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Exact generalized Fokker-Planck equation for arbitrary dissipative quantum systems
Volume 28A, number
PHYSICS
4
2 December
LETTERS
ute to the Kr specific
heat. A detailed discussion of this work will appear in a forthcoming paper.
1968
1. J. S.Brown and G.K.Horton,
Phys. Rev. Letters 18 (1967) 647. 2. G. Jelinek, private communication. 3. S. L.Ruby, Y. Hazoni and M. Pasternak, Phys. Rev.
129 (196$ 826. 4. S. Margulies and J. R. Ehrman, Nucl. Instr. Methods 12 (1961) 131. 5. M. Pasternak, A. Simopoulos, S. Bukshpan and T. Sonnino, Phys. Letters 22 (1966) 52. 6. R.H.Beaumont, H. Chihara and J.A.Morrison, Proc Phys. Sot. (London) 78 (1961) 1462.
We gratefully acknowledge helpful discussions with S. L. Ruby, R. 0. Simmons, B. J. Alder, R. J. Borg, R. Booth, R. Ohlwiler, D. N. Pipkorn and H. L. Sahlin.
*****
EXACT
GENERALIZED ARBITRARY
I. Institut
FOKKER-PLANCK
DISSIPATIVE
QUANTUM
H .HAKEN ftir theoretische Physik Stuttgart, Received
der
FOR
SYSTEMS
Universith’t,
Gemzany
17 October
We derive an explicit and exact partial differential vided the system is described by a density matrix
EQUATION
equation question.
1968
for
a c-number
distribution
function,
pro-
We consider a quantum system which is coupled to reservoirs (or heatbaths). We assume as usual that the heatbath variables may be eliminated by second order perturbation theory. Provided the heatbaths are Markoffian (i.e., they have a short memory), the resulting density matrix equation may be written in the form [l] *:
(1) The first term on the right hand side describes the coherent motion of the system, the sum represents dissipation and fluctuation. In the following we drop the first term, since otherwise the final result (3) would become too lengthy. (It can be easily treated, however). The Pik’s are the usual projection operators from quantum state k to quantum state i with the property Pik Plm = Pim dkl . We associate with each Pfk a classical variable “ik and define a distribution functionf(v) by f(v) = N J exp (- z? vipik)
tr (E
eltp (X;k P&P)
{d&}
.
(2)
N is the normalization
constant. The product is arranged in such a way that (from left to right) i < k, then i = k, and finally i > k. The path of.integrations is to be chosen appropriately. A function of the type (2) had been introduced previously by Haken et al. [2], who derived an exact Fokker-Planck type equation for two-level atoms. As had been shown there 121, such a function allows to calculate all expectation values, even if mul; ti-time averages (with time-ordered operators) are required. The non-trivial task consists in deriving an equation of motion for f(v). Starting from eq. (l), we have derived such an equation in the following form: (3) * Our procedure
286
of deriving
an equation of the type (3) can be easily
extended to non-Markoffian
reservoirs.
Volume 28A, number 4
PHYSICS
LETTERS
2 December 1968
a
Using the rule xik - - we define Mxp as follows: svik Mxc, (x) = ,&A- zkmn A&lk cml,Ip e~hm with AZ,, erwise.
= Oka n (iii, XGi = Xmi ; X&i
- Xm*i6i> ,);
(4)
- *El)
&im is the Kronecker symbol, bi>m = 1 for i > m and = 0 oth-
= Xim. oksn=b*+C
xkll ‘X1112 - 1. Xlln with k < I1 < 12 . . < n for the
upper arrow, provided k 11 > 12 . . > Zj > n for the lower arrow, provided k 2 n . Otherwise 0 vanishes. C[klm is defined by 6i.l (bkm - Xkm bm? k (1 - bib))
for igk,
bk,
for i > k,l > m ,
0
eq(-xii
+ Xkk)(&il -
li 61, i)
lsrn
,
otherwise
Finally, Uli = 1 for 1 > i , oli = 0 for 1 = i , and oli = -1 for 1 < i . There are two constraints in eqs. (1) and (2) to be observed: 1) Be ause we want a real distri tion function, f, we postulate %jk = Vij . 2) Gil account Of C! Pjj = 1 one has to require bE V” 21-- 1* In subsequent publications we will show that eq. (3) has widespread applications, e.g., in the theory of lasers and asers, non-linear quantum optics, spin resonance, spin waves, and phase transitions. Our above tre ment includes the harmonic oscillator and, more generally, the lightfield in its quan5 tized form. Gn the other hand, for this case classical distribution functions can be defined in the form of the Wigner function [3] or by means of the diagonal coherent state representation of Glauber [4] and Sudarshan [5]. ‘It will be demonstrated in a forthcoming paper that these representations can be obtained from the representation (2) by a suitable projection technique. -X~j
vjk
,
=
The author wishes to thank Dipl. Phys. H. Vollmer and Professor W. Weidlich for several useful discussions, and bipl. Phys. P.Reinker for checking some of the results.
References 1. Density matri equations for different systems were derived by a number of authors, in particular by R. K. Wangsne s and F. Bloch, Phys. Rev. 89 (1953) 728. P. N. Argyres, in: Magnetic and electric resonance and relaxation, ed. J. Smidt (North-Holland, Amsterdam, 1963) p, 555. W. Weidlich and F. Haake, Z. Physik 185 (1965) 30; 186 (1965) 203. C. R. Willis, Phys. Rev. 147 (1966) 406. 2. H. Haken, H. Risken and W. Weidlich, Z. Physik 206 (1967) 355. 3. E. P. Wiener. Phvs. Rev. 40 (1932) 749; J. E. Moial, .Proc. Cambridge Phil. Sot. 45 (1949) 99. 4. R. J. Glauber. ‘Phvs. Rev. 130 (1963) 2529; 131 (1963) 2766. 5. E. C. G. Sudar$h&, Phys. Rev.‘Letters 10 (1963) 277.
287
PHYSICS
4
2 December
LETTERS
ute to the Kr specific
heat. A detailed discussion of this work will appear in a forthcoming paper.
1968
1. J. S.Brown and G.K.Horton,
Phys. Rev. Letters 18 (1967) 647. 2. G. Jelinek, private communication. 3. S. L.Ruby, Y. Hazoni and M. Pasternak, Phys. Rev.
129 (196$ 826. 4. S. Margulies and J. R. Ehrman, Nucl. Instr. Methods 12 (1961) 131. 5. M. Pasternak, A. Simopoulos, S. Bukshpan and T. Sonnino, Phys. Letters 22 (1966) 52. 6. R.H.Beaumont, H. Chihara and J.A.Morrison, Proc Phys. Sot. (London) 78 (1961) 1462.
We gratefully acknowledge helpful discussions with S. L. Ruby, R. 0. Simmons, B. J. Alder, R. J. Borg, R. Booth, R. Ohlwiler, D. N. Pipkorn and H. L. Sahlin.
*****
EXACT
GENERALIZED ARBITRARY
I. Institut
FOKKER-PLANCK
DISSIPATIVE
QUANTUM
H .HAKEN ftir theoretische Physik Stuttgart, Received
der
FOR
SYSTEMS
Universith’t,
Gemzany
17 October
We derive an explicit and exact partial differential vided the system is described by a density matrix
EQUATION
equation question.
1968
for
a c-number
distribution
function,
pro-
We consider a quantum system which is coupled to reservoirs (or heatbaths). We assume as usual that the heatbath variables may be eliminated by second order perturbation theory. Provided the heatbaths are Markoffian (i.e., they have a short memory), the resulting density matrix equation may be written in the form [l] *:
(1) The first term on the right hand side describes the coherent motion of the system, the sum represents dissipation and fluctuation. In the following we drop the first term, since otherwise the final result (3) would become too lengthy. (It can be easily treated, however). The Pik’s are the usual projection operators from quantum state k to quantum state i with the property Pik Plm = Pim dkl . We associate with each Pfk a classical variable “ik and define a distribution functionf(v) by f(v) = N J exp (- z? vipik)
tr (E
eltp (X;k P&P)
{d&}
.
(2)
N is the normalization
constant. The product is arranged in such a way that (from left to right) i < k, then i = k, and finally i > k. The path of.integrations is to be chosen appropriately. A function of the type (2) had been introduced previously by Haken et al. [2], who derived an exact Fokker-Planck type equation for two-level atoms. As had been shown there 121, such a function allows to calculate all expectation values, even if mul; ti-time averages (with time-ordered operators) are required. The non-trivial task consists in deriving an equation of motion for f(v). Starting from eq. (l), we have derived such an equation in the following form: (3) * Our procedure
286
of deriving
an equation of the type (3) can be easily
extended to non-Markoffian
reservoirs.
Volume 28A, number 4
PHYSICS
LETTERS
2 December 1968
a
Using the rule xik - - we define Mxp as follows: svik Mxc, (x) = ,&A- zkmn A&lk cml,Ip e~hm with AZ,, erwise.
= Oka n (iii, XGi = Xmi ; X&i
- Xm*i6i> ,);
(4)
- *El)
&im is the Kronecker symbol, bi>m = 1 for i > m and = 0 oth-
= Xim. oksn=b*+C
xkll ‘X1112 - 1. Xlln with k < I1 < 12 . . < n for the
upper arrow, provided k
for igk,
bk,
for i > k,l > m ,
0
eq(-xii
+ Xkk)(&il -
li 61, i)
lsrn
,
otherwise
Finally, Uli = 1 for 1 > i , oli = 0 for 1 = i , and oli = -1 for 1 < i . There are two constraints in eqs. (1) and (2) to be observed: 1) Be ause we want a real distri tion function, f, we postulate %jk = Vij . 2) Gil account Of C! Pjj = 1 one has to require bE V” 21-- 1* In subsequent publications we will show that eq. (3) has widespread applications, e.g., in the theory of lasers and asers, non-linear quantum optics, spin resonance, spin waves, and phase transitions. Our above tre ment includes the harmonic oscillator and, more generally, the lightfield in its quan5 tized form. Gn the other hand, for this case classical distribution functions can be defined in the form of the Wigner function [3] or by means of the diagonal coherent state representation of Glauber [4] and Sudarshan [5]. ‘It will be demonstrated in a forthcoming paper that these representations can be obtained from the representation (2) by a suitable projection technique. -X~j
vjk
,
=
The author wishes to thank Dipl. Phys. H. Vollmer and Professor W. Weidlich for several useful discussions, and bipl. Phys. P.Reinker for checking some of the results.
References 1. Density matri equations for different systems were derived by a number of authors, in particular by R. K. Wangsne s and F. Bloch, Phys. Rev. 89 (1953) 728. P. N. Argyres, in: Magnetic and electric resonance and relaxation, ed. J. Smidt (North-Holland, Amsterdam, 1963) p, 555. W. Weidlich and F. Haake, Z. Physik 185 (1965) 30; 186 (1965) 203. C. R. Willis, Phys. Rev. 147 (1966) 406. 2. H. Haken, H. Risken and W. Weidlich, Z. Physik 206 (1967) 355. 3. E. P. Wiener. Phvs. Rev. 40 (1932) 749; J. E. Moial, .Proc. Cambridge Phil. Sot. 45 (1949) 99. 4. R. J. Glauber. ‘Phvs. Rev. 130 (1963) 2529; 131 (1963) 2766. 5. E. C. G. Sudar$h&, Phys. Rev.‘Letters 10 (1963) 277.
287