McCumber relation

McCumber relation

The McCumber relation (or McCumber theory) refers to the effective cross-sections of absorption and emission of light in the physics of solid-state lasers [1][2].

Contents

Definition

Let σa(ω) be the effective absorption cross-section σe(ω) be effective emission cross-sections at frequency ω, and let ~T~ be the effective temperature of the medium. The McCumbner relation is

(1) \frac{\sigma_{\rm e}(\omega)}{\sigma_{\rm a}(\omega)}\exp\!\left( \frac{\hbar \omega}{k_{\rm B} T}\right)
=\left(\frac{N_1}{N_2}\right)_T
=\exp\!\left( \frac{\hbar \omega_{\rm z}}{k_{\rm B} T}\right)

where  \left(\frac{N_1}{N_2}\right)_T is thermal steady-state ratio of populations; frequency ωz is called "zero-line" frequency [3][4]; \hbar is the Planck constant and kB is the Boltzmann constant. Note that the right-hand side of Equation (1) does not depend on ~\omega~.

Gain

It is typical that the lasing properties of a medium are determined by the temperature and the population at the excited laser level, and are not sensitive to the method of excitation used to achieve it. In this case, the absorption cross-section σa(ω) and the emission cross-section σe(ω) at frequency ~\omega~ can be related to the lasers gain in such a way, that the gain at this frequency can be determined as follows:

(2) ~~~~~~~~~~~~~~~G(\omega)=N_2 \sigma_{\rm e}(\omega)-N_1 \sigma_{\rm a}(\omega)

D.E.McCumber had postulated these properties and found that the emisison and absorption cross-sections are not independent [1][2]; they are related with Equation (1).

Idealized atoms

In the case of an idealized two-level atom the detailed balance for the emission and absorption which preserves the Max Planck formula for the black body radiation leads to equality of cross-section of absorption and emission. In the solid-state lasers the splitting of each of laser levels leads to the broadening which greatly exceeds the natural spectral linewidth. In the case of an ideal two-level atom, the product of the linewidth and the lifetime is of order of unity, which obeys the Heisenberg uncertainty principle. In solid-state laser materials, the linewidth is several orders of magnitude larger so the spectra of emission and absorption are determined by distribution of excitation among sublevels rather than by the shape of the spectral line of each individual transition between sublevels. This distribution is determined by the effective temperature within each of laser levels. The McCumber hypothesis is that the distribution of excitation among sublevels is thermal. The effective temperature determines the spectra of emission and absorption ( The effective temperature is called a temperature by scientists even if the excited medium as whole is pretty far from the thermal state )

Deduction of the McCumber relation

Fig.1. Sketch of sublevels

Consider the set of active centers (fig.1.). Assume fast transition between sublevels within each level, and slow transition between levels. According to the McCumber hypothesis, the cross-sections σa and σe do not depend on the populations N1 and N2. Therefore, we can deduce the relation, assuming the thermal state.

Let ~v(\omega)~ be group velocity of light in the medium, the product ~n_2\sigma_{\rm e}(\omega) v(\omega)D(\omega)~ is spectral rate of stimulated emission, and ~n_1\sigma_{\rm a}(\omega) v(\omega)D(\omega)~ is that of absorption; a(ω)n2 is spectral rate of spontaneous emission. (Note that in this approximation, there is no such thing as a spontaneous absorption) The balance of photons gives:

(3) ~~~
n_2\sigma_{\rm e}(\omega) v(\omega)D(\omega)+n_2 a(\omega)=
n_1\sigma_{\rm a}(\omega) v(\omega)D(\omega)
~~~~~~~~~~~~~~~{\rm (balance)}

Which can be rewritten as

(4) ~~~
D(\omega)=
\frac{\frac{a(\omega)}{\sigma_{\rm e}(\omega) v(\omega)}}
{\frac{n_1}{n_2} \frac{\sigma_{\rm a}(\omega)}{\sigma_{\rm e}(\omega)}-1}
~~~~~~~~~~~~~~{\rm (D1)}

The thermal distribution of density of photons follows from blackbody radiation [5]

(5) ~~~
D(\omega)~=~
\frac{\frac{1}{\pi^2} \frac{\omega^2}{c^3}}
{\exp\!\left(\frac{\hbar\omega}{k_{\rm B}T}\right)-1}
~~~~~
{\rm (D2)}

Both (4) and (5) hold for all frequencies ~\omega~. For the case of idealized two-level active centers, ~\sigma_{\rm a}(\omega)=\sigma_{\rm e}(\omega)~, and ~n_1/n_2=\exp\!\left( \frac{\hbar\omega}{k_{\rm B}T} \right), which leads to the relation between the spectral rate of spontaneous emission a(ω) and the emission cross-section ~\sigma_{\rm e}(\omega)~ [5]. (We keep the term probability of emission for the quantity ~a(\omega){\rm d}\omega{\rm d}t~, which is probability of emission of a photon within small spectral interval ~(\omega,\omega+{\rm d}\omega)~ during a short time interval ~(t,t+{\rm d}t)~, assuming that at time ~t~ the atom is excited.) The relation (D2) is a fundamental property of spontaneous and stimulated emission, and perhaps the only way to prohibit a spontaneous break of the thermal equilibrium in the thermal state of excitations and photons.

For each site number ~s~, for each sublevel number j, the partial spectral emission probability ~a_{s,j}(\omega)~ can be expressed from consideration of idealized two-level atoms [5]:

(6) ~~~
a_{s,j}(\omega)=\sigma_{s,j}(\omega)
\frac{\omega^2 v(\omega)}{\pi^2c^3}~~.
~~~~~~~~~~~~~~~~{\rm comparison1}
~~{\rm partial}

Neglecting the cooperative coherent effects, the emission is additive: for any concentration ~q_{s}~ of sites and for any partial population ~n_{s,j}~ of sublevels, the same proportionality between ~a~ and ~\sigma_{\rm e}~ holds for the effective cross-sections:

(7) 
\frac{a(\omega)}{\sigma_{\rm e}(\omega)}=
\frac{\omega^2 v(\omega)}{\pi^2c^3}
~~~~~~~~~~~~~~~~~~(\rm comparison)(av)

Then, the comparison of (D1) and (D2) gives the relation

(8) 
\frac{n_1}{n_2}
\frac{\sigma_{\rm a}(\omega)}
{\sigma_{\rm e}(\omega)}=
\exp\!\left( \frac{\hbar\omega}{k_{\rm B}T}\right)~~.
~~~~~~~~{\rm (n1n2) (mc1)}

This relation is equivalent of the McCumber relation (mc), if we define the zero-line frequency ωZ as solution of equation

(9) ~\left(\frac{n_2}{n_1}\right)_{\!T}=
\exp\!\left(\frac{\hbar \omega_{\rm Z}}{k_{\rm B}T}\right)~~~~,~~~

the subscript ~T~ indicates that the ratio of populations in evaluated in the thermal state. The zero-line frequency can be expressed as

(10)  \omega_{\rm Z}=\frac{k_{\rm B}T}{\hbar}
\ln \left(\frac{n_1}{n_2}\right)_{T} ~~~~~~~~~~~~~~~~.~~{(\rm oz)}

Then (n1n2) becomes equivalent of the McCumber relation (mc).

No specific property of sublevels of active medium is required to keep the McCumber relation. It follows from the assumption about quick transfer of energy among excited laser levels and among lower laser levels. The McCumber relation (mc) has the same range of validity as the concept of the emission cross-section itself.

Confirmation of the McCumber relation

The McCumber relation is confirmed for various media [6][7]. In particular relation (1) makes it possible to approximate two functions of frequency, emission and absorption cross sections, with single fit [8].

Violation of the McCumber relation and perpetual motion

Fig.2. Cross-sections for Yb:Gd2SiO5 versus  \lambda=\frac{2\pi c}{\omega}

In 2006 the strong violation of McCumber relation was "observed" for Yb:Gd2SiO5 and reported in 3 independent journals[9][10][11]. Typical behaivor of the cross-sections reported is shown in FIg.2 with thick curves. The emission cross-section is practically zero at wavelength 975 nm; this property makes Yb:Gd2SiO5 an excellent material for efficient solid-state lasers.

However, the property reported (thick curves) is not compatible with the Second Law of thermodynamics. With such a material, the Perpetual motion device would be possible. It would be sufficient to fill a box with reflecting walls with Yb:Gd2SiO5 and allow it to exchange radiation with a blackbody through a spectrally-selective window which is transparent in vicinity of 975 nm and reflective at other wavelengths. Due to the lack of emissivity at 975 nm the medium should warm, breaking the thermal equilibrium.

On the base of the Second Law of thermodynamics, the experimental results [9][10][11] were refuted in 2007. WIth the McCumner theory, the correction was suggested for the effective emission cross section (black thin cirve) [3]. Then this correction was confirmed experimentally[12].

References

  1. ^ a b D.E.McCumber. Einstein relations connecting broadband emission and absorption spectra. PRB 136 (4A), 954–957 (1964)
  2. ^ a b P.C.Becker, N.A.Olson, J.R.Simpson. Erbium-doped fiber amplifiers: fundamentals and theory (Academic, 1999).
  3. ^ a b D. Kouznetsov (2007). "Comment on Efficient diode-pumped Yb:Gd2SiO5 laser (Appl.Phys.Lett.88,221117(2006))". APL 90: 066101. http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=APPLAB000090000006066101000001&idtype=cvips&gifs=yes. 
  4. ^ D.Kouznetsov (2007). "Broadband laser materials and the McCumber relation" (– Scholar search). Chinese Optics Letters 5: S240–S242. http://col.org.cn/getArticle.aspx?id=OJ070715000250D0GcIf. [dead link]
  5. ^ a b c e2
  6. ^ R.S.Quimby (2002). "Range of validity of McCumber theory in relating absorption and emission cross sections". J. Appl. Phys. 92: 180–187. Bibcode 2002JAP....92..180Q. doi:10.1063/1.1485112. http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=JAPIAU000092000001000180000001. 
  7. ^ R.M.Martin; R.S.Quimby (2006). "Experimental evidence of the validity of the McCumber theory relating emission and absorption for rare-earth glasses". JOSAB 23 (9): 1770–1775. Bibcode 2006JOSAB..23.1770M. doi:10.1364/JOSAB.23.001770. http://josab.osa.org/abstract.cfm?id=97826. 
  8. ^ D.Kouznetsov; J.-F.Bisson, K.Takaichi, K.Ueda (2005). "Single-mode solid-state laser with short wide unstable cavity". JOSAB 22 (8): 1605–1619. Bibcode 2005JOSAB..22.1605K. doi:10.1364/JOSAB.22.001605. http://josab.osa.org/abstract.cfm?id=84730. 
  9. ^ a b W. Li; H. Pan, L. Ding, H. Zeng, W. Lu, G. Zhao, C. Yan, L. Su, J. Xu. (2006). "Efficient diode-pumped Yb:Gd2SiO5 laser". APL 88: 221117. http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=APPLAB000088000022221117000001. 
  10. ^ a b W.Li; H.Pan, L.Ding, H.Zeng, G.Zhao, C.Yan, L.Su, J.Xu (2006). year=2006 "Diode-pumped continuous-wave and passively mode-locked Yb:Gd2SiO5laser". Optics Express 14 (2): 686–695. Bibcode 2006OExpr..14..686L. doi:10.1364/OPEX.14.000686. http://www.opticsexpress.org/search.cfm year=2006. 
  11. ^ a b C.Yan; G.Zhao, L.Zhang, J.Xu, X.Liang, D.Juan, W.Li, H.Pan, L.Ding, H.Zeng. (2006). "A new Yb-doped oxyorthosilicate laser crystal: Yb:Gd2SiO5". Solid State Communications 137 (8): 451–455. Bibcode 2006SSCom.137..451Y. doi:10.1016/j.ssc.2005.12.023. http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6TVW-4HYTYFW-3&_user=10&_coverDate=02%2F28%2F2006&_alid=615430684&_rdoc=1&_fmt=summary&_orig=search&_cdi=5545&_sort=d&_docanchor=&view=c&_ct=1&_acct=C000050221&_version=1&_urlVersion=0&_userid=10&md5=b6673cac47762a0184b56a206d31ccd6. 
  12. ^ G.Zhao; L.Su, J.Xua, and H.Zeng (2007). "Response to Comment on Efficient diode-pumped Yb:Gd2SiO5 laser (Appl. Phys. Lett. 90, 066101 2007)". APL 90: 066103. http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=APPLAB000090000006066103000001&idtype=cvips&gifs=yes. 

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