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Non-inertial accelerations in the theory of molecular dynamics
Journal of Molecular Liquids, 33 (1987) 119-126
119
ElsevierSciencePublishersB.V.,Amsterdam-Printed
NON-INERTIAL
ACCELERATIONS
inTheNetherlands
IN THE THEORY OF MOLECULAR
DYNAMICS
M.W. EVANS
Dept. of Physics, Swansea
University
SA2 SPP, WAles,
(Received
College
of Swansea,
Singleton
Park,
(UK).
14 July 1986)
ABSTRACT
By repeated reference
non-inertial
of computer
acceleration
simulation
of some of these new statistical the conventional
methods
in the rotating
ensemble.
can be used to illustrate which
correlations,
built
frame of
of ways exist of correlating
terms in a molecular
using diffusion
fields can be conveniently revealing
operators
it is shown that a large number
fundamental technique
use of differential
equations.
in to the rotating
The
the time dependence
cannot be described
with
The effect of external frame analysis,
many new correlations.
INTRODUCTION
The new rotating to the molecular
frame theory of molecular
dynamics
transformation possible realised.
Cl1
Using
the result
No spectral method computer
the simplest,
the influence fields
correlations
(c.c.f. 's) is increased
0167-7322/87/$03.50
here to include new
of
has not been explicitly on any of these
Standard C2,31
simplifying
diffusion
cannot be used to assumption.
and electromagnetic
When
force
the extra torque due to the the number of possible
considerably.
between molecules
frame method,
equations
magnetic,
of liquid crystals,
of cross-correlations rotating
electric,
applied
of frame
information
on a very few.
[41, or alternatively
potentials
direct
and Kramers
recently
of a very large number
whose existence
can provide
even with considerable
of external
is included
director
is the generation
simulation
theory, based on Fokker-Planck describe
the simple mathematics
auto and cross-correlations
and contemporary
top, is extended
of an asymmetric
types of cross-correlation.
diffusion,
results
of new possibilities
Similarly,
crossconsideration
in the emergence,
from the
when dealing with the collective
0 1987 Elsevier Science PublishersB.V.
120 correlations
of the molecular
liquid state.
all emerge from a very simple mathematical number of possible mathematically, exists.
auto and cross-correlation
the majority
Therefore,
infinite,
because
the minority
physical
implications
describe
molecular
vanishes
generated
by syrmnetry for all t;
the total number
of possible
diffusion
Neither
nor the hydrodynamical
things stand at present.
approach
theories
which may be used to approximate functions
simulation
The general
of external
force fields
Cll,lZl
.
function
and its quantum mechanical [ll], then the existence
experimental
under favourable
equivalent,
conditions,
a broad band,
quantum
theoretically,
features,
DEVELOPMENT
Consider
This defines higher
wave functions
Let gfs to
the differential
derivatives
m = (1,2,3)',
Let c be the position
in each frame.
This
of a very large number
frame f = (x,y,z) at the angular
centre of mass relative
types of
produces, work of
is associated,
are mutually
influential
than meets
the eye.
FRAME THEORY
a frame of reference,
has the same origin.
which
type of lab. frame auto and cross-correlation
and translational
OF THE ROTATING
to the laboratory
molecule
is composed
Clll.
There is much more to a broad band, therefore,
113,141.
and c.c.f's
features,
normally
infra-red
sets of lines, each of which
with a particular
in which rotational
value of a wave
new a.c.f.'s
spectral
fields
correlation
could be linked to specific
such as that in the far
shows that the broad band absorption discrete
an expectation
of discrete
to
of molecular
the classical
The liquid state at room temperature
cross-correlation. however,
C41, and also of internal
of the many different
here would mean the emergence
method
with the specific
and the interaction
If we make the analogy between
function described
fields
of this as
of the cross - and
effect on ensemble
potential
or
laws that may be expected
approach may be those concerned
dynamics
capable
as a numerical
emerge from this fundmental
such as those caused by the director
(a.c.f.'s)
[2,31 based on Kramers
the time dependence
CS-101.
functions
141 seems remotely
This leaves computer
The
to
the time dependence
and auto-correlation
the diffusion
is
in number.
is intended
must be capable of describing
self-consistently.
but a minority
correlations
infinity
of this are that any theory which
cross-correlation
auto-correlation
Out of the infinite
functions
that exists also approaches
of all the existing
Langevin
These new cross-correlations treatment.
vector
which rotates with respect frequency,
be the linear velocity
of & in both frames.
Rf and $.
Each frame
of the molecular
(x,y,z) and Qrn$ that relative operators
w.
of the centre of mass of a
to (1,2,3)'.
Let us now examine
the
121 VELOCITIES
The velocities
Em6 = Qf’
where
-
in the fixed and rotating
x
l$
(2)
5
it is understood
respect
to frame
that all the terms on the r.h.s. are defined with
(1,2,3)',
The angular
(x,y,s).
frames are linked through:
and that on the 1.h.s. with respect
frequency
to frame
w is the same in both frames because
the rate at which one frame rotates with respect
it is
to the other.
ACCELERATIONS
The frame relations gf and $
providing
the forward
The eqn (4) introduces centripetal
the Newton
molecular
dynamics
of existence
conditions
C13,141,
other spectral
DERIVATIVES
equations
are written
they are important diffusion
counterparts, result
of the operators
transformations.
acceleration,
acceleration.
in a non-inertial
C6-91 theory
,
the
These appear context
Lll
.
For
and cannot be approximated C2,31
.
Naturally,
which may, under "particle
in discrete,
observable
out
they have
in the box"
infra red absorptions
and
features.
OF ACCELERATION
In this case the operators transforms,
and backward
and the non-uniform
as in standard
quantum mechanical
two applications
into the lab frame the Coriolis
acceleration
whenever
now involve
are applied
three times in the forward
and back
producing:
D3 = 2;~ + &( 28 x Frn@ + ~m!,(c&&) x f) + Qrn(!+x (& x z)) %fr +8x
I&+
* x (2% x grn:, + * x ((&&)
x f) + t x (g x (b x z))
(5)
122 D3 = & 2rmr +Ex Eqn
x 6) + gf(&
- ;f(2& x 2fZ) - 2f((Qf#) (2KX?f9
+tx
(6) shows the existence
((Rf&) x5)
of many higher
in the laboratory
in frame
(x,y,z) and some of the c.c.f. 's between Furthermore,
(x,y,z).
& (‘3)
for each
The a.c.f. 's of all of these exist the terms are allowed by
making use of the results:
<&W
- p&3(0)> #
0;
t#o
‘g,(t)
. l&O,’
0;
t
it becomes
- * x
(w x (&XX))
@X
order accelerations
molecule
symmetry.
frame
-
x (8 x z))
+
#o
clear that many new cross-correlations
are generated
in frame
(1,2,3)' and (x,y,s).
EXTERNAL
TORQUES
If the molecular acceleration intrinsic
ELECTRIC
term gft
acceleration
ensemble
is treated with an external
in frame
(x,y,z) must be rewritten
and a term due to the effect
field C2,4,121
the
as the sum of the
of the field.
FIELD
The extra angular
acceleration
where x is the molecular in the denominator
dipole,
DfK -
ti
and E the external
is the equivalent
The total angular
molecule.
due to the electric
inertia
acceleration
field is:
field strength.
Here gE
due to the effect of g on the
is therefore:
“B
(9)
Bg Substituting
this in eqns
(2), (4) and (6) immediately
lab. frame cross-correlation Taking
into account
molecule
functions
polarisability
involving
effects
C2,31
produces
a range of new
the field acceleration. the effective
field on each
is:
g = E, + E .p . E + EEE where 9 is the molecular
i y- +............
polarisability,
1 the hyper-polarisability,
(10) and so on.
123 Similar
considerations
external
magnetic
inevitable
of Lorentz
E = ,E, exp(i(wt 2.em
correlations
field vector
for example,
generated
go nearly
generate effect,
new cross
i.e. a torque and
field applied
Some diagonal
However
0.50 elements
x ($L$t) x F(t)).gl(O)
3. (3,3) element.
diffusion,
to produce
the relatively
to a molecular
hydrodynamical
these new correlation
primitive
methods
t(ps) of the cross-correlation
(1,2,3)
of
can be used to illustrate
I x V(O)>/[<,2>Z] %
frame of reference
2. (2,2) element.
of molecular
we now have available
0.25
in the moving
theories
into enough detail
analytically. simulation
cl Fig. 1.
automatically
the Buckingham
Cl21.
otherwise, functions
(11)
by an electromagnetic
None of the available
computer
is, as usual,
- k . ,R))
(2), (4), and (6) would through,
birefringence ensemble
forces.
FIELD
The electromagnetic
and from eqns
x H generated by a static % in this case the situation is affected by the
field, although
presence
ELECTROMAGNETIC
hold for the torque -t
function
their
or
124 existence
numerically,
correlation increase made
and also to pinpoint
of an external
in speed and power of computers
C15,16,171,
selenide,
illustrates
the results
in fig.
to see how the results
scheme.
In the meantime,
of a simulation
(I) the existence
to the sample.
. qgo)
can be
of this letter
for gaseous
with only 108 molecules
of a simple cross-correlation
one out of many which has not seen the light of day before.
With the
the link up with hydrodynamics
and it would be possible
fit in to the overall hydrodynamic hydrogen
[41 on cross-
the exact effects
field of force applied
function,
This is:
x X(O)’ (12)
4<,2,,,2,~<,2, This cross-correlation, frame defined vanishes
by symmetry
components
in frame
exist however
I
0.25
0 Fig. 2.
Autocorrelation
CROSS-CORRELATIONS
(x,y,z) for all t.
in the moving
of inertia,
The a.c.f.'s
but
of the
(x,y,z) and are illustrated
functions
of the force 2#m&(t) x (t(t) x ,$t),
frame and (2) the moving
DIFFERENT
leading to eqns
intermolecular
e(t) = cl(t) we obtain varieties vectors
moments
in frame
BETWEEN
If the analysis time-dependent
(5) and (3), exists
molecular
in fig. (2).
Ups)
in (1) the laboratory
position
implied by eqns
by the three principal
frame of reference.
MOLECULES
(2) to (6) is repeated
separation
for the
of two molecules: (13)
:2(t)
of cross-correlation
$1 and 52
contain
which depend on e and
of the two molecules
in question.
A
the
125 straightforward correlation
piece of algebra
functions
<4(k(t) x
leads to the implied existence
of cross-
such as
~2(Q)
.
(~(0)
x
$0)
x
$b))>
and
(14) <4(&(t) x x1(t))
which
correlate
. (t(o) x t(o) x x2(0))>
and define
molecule
(I) depend
explored
in any detail,
construction
expanding
theoretical
the way that the dynamics
although
the number
existence
use of supercomputers could be explored hydrodynamic
to extend
of a.c.f.'s
play a role in the
diffusion.
Having
got as far as thus
and c.c.f's which have a
condensed
states of matter.
the nature of these cross-correlation
in considerable
and molecular
of
None of these seems to have been
the logic to three and more particles,
in the molecular Cl51
(2).
they implicitly
of the theory of N particle
eqn (14) it is natural greatly
statistically
on those of molecule
detail, with a view to unifying
theory of the condensed
With the functions the
phases.
ACKNOWLEDGEMENTS
The University
of Wales
is thanked
and the staff of the University thanked
of Dublin
for the award of a Visiting
for a Pilcher
Senior Fellowship
for many discussions.
Professorship
IBM is
at Kingston.
REFERENCES
1
M.R. Spiegel,
2
"Memory Function
"Vector Analysis", Approaches
vol. 62 of "Advances and G. Pastori
(Schaum, New York,
to Stochastic
in Chemical
Parravicini,
Physics"
ser. ed. I.
Problems
Prigogine
(Wiley/Interscience,
New York,
"Dynamical
in Condensed
4
M.W. Evans,
Physica,
5
M.W. Evans,
Phys. Rev. Letters,
6
M.W. Evans and G.J. Evans, Phys. Rev. Letters, ibid.
7
131B,
Matter",
ed. M.W. Evans, P. Grigolini,
3
Processes
1958), p. 51 ff. in Condensed
and S.A. Rice
1985). Matter",
ibid,, vol. 63, ed. M.W. Evans.
(1985) 273 50, (1983) 381 55 (1985) 818; M.W. Evans,
55 (1985) 1551
M.W. Evans,
Phys. Rev. A, Rapid Corn., 33 (1986) 2193;
Phys. Rev
A,
33 (1986) 1903. 8
M.W. Evans and G.J. Evans, Phys. Rev. A, 34 (1986) 468 in press.
; M.W. Evans, ibid.,
126 9
M.W. Evans, .I. Molecular Trans.
Liq., 31 (1986) 231, 213; J. Chem. Sot., Faraday
II, 82 (1986) 653. Phys. Rev., A, 30 (1984) 2062
10
M.W. Evans,
11
M.W. Evans, G.J. Evans, W.T. Coffey and P. Grigolini,
12
W.T. Coffey, M.W. Evans,
13
G.E. Ewing, Act. Chem. Res., 2 (6) (1979) 168
14
H. Friedmann
15
M. Wojcik
16
M.W. Evans, Phys. Rev. A, submitted,
ibid., 81 (1985) 1463;
(Wiley/Interscience,
(Wiley/Interscience,
New York,
G.J. Reid, G. Salvetti
"Molecular
Diffusion"
1984).
and S. Kimel, J. Chem. Phys.,
and E. Clementi,
Dynamics",
1982), chapter 8, 1, 84.
and P. Grigolini,
New York,
"Molecular
IBM Internal
47 (1967) 3589.
Report,
1986.
G.J. Evans, M.W. Evans, P. Minguzzi,
and J.K. Vij, ibid., submitted.
119
ElsevierSciencePublishersB.V.,Amsterdam-Printed
NON-INERTIAL
ACCELERATIONS
inTheNetherlands
IN THE THEORY OF MOLECULAR
DYNAMICS
M.W. EVANS
Dept. of Physics, Swansea
University
SA2 SPP, WAles,
(Received
College
of Swansea,
Singleton
Park,
(UK).
14 July 1986)
ABSTRACT
By repeated reference
non-inertial
of computer
acceleration
simulation
of some of these new statistical the conventional
methods
in the rotating
ensemble.
can be used to illustrate which
correlations,
built
frame of
of ways exist of correlating
terms in a molecular
using diffusion
fields can be conveniently revealing
operators
it is shown that a large number
fundamental technique
use of differential
equations.
in to the rotating
The
the time dependence
cannot be described
with
The effect of external frame analysis,
many new correlations.
INTRODUCTION
The new rotating to the molecular
frame theory of molecular
dynamics
transformation possible realised.
Cl1
Using
the result
No spectral method computer
the simplest,
the influence fields
correlations
(c.c.f. 's) is increased
0167-7322/87/$03.50
here to include new
of
has not been explicitly on any of these
Standard C2,31
simplifying
diffusion
cannot be used to assumption.
and electromagnetic
When
force
the extra torque due to the the number of possible
considerably.
between molecules
frame method,
equations
magnetic,
of liquid crystals,
of cross-correlations rotating
electric,
applied
of frame
information
on a very few.
[41, or alternatively
potentials
direct
and Kramers
recently
of a very large number
whose existence
can provide
even with considerable
of external
is included
director
is the generation
simulation
theory, based on Fokker-Planck describe
the simple mathematics
auto and cross-correlations
and contemporary
top, is extended
of an asymmetric
types of cross-correlation.
diffusion,
results
of new possibilities
Similarly,
crossconsideration
in the emergence,
from the
when dealing with the collective
0 1987 Elsevier Science PublishersB.V.
120 correlations
of the molecular
liquid state.
all emerge from a very simple mathematical number of possible mathematically, exists.
auto and cross-correlation
the majority
Therefore,
infinite,
because
the minority
physical
implications
describe
molecular
vanishes
generated
by syrmnetry for all t;
the total number
of possible
diffusion
Neither
nor the hydrodynamical
things stand at present.
approach
theories
which may be used to approximate functions
simulation
The general
of external
force fields
Cll,lZl
.
function
and its quantum mechanical [ll], then the existence
experimental
under favourable
equivalent,
conditions,
a broad band,
quantum
theoretically,
features,
DEVELOPMENT
Consider
This defines higher
wave functions
Let gfs to
the differential
derivatives
m = (1,2,3)',
Let c be the position
in each frame.
This
of a very large number
frame f = (x,y,z) at the angular
centre of mass relative
types of
produces, work of
is associated,
are mutually
influential
than meets
the eye.
FRAME THEORY
a frame of reference,
has the same origin.
which
type of lab. frame auto and cross-correlation
and translational
OF THE ROTATING
to the laboratory
molecule
is composed
Clll.
There is much more to a broad band, therefore,
113,141.
and c.c.f's
features,
normally
infra-red
sets of lines, each of which
with a particular
in which rotational
value of a wave
new a.c.f.'s
spectral
fields
correlation
could be linked to specific
such as that in the far
shows that the broad band absorption discrete
an expectation
of discrete
to
of molecular
the classical
The liquid state at room temperature
cross-correlation. however,
C41, and also of internal
of the many different
here would mean the emergence
method
with the specific
and the interaction
If we make the analogy between
function described
fields
of this as
of the cross - and
effect on ensemble
potential
or
laws that may be expected
approach may be those concerned
dynamics
capable
as a numerical
emerge from this fundmental
such as those caused by the director
(a.c.f.'s)
[2,31 based on Kramers
the time dependence
CS-101.
functions
141 seems remotely
This leaves computer
The
to
the time dependence
and auto-correlation
the diffusion
is
in number.
is intended
must be capable of describing
self-consistently.
but a minority
correlations
infinity
of this are that any theory which
cross-correlation
auto-correlation
Out of the infinite
functions
that exists also approaches
of all the existing
Langevin
These new cross-correlations treatment.
vector
which rotates with respect frequency,
be the linear velocity
of & in both frames.
Rf and $.
Each frame
of the molecular
(x,y,z) and Qrn$ that relative operators
w.
of the centre of mass of a
to (1,2,3)'.
Let us now examine
the
121 VELOCITIES
The velocities
Em6 = Qf’
where
-
in the fixed and rotating
x
l$
(2)
5
it is understood
respect
to frame
that all the terms on the r.h.s. are defined with
(1,2,3)',
The angular
(x,y,s).
frames are linked through:
and that on the 1.h.s. with respect
frequency
to frame
w is the same in both frames because
the rate at which one frame rotates with respect
it is
to the other.
ACCELERATIONS
The frame relations gf and $
providing
the forward
The eqn (4) introduces centripetal
the Newton
molecular
dynamics
of existence
conditions
C13,141,
other spectral
DERIVATIVES
equations
are written
they are important diffusion
counterparts, result
of the operators
transformations.
acceleration,
acceleration.
in a non-inertial
C6-91 theory
,
the
These appear context
Lll
.
For
and cannot be approximated C2,31
.
Naturally,
which may, under "particle
in discrete,
observable
out
they have
in the box"
infra red absorptions
and
features.
OF ACCELERATION
In this case the operators transforms,
and backward
and the non-uniform
as in standard
quantum mechanical
two applications
into the lab frame the Coriolis
acceleration
whenever
now involve
are applied
three times in the forward
and back
producing:
D3 = 2;~ + &( 28 x Frn@ + ~m!,(c&&) x f) + Qrn(!+x (& x z)) %fr +8x
I&+
* x (2% x grn:, + * x ((&&)
x f) + t x (g x (b x z))
(5)
122 D3 = & 2rmr +Ex Eqn
x 6) + gf(&
- ;f(2& x 2fZ) - 2f((Qf#) (2KX?f9
+tx
(6) shows the existence
((Rf&) x5)
of many higher
in the laboratory
in frame
(x,y,z) and some of the c.c.f. 's between Furthermore,
(x,y,z).
& (‘3)
for each
The a.c.f. 's of all of these exist the terms are allowed by
making use of the results:
<&W
- p&3(0)> #
0;
t#o
‘g,(t)
. l&O,’
0;
t
it becomes
- * x
(w x (&XX))
@X
order accelerations
molecule
symmetry.
frame
-
x (8 x z))
+
#o
clear that many new cross-correlations
are generated
in frame
(1,2,3)' and (x,y,s).
EXTERNAL
TORQUES
If the molecular acceleration intrinsic
ELECTRIC
term gft
acceleration
ensemble
is treated with an external
in frame
(x,y,z) must be rewritten
and a term due to the effect
field C2,4,121
the
as the sum of the
of the field.
FIELD
The extra angular
acceleration
where x is the molecular in the denominator
dipole,
DfK -
ti
and E the external
is the equivalent
The total angular
molecule.
due to the electric
inertia
acceleration
field is:
field strength.
Here gE
due to the effect of g on the
is therefore:
“B
(9)
Bg Substituting
this in eqns
(2), (4) and (6) immediately
lab. frame cross-correlation Taking
into account
molecule
functions
polarisability
involving
effects
C2,31
produces
a range of new
the field acceleration. the effective
field on each
is:
g = E, + E .p . E + EEE where 9 is the molecular
i y- +............
polarisability,
1 the hyper-polarisability,
(10) and so on.
123 Similar
considerations
external
magnetic
inevitable
of Lorentz
E = ,E, exp(i(wt 2.em
correlations
field vector
for example,
generated
go nearly
generate effect,
new cross
i.e. a torque and
field applied
Some diagonal
However
0.50 elements
x ($L$t) x F(t)).gl(O)
3. (3,3) element.
diffusion,
to produce
the relatively
to a molecular
hydrodynamical
these new correlation
primitive
methods
t(ps) of the cross-correlation
(1,2,3)
of
can be used to illustrate
I x V(O)>/[
frame of reference
2. (2,2) element.
of molecular
we now have available
0.25
in the moving
theories
into enough detail
analytically. simulation
cl Fig. 1.
automatically
the Buckingham
Cl21.
otherwise, functions
(11)
by an electromagnetic
None of the available
computer
is, as usual,
- k . ,R))
(2), (4), and (6) would through,
birefringence ensemble
forces.
FIELD
The electromagnetic
and from eqns
x H generated by a static % in this case the situation is affected by the
field, although
presence
ELECTROMAGNETIC
hold for the torque -t
function
their
or
124 existence
numerically,
correlation increase made
and also to pinpoint
of an external
in speed and power of computers
C15,16,171,
selenide,
illustrates
the results
in fig.
to see how the results
scheme.
In the meantime,
of a simulation
(I) the existence
to the sample.
. qgo)
can be
of this letter
for gaseous
with only 108 molecules
of a simple cross-correlation
one out of many which has not seen the light of day before.
With the
the link up with hydrodynamics
and it would be possible
fit in to the overall hydrodynamic hydrogen
[41 on cross-
the exact effects
field of force applied
function,
This is:
x X(O)’ (12)
4<,2,,,2,~<,2, This cross-correlation, frame defined vanishes
by symmetry
components
in frame
exist however
I
0.25
0 Fig. 2.
Autocorrelation
CROSS-CORRELATIONS
(x,y,z) for all t.
in the moving
of inertia,
The a.c.f.'s
but
of the
(x,y,z) and are illustrated
functions
of the force 2#m&(t) x (t(t) x ,$t),
frame and (2) the moving
DIFFERENT
leading to eqns
intermolecular
e(t) = cl(t) we obtain varieties vectors
moments
in frame
BETWEEN
If the analysis time-dependent
(5) and (3), exists
molecular
in fig. (2).
Ups)
in (1) the laboratory
position
implied by eqns
by the three principal
frame of reference.
MOLECULES
(2) to (6) is repeated
separation
for the
of two molecules: (13)
:2(t)
of cross-correlation
$1 and 52
contain
which depend on e and
of the two molecules
in question.
A
the
125 straightforward correlation
piece of algebra
functions
<4(k(t) x
leads to the implied existence
of cross-
such as
~2(Q)
.
(~(0)
x
$0)
x
$b))>
and
(14) <4(&(t) x x1(t))
which
correlate
. (t(o) x t(o) x x2(0))>
and define
molecule
(I) depend
explored
in any detail,
construction
expanding
theoretical
the way that the dynamics
although
the number
existence
use of supercomputers could be explored hydrodynamic
to extend
of a.c.f.'s
play a role in the
diffusion.
Having
got as far as thus
and c.c.f's which have a
condensed
states of matter.
the nature of these cross-correlation
in considerable
and molecular
of
None of these seems to have been
the logic to three and more particles,
in the molecular Cl51
(2).
they implicitly
of the theory of N particle
eqn (14) it is natural greatly
statistically
on those of molecule
detail, with a view to unifying
theory of the condensed
With the functions the
phases.
ACKNOWLEDGEMENTS
The University
of Wales
is thanked
and the staff of the University thanked
of Dublin
for the award of a Visiting
for a Pilcher
Senior Fellowship
for many discussions.
Professorship
IBM is
at Kingston.
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1
M.R. Spiegel,
2
"Memory Function
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to Stochastic
in Chemical
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Physics"
ser. ed. I.
Problems
Prigogine
(Wiley/Interscience,
New York,
"Dynamical
in Condensed
4
M.W. Evans,
Physica,
5
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Phys. Rev. Letters,
6
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New York,
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and P. Grigolini,
New York,
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