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References

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  1. Callender, Roy. Soc., Trans., Vol.  178, p. 161, 1887.
    [CrossRef]
  2. Callender and Griffiths, Roy. Soc. Trans., Vol.  182, p. 123, 1891.
  3. Holborn and Grüneisen, Ann. der Phys., Vol.  311, p. 136, 1901.
    [CrossRef]
  4. Thiesen, Sheel, and Sell, Zeits. f. Instk., Vol.  16, p. 49, 1896.
  5. Henning, Ann. der Phy., Vol.  22, p. 631, 1907.
    [CrossRef]
  6. M. So, Tokyo Math. Phy., Soc. Proc., Vol.  9, p. 425, 1917-18.
  7. Fizeau, Ann. der Phy., Vol.  128, p. 564, 1866.
    [CrossRef]
  8. Pulfrich, Zeits. f. Instk., Vol.  13, p. 365, 1893.
  9. Reimerdes, Dissertation Jena, 1896.
  10. Hovestadt, “Jena Glass,” p. 234.
  11. Dorsey, Phys. Rev., Vol.  25, p. 88, 1907.
  12. Tool and Valasek, .
  13. Peters, Phys. Rev., p. 147, Feb., 1919.
  14. Pulfrich, Zeits. f. Instk., Vol.  14, p. 261, 1898.
  15. Meggers and Peters, , 1918.
  16. Souder and Hidnert, .
  17. White, Am. Jour. Sci., Vol.  XLVI, Jan., 1919.
  18. Feild and Royster, , 1918.

1919 (2)

Peters, Phys. Rev., p. 147, Feb., 1919.

White, Am. Jour. Sci., Vol.  XLVI, Jan., 1919.

1907 (2)

Henning, Ann. der Phy., Vol.  22, p. 631, 1907.
[CrossRef]

Dorsey, Phys. Rev., Vol.  25, p. 88, 1907.

1901 (1)

Holborn and Grüneisen, Ann. der Phys., Vol.  311, p. 136, 1901.
[CrossRef]

1898 (1)

Pulfrich, Zeits. f. Instk., Vol.  14, p. 261, 1898.

1896 (1)

Thiesen, Sheel, and Sell, Zeits. f. Instk., Vol.  16, p. 49, 1896.

1893 (1)

Pulfrich, Zeits. f. Instk., Vol.  13, p. 365, 1893.

1891 (1)

Callender and Griffiths, Roy. Soc. Trans., Vol.  182, p. 123, 1891.

1887 (1)

Callender, Roy. Soc., Trans., Vol.  178, p. 161, 1887.
[CrossRef]

1866 (1)

Fizeau, Ann. der Phy., Vol.  128, p. 564, 1866.
[CrossRef]

Callender,

Callender and Griffiths, Roy. Soc. Trans., Vol.  182, p. 123, 1891.

Callender, Roy. Soc., Trans., Vol.  178, p. 161, 1887.
[CrossRef]

Dorsey,

Dorsey, Phys. Rev., Vol.  25, p. 88, 1907.

Feild,

Feild and Royster, , 1918.

Fizeau,

Fizeau, Ann. der Phy., Vol.  128, p. 564, 1866.
[CrossRef]

Griffiths,

Callender and Griffiths, Roy. Soc. Trans., Vol.  182, p. 123, 1891.

Grüneisen,

Holborn and Grüneisen, Ann. der Phys., Vol.  311, p. 136, 1901.
[CrossRef]

Henning,

Henning, Ann. der Phy., Vol.  22, p. 631, 1907.
[CrossRef]

Hidnert,

Souder and Hidnert, .

Holborn,

Holborn and Grüneisen, Ann. der Phys., Vol.  311, p. 136, 1901.
[CrossRef]

Hovestadt,

Hovestadt, “Jena Glass,” p. 234.

Meggers,

Meggers and Peters, , 1918.

Peters,

Peters, Phys. Rev., p. 147, Feb., 1919.

Meggers and Peters, , 1918.

Pulfrich,

Pulfrich, Zeits. f. Instk., Vol.  14, p. 261, 1898.

Pulfrich, Zeits. f. Instk., Vol.  13, p. 365, 1893.

Reimerdes,

Reimerdes, Dissertation Jena, 1896.

Royster,

Feild and Royster, , 1918.

Sell,

Thiesen, Sheel, and Sell, Zeits. f. Instk., Vol.  16, p. 49, 1896.

Sheel,

Thiesen, Sheel, and Sell, Zeits. f. Instk., Vol.  16, p. 49, 1896.

So, M.

M. So, Tokyo Math. Phy., Soc. Proc., Vol.  9, p. 425, 1917-18.

Souder,

Souder and Hidnert, .

Thiesen,

Thiesen, Sheel, and Sell, Zeits. f. Instk., Vol.  16, p. 49, 1896.

Tool,

Tool and Valasek, .

Valasek,

Tool and Valasek, .

White,

White, Am. Jour. Sci., Vol.  XLVI, Jan., 1919.

Am. Jour. Sci. (1)

White, Am. Jour. Sci., Vol.  XLVI, Jan., 1919.

Ann. der Phy. (2)

Fizeau, Ann. der Phy., Vol.  128, p. 564, 1866.
[CrossRef]

Henning, Ann. der Phy., Vol.  22, p. 631, 1907.
[CrossRef]

Ann. der Phys. (1)

Holborn and Grüneisen, Ann. der Phys., Vol.  311, p. 136, 1901.
[CrossRef]

Phys. Rev. (2)

Dorsey, Phys. Rev., Vol.  25, p. 88, 1907.

Peters, Phys. Rev., p. 147, Feb., 1919.

Roy. Soc. Trans. (1)

Callender and Griffiths, Roy. Soc. Trans., Vol.  182, p. 123, 1891.

Roy. Soc., Trans. (1)

Callender, Roy. Soc., Trans., Vol.  178, p. 161, 1887.
[CrossRef]

Tokyo Math. Phy., Soc. Proc. (1)

M. So, Tokyo Math. Phy., Soc. Proc., Vol.  9, p. 425, 1917-18.

Zeits. f. Instk. (3)

Pulfrich, Zeits. f. Instk., Vol.  14, p. 261, 1898.

Thiesen, Sheel, and Sell, Zeits. f. Instk., Vol.  16, p. 49, 1896.

Pulfrich, Zeits. f. Instk., Vol.  13, p. 365, 1893.

Other (6)

Reimerdes, Dissertation Jena, 1896.

Hovestadt, “Jena Glass,” p. 234.

Meggers and Peters, , 1918.

Souder and Hidnert, .

Tool and Valasek, .

Feild and Royster, , 1918.

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Figures (21)

F. 1
F. 1

Interferometer.

F. 2
F. 2

Electric furnace.

F. 3
F. 3

Thermal dilatation of optical glass.

F. 4
F. 4

Thermal dilatation of barium flint glass, B.S. 145.

F. 5
F. 5

Thermal dilatation of barium flint glass, B.S. 145.

F. 6
F. 6

Thermal dilatation of plate glass.

F. 7
F. 7

Thermal dilatation of plate glass.

F. 8
F. 8

Thermal dilatation of optical glass.

F. 9
F. 9

Thermal dilatation of optical glass.

F. 10
F. 10

Thermal dilatation of optical glass.

F. 11
F. 11

Thermal dilatation of commercial glass.

F. 12
F. 12

Thermal dilatation of chemical glassware.

F. 13
F. 13

Thermal dilatation of chemical glassware and commercial glass.

F. 14
F. 14

Thermal dilatation of commercial glass.

F. 15
F. 15

Thermal dilatation of vacuum tube glass.

F. 16
F. 16

Thermal dilatation of thermometer glass.

F. 17
F. 17

Contraction of glass at constant temperature.

F. 18
F. 18

Rate of contraction of glass.

F. 19
F. 19

Thermal dilatation by the micrometric method.

F. 20
F. 20

Thermal dilatation and heat absorption of barium crown glass, B. S. 87.

F. 21
F. 21

Thermal dilatation and heat absorption of light flint glass, B. S. 188.

Tables (5)

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Table II Mean Coefficient of Linear Expansion.

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Table III Chemical Composition.

Equations (11)

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C = Δ L L · Δ t
Δ N = 2 L + Δ L λ υ 2 L λ υ
C = λ υ Δ N 2 L Δ t
Δ N = 2 L + Δ L λ 2 2 L λ 1 = 2 ( L + Δ L λ υ · λ υ λ 2 L λ υ · λ υ λ 1 ) = 2 ( L + Δ L λ υ · n 2 L λ υ · n 1 )
n p , t 1 n o 1 = 273 T P 760
n 1 = 1 + ( n o 1 ) 273 760 P 1 T 1
n 2 = 1 + ( n o 1 ) 273 760 P 2 T 2
Δ L = λ υ Δ N 2 + L ( n o 1 ) 273 760 ( P 1 T 1 P 2 T 2 ) 1 + ( n o 1 ) 273 P 2 760 T 2
Δ L = λ υ Δ N 2 + L ( n o 1 ) 273 760 ( P 1 T 1 P 2 T 2 )
C = Δ L L Δ t = λ υ Δ N 2 L Δ t + 273 760 ( n o 1 ) Δ t ( P 1 T 1 P 2 T 2 )
Δ L L = λ υ Δ N 2 L + 273 760 ( n o 1 ) ( P 1 T 1 P 2 T 2 )