustion

Keke Zhu, Stuart J. Barkley, Chloe E. Dedic, Travis R. Sippel, and James B. Michael

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Keke Zhu, Stuart J. Barkley, Chloe E. Dedic, Travis R. Sippel, and James B. Michael, "Two-photon laser-induced fluorescence of sodium in multiphase combustion," Appl. Opt. 59, 5632-5641 (2020)

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- Spectroscopy
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About this Article
History
- Original Manuscript: March 13, 2020
- Revised Manuscript: May 15, 2020
- Manuscript Accepted: May 18, 2020
- Published: June 19, 2020

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Abstract

Alkali metals are prevalent in coal combustion, biomass thermal conversion to fuels, and energetic material combustion, and have applications as dopants for combustion diagnostics and plasma-based combustion control. Recently, the dynamic control of propellant burning rate and pyrotechnic luminosity have been demonstrated through combined microwave field radiation and incorporation of alkali dopants. Understanding of the alkali distribution within the flame is essential to predicting field–flame interaction. However, the multiphase propellant combustion environment exhibits significant particle scattering, broadband emission background, and high optical density, which complicate optical measurements. Here, multiple two-photon laser-induced fluorescence (LIF) schemes for atomic sodium were compared in gas-phase flames and sodium-doped solid propellant combustion. For the two-photon Na LIF scheme, a rate equation model incorporating fluorescence, amplified spontaneous emission, and ionization shows good agreement with experimental characterization in a gas-phase flame. The technique was then extended to sodium-doped solid propellant flames, a multiphase combustion environment characterized by strong particle scattering. The 3s–3d two-photon excitation LIF achieved a better signal-to-noise ratio of ${\sim}100$ in the propellant flame and allowed imaging of gradients in the gas-phase sodium distribution at the burning surface.

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Premixed Gas-Phase Flames
Burner	Natural gas	Air	Solvent/ $N a N O_{3}$	Predicted equilibrium
Burner	(SLPM)	(SLPM)	Concentration ( $g / L$ )	Na concentration (PPM)
Premixed	0.5	5.6	$H_{2} O / 360 g / L$	50
Composite Propellant Flame
Al (wt.%)	$N a N O_{3}$ (wt.%)		AP/HTPB (wt.%)	Predicted equilibrium (Na PPM)
14.5	3.5		70/12	2510

Parameters	Values	Units	Reference
$α_{1, 3}$ (3s–3d)	$1.180 \times 10^{- 28}$	${c m}^{4} / W$	Calculated
$σ_{ion}$ (3d)	$1.418 \times 10^{- 17}$	${c m}^{2}$	Calculated
$A_{3, 2}$ (3d–3p)	$5.14 \times 10^{7}$	$s^{- 1}$	[38]
$A_{2, 1}$ (3p–3s)	$6.25 \times 10^{7}$	$s^{- 1}$	[38]
$Q$ (3d, 3p)	$1.63 \times 10^{9}$	$s^{- 1}$	[32]

Premixed Gas-Phase Flames
Burner	Natural gas	Air	Solvent/ $N a N O_{3}$	Predicted equilibrium
Burner	(SLPM)	(SLPM)	Concentration ( $g / L$ )	Na concentration (PPM)
Premixed	0.5	5.6	$H_{2} O / 360 g / L$	50
Composite Propellant Flame
Al (wt.%)	$N a N O_{3}$ (wt.%)		AP/HTPB (wt.%)	Predicted equilibrium (Na PPM)
14.5	3.5		70/12	2510

Parameters	Values	Units	Reference
$α_{1, 3}$ (3s–3d)	$1.180 \times 10^{- 28}$	${c m}^{4} / W$	Calculated
$σ_{ion}$ (3d)	$1.418 \times 10^{- 17}$	${c m}^{2}$	Calculated
$A_{3, 2}$ (3d–3p)	$5.14 \times 10^{7}$	$s^{- 1}$	[38]
$A_{2, 1}$ (3p–3s)	$6.25 \times 10^{7}$	$s^{- 1}$	[38]
$Q$ (3d, 3p)	$1.63 \times 10^{9}$	$s^{- 1}$	[32]

Abstract

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Equations (13)

Applied Optics