213 13 21MB
English Pages 441 [444] Year 1978
Thermodynamics of Biological Processes
Thermodynamics of Biological Processes Editors Ingolf Lamprecht A. I. Zotin
w DE
G
Walter de Gruyter • Berlin • New York 1978
Editors Prof. Dr. Ingolf Lamprecht Institute o f Biophysics Freie Universität Berlin D - 1 0 0 0 Berlin 33 Prof. Dr. A. I. Zotin Institute o f Developmental Biology Academy o f Science of the U.S.S.R. Moscow with 6 9 Figures
CIP-Kurztitelaufnahme der Deutschen
Bibliothek
Thermodynamics of biological processes/ed. : Ingolf Lamprecht; A.I. Zotin. - Berlin, New York: de Gruyter, 1978 ISBN 3-11-007312-9 NE: Lamprecht, Ingolf [Hrsg.]
Library of Congress Cataloging in Publication Data
Thermodynamics of biological processes. Includes bibliographical references and index. 1. Biological physics. 2. Thermodynamics. 3. Developmental biology. I. Lamprecht, Ingolf, 1933 II. Zotin, Aleksandr Il'ich. QH505.T395 574.r91 78-15462
© Copyright 1978 by Walter de Gruyter & Co., Berlin 30. All rights reserved, including those of translation into foreign languages. No part of this book may be reproduced in any form - by photoprint, microfilm or any other means - nor transmitted nor translated into a machine language without written permission from the publisher. Printing: Karl Gerike, Berlin. - Binding: Liideritz & Bauer, Buchgewerbe GmbH, Berlin. Printed in Germany.
V This c o l l e c t i o n of n o n - l i n e a r thermodynamics
s u r v e y s current p r o b l e m s in the
irreversible in b i o l o g y .
and e x p e r i m e n t a l
thermodynamics
p r o c e s s e s and the a p p l i c a t i o n s Problems concerning
substantiation
the
of the p h e n o m e n o l o g i c a l
of d e v e l o p m e n t , g r o w t h and aging
of o r g a n i s m s are
and e x p e r i m e n t a l data are p r e s e n t e d
theory
discussed,
on o o g e n e s i s , a n i m a l
v e l o p m e n t and g r o w t h , and on heat p r o d u c t i o n and energy bolism during concluding
the g r o w t h of m i c r o o r g a n i s m s
of
in c u l t u r e .
e v o l u t i o n and the
demeta-
The
c h a p t e r s treat m o d e r n t h e o r i e s of d i s s i p a t i o n
t u r e s , p r o b l e m s of p r o g r e s s i v e
of
theoretical
struc-
classification
animals.
This m o n o g r a p h w i l l be u s e f u l to b i o p h y s i c i s t s , and e m b r y o l o g i s t s as w e l l as to p h y s i c i s t s and interested
physiologists mathematicians
in m o d e r n p r o b l e m s in t h e r m o d y n a m i c s and the a p p l i -
c a t i o n of this field to
biology.
L i s t of Berlin
authors
(üJest)
R.
Brettel
I.
Lamprecht
K.D.
Loehr
P.
Sayyadi
B.
Schaarschmidt
R. U a l t e r MOSCOUJ:
U.A.
Grudnitzky
U.A.
Kanoplev
I.S.
Nikolskaja
l\!.D. Ozernyuk E.U.
Presnov
E.A.
Prokofiev
L.I.
Radzinskaja
l\l.Sh. S h a g i m o r d a n o v U.E.
Sokolov
U.A.
Uasiliev
S.S.
Uasiliev
I.G.
Uladimirova
A.A.
Zotin
A.I.
Zotin
R.S.
Zotina
IX
Preface The main d i f f i c u l t y , as ue SEE it, is that a general
phenomenological
accompanied
T r u e , two large d i v i s i o n s reversible
theory
by a d i s s i p a t i o n and
linear
of t h e r m o d y n a m i c s
e s t a b l i s h e d ; but the theory a p p r o a c h e s under principles
cf all p r o c e s s e s
of n o n - l i n e a r
of t h e r m o d y n a m i c s ,
(the t h e o r i e s
irreversible
are the creation the a p p l i c a t i o n
of
linear p r o c e s s e s , using
the theory
considerations rather
to say which
of these
a basis for the t h e r m o d y n a m i c s c e s s e s . Yet sential
it is quite
of n o n - l i n e a r
suggest
for solving
p r o b l e m s in p h y s i o l o g y , b i o c h e m i s t r y It should
be noted
recent
that
w a s long
were available
extensive basis
slow heat
It is hoped
the most
of
systems Some
data
important biology.
thermodynamics methods
It w a s not were
until
designed
their wide
will help create a
for the t h e r m o d y n a m i c s
proes-
of i r r e v e r s i b l e p r o -
flows. that
is
is
in
systems.
b e c a u s e no satistact ory
deployment
it
take hold as
irreversible
sensitive m i c r o c a l o r i m e t e r s
and came into common u s e . experimental
stochastic
and d e v e l o p m e n t a l
the i n t r o d u c t i o n
delayed
for measuring
d e c a d e s that
bution and
generalized
occurring
in living
that the t h e r m o d y n a m i c s
c e s s e s could be used as a tool
into biology
basic to n o n -
of this kind
of p h e n o m e n a
e q u i l i b r i u m , particularly
in biology
variational
and
t r e n d s will
obvious that work
to our u n d e r s t a n d i n g
far from
of g r a p h , the
characteristics,
proces-
of t h e r m o d y n a m i c s p r o c e s s e s . At present
difficult
of
the main
of the
local t h e r m o d y n a m i c s theory
r e l a t i o n s and global
are
complete.
of its d e v e l o p m e n t . Among
consideration
as
p r o c e s s e s ) are now uiell
c o n c e p t s of P r i g o g i n e ' s reciprocal
that
of e n e r g y , is far from
irreversible
ses is still at the onset
thermodynamics,
distri-
reliable
of b i o l o g i c a l
pro-
cesses. This m o n o g r a p h laboratories: tute
resulted
from a c o o p e r a t i v e
the B i o p h y s i c a l
for Biochemistry
and
Laboratory
effort
between two
of the C e n t r a l
B i o p h y s i c s at the Free
Insti-
University,
X
West B e r l i n , a n d the L a b o r a t o r y the A c a d e m y
of D e v e l o p m e n t a l
Biology
of S c i e n c e s of the U S S R . Each c o n t r i b u t o r
to
v o l u m e is in some way c o n n e c t e d w i t h one of t h e s e two tories.
As we c o u l d h a r d l y
in w h i c h t h e r m o d y n a m i c s
of this
labora-
e m b r a c e all the f i e l d s of
biology
of i r r e v e r s i b l e p r o c e s s e s m a y
be
a p p l i e d , we c o n f i n e d o u r s e l v e s to the p r o b l e m s w h i c h are being s t u d i e d in our l a b o r a t o r i e s . A c c o r d i n g l y
it s h o u l d be
empha-
sized that the m a i n t h e o r i e s d i s c u s s e d in the book are on the g l o b a l a p p r o a c h to n o n - l i n e a r
irreversible
based
processes,
m o s t of the a u t h o r s being a d h e r e n t s of t h i s a p p r o a c h w h i c h d i s c u s s e d in c o n s i d e r a b l e d e t a i l and s u b s t a n t i a t e d
is
in the first
chapters. The m a t e r i a l p r e s e n t e d w a s t h o r o u g h l y
discussed
beforehand
at the t h e o r e t i c a l p h y s i c s s e m i n a r s of the P h y s i c a l of the A c a d e m y
of S c i e n c e s of the U S S R , at v a r i o u s
and c o l l o q u i a in the same a c a d e m y ' s I n s t i t u t e B i o l o g y , in the S o c i e t y of M a t h e m a t i c a l
of
Institute seminars
Developmental
and P h y s i c a l
Biology
of the G e r m a n D e m o c r a t i c R e p u b l i c , and in the C e n t r a l of B i o c h e m i s t r y
and B i o p h y s i c s of the Free U n i v e r s i t y ,
B e r l i n . U)e are m o s t g r a t e f u l these f r u i t f u l
Institute
to a n u m b e r
of c o l l e a g u e s
West for
discussions.
D o u b t l e s s a book the very b e g i n n i n g
such as this, being
d e v o t e d to a s c i e n c e
of its d e v e l o p m e n t , w i l l c o n t a i n
c i e s or even o u t r i g h t m i s t a k e s . The a u t h o r s w i l l be very ful for all c r i t i c a l r e m a r k s a i m e d at r e m o v i n g d a b l e d e f e c t s of their
these
grate-
unavoi-
work. I. L a m p r e c h t , A . I .
at
inaccura-
Zotin
XI
Contents
I. G e n e r a l
P r o b l e m s of B i o l o g i c a l
I. L a m p r e c h t
-
Application Classical
Thermodynamics
of the C o n c e p t s
Thermodynamics
1
of
in
Biology A . I . Zotin
-
5
The Second Law, N e g e n t r o p y , modynamics
of L i n e a r
Ther-
Irreversible
Processes E.V. P r e s n o v
-
19
Formalism
of N o n - E q u i l i b r i u m
menolagical II. Q u a l i t a t i v e
Pheno-
Thermodynamics
Phenomenological
Theory
31
of the D e v e l o p m e n t
of O r g a n i s m s A . I . Z o t i n , R.S. Zotina
-
Experimental
Qualitative
Basis
Phenomenological
for Theory
of D e v e l o p m e n t
61
A . I . Z o t i n , R . S . Z o t i n a , V/.A. K o n o p l e v
-
Theoretical
Basis for a Q u a l i t a t i v e Theory
Phenomenological
of D e v e l o p m e n t
E.V. P r e s n o v , R . S . Zotina
-
B5
Stochastic
of C o n s t i t u t i v e
Consideration
P r o c e s s e s and of the
Evolution Criterion E.V. P r e s n o v
-
Strengthened Evolution Criterion Developmental
III. Q u a n t i t a t i v e
99
Phenomenological
in
Biology Theory
105 of
Development
of O r g a n i s m s
111
A . I . Zotin, V . A . K o n o p l e v , E.V. P r e s n o v Phenomenological R . S . Z o t i n a , A . I . Zotin
-
-
Equations
Differential
Developmental
Non-Linear
Biology
Equations
115 of 121
XII
R.S. Z o t i n a , A . I . Zotin
-
Differential
of D e v e l o p m e n t a l
Equations
Biology
U.A. K o n o p l e v , A . I . Z o t i n , E.A. P r o k o f i e v , mordanov
-
R. W a l t e r ,
I. L a m p r e c h t ning
IU. B.
Heat P r o d u c t i o n
-
B.
Growth
of Living
-
-
1^3 163
Heat
Production 167
The C h a n g e of the the G r o w t h
of
Mi-
Cultures
C h a n g e s of ring
Concer-
Equations
F u n c t i o n During
Zotin
135
Processes
S c h a a r s c h m i d t . R. B r e t t e l
A.I.
Equations
Systems
S c h a a r s c h m i d t , I. L a m p r e c h t
crobial
Shagi-
Analysis
Modern Theories
the G r o w t h
in Life
Sh.
Computer
of N o n - L i n e a r
121
181
and
Functions
O o g e n e s i s of X e n o p u s
K.D. L o e h r , P. S a y y a d i , I. L a m p r e c h t
-
Development
and G r o w t h
Laevis
Heat
d u c t i o n and R e s p i r a t i o n
Du191
Pro-
During of two
Insects U.A.
197
G r u d n i t z k y , I.S. IMikolskaja
-
and R e s p i r a t i o n Early U.A. G r u d n i t z k y ,
Heat
B. S c h a a r s c h m i d t
-
P r o b l e m s of E n e r g e t i c s
Relationship Body
Organisms
209
of D e v e l o p m e n t a l Processes
I.S. IMikolskaja, L . I . R a d z i n s k a j a chondria
205
Heat P r o d u c t i o n and
LJeight in Growing Some
the
S t a g e s of G r o w t h
Between
U.
Production
of A x o l o t l e at
During
-
C h a n g e s in
Development
Mito-
and
Growth
of A n i m a l s f\I.D.
Dzernyuk
The Role of M i t o c h o n d r i a
213
217 in
tion of R e s p i r a t i o n During
RegulaOogenesis
229
XIII I.G. V l a d i m i r o v a
-
The E n e r g e t i c s
of
Regeneration
Processes VI.
Dissipative
I. L a m p r e c h t
243
Structures
-
Revieu
257 of the
Theory
of
Dissipative
Structures
261
U.A. Vasiliev
-
Stationary
U.A. Vasiliev
-
Dynamic Dissipative
A.I.
-
Dissipative Fuction
Zotin
S.S. Vasiliev
-
The R o l e Energy
Dissipative
Structures
Structures
Structures
293
and 3D1
of C y c l i z a t i o n
in
277
of
Free
Bio-Physico-Chemical
Processes VII.
Probability
305
State and Orderliness
of
Biological
Systems N.D.
325
Ozernyuk, A.I.
Zotin,
U.A. Konoplev, A.A.
Possible
Mechanism
of t h e
Zûtin Origin
of
Bacteria A.I.
Zotin,
U.A.
Konoplev
329 -
Direction
Evolutionary V.A. Konoplev,
U.E.
Progress
Sokolov, A.I.
Zotin
of O r d e r l i n e s s a n d
of
the
of O r g a n i s m s -
some
341
Criterion Problems
of
Taxonomy A.I.
Zotin, V.A. Konoplev,
U.A. Grudnitzky
of IMon-Linearity of O r d e r l i n e s s Concluding
Remarks
349 - The Q u e s t i o n s
for U s i n g
Criterion 361 3S9
References
371
Index
^35
I. General P r o b l e m s of B i o l o g i c a l Thermodynamics
3
None of the fields of theoretical physics is so closely connected with biology o r gives such an effective description of the life p r o c e s s e s as thermodynamics. Although m e c h a n i c s , hydrodynamics, electrodynamics and optics a r e widely applied in biology, they d e s c r i b e phenomena which a r e not a s c h a r a c t e r i s t i c of the living s y s t e m s as heat production and the p r o c e s s of m e t a b o l i s m concerned with it. Modern thermodynamics also includes other concepts e x t r e m e l y important f o r biology such as " t i m e a r r o w s " (see Popper, 1965, 1967 a , b) or various evolution c r i t e r i a specifying the direction of the changes of thermodynamic s y s t e m s (Glansdorff, P r i g o g i n e , 1964, 1971; P r i g o g i n e , 1966; N i c o l i s , 1971; Zotin, 1972, 1974; P r e s n o v , 1973). In spite of this, the problems of applying individual fields of thermodynamics in biology a r e still open to discussion ( L a z a r e v , 1945; Schrodinger, 1945; Ubbelohde, 1947; B r i l l o u i n , 1949, 1955; Raymond, 1950; P a s y n s k y , 1953, 1963; Touloukian, 1956; Volkenstein, 1958, 1965, 1973; Wilkie, 1960; B e r n h a r d , 1964; M o r r i s o n , 1964; R i e g e l , 1965; Calloway, 1966; B l u m , 1967; Molchanov, 1967; T r i n t s c h e r , 1967; Antonov, 1968; Morowitz, 1968, 1970; Kobozev, 1971; Rebane, 1972; Zotin, 1971, 1972, 1974; B l u menfeld, 1974; P r i t z , 1974; Chernavsky, 1975; Nikolaev, 1976). T h e applicability of the concepts of c l a s s i c a l thermodynamics and thermodynamics of l i n e a r i r r e v e r s i b l e p r o c e s s e s to some biological phenomena a r e reviewed below, and b a s i c concepts of the s o - c a l l e d global theory of n o n - l i n e a r i r r e v e r s i b l e p r o c e s s e s a r e presented. Much of the t h e o r e t i c a l and experimental work presented in this book r e s t upon this global theory.
Application of the Concepts of C l a s s i c a l T h e r m o d y n a m i c s in Biology I. L a m p r e c h t
T h e r m o d y n a m i c s was b o r n 200 y e a r s ago when L a v o i s i e r ' s e x p e r i m e n t s on the oxidation b r o k e with S t a h l ' s t h e o r y of phlogiston. At the v e r y beginning of this development, t h e r e w e r e c a l o r i m e t r i c m e a s u r e m e n t s on the heat production of s m a l l a n i m a l s in an ice c a l o r i m e t e r of the L a v o i s i e r - L a p l a c e - t y p e . T h i s s t r o n g connection between biology and t h e r m o d y n a m i c s was n e v e r b r o k e n , and two physicians m a d e the f i r s t s t e p s toward a m o d e r n t h e o r y of e n e r g y : M a y e r and Helmholtz with t h e i r f o r m u l a t i o n of the f i r s t law of t h e r m o d y n a m i c s . Half a c e n t u r y l a t e r , R u b n e r in B e r l i n d e m o n s t r a t e d the validity of the f i r s t law in biology with h i s e x p e r i m e n t s on the m e t a b o l i s m of m i c r o o r g a n i s m s and nowadays living m a t t e r is one of the favoured topics of both c l a s s i c a l t h e r m o d y n a m i c s and (more r e c e n t l y ) the t h e r m o d y n a m i c s of i r r e v e r s i b l e p r o c e s s e s . T h e r e is no question that just this t h e o r y l e a d s to d e e p e r u n d e r s t a n d i n g of living m a t t e r and p r e d i c t s developments which a r e not c o m p r e h e n s i b l e in other w a y s . In this c h a p t e r we s h a l l introduce the c h a r a c t e r i s t i c t h e r m o d y n a m i c a l quantities and explain t h e i r connection with biological p r o c e s s e s .
Internal Energy U Although t h e r e e x i s t s a m a t h e m a t i c a l , a x i o m a t i c deduction of t h e r m o d y n a m i c s which p o s t u l a t e s the e x i s t e n c e of v a r i a b l e s of s t a t e a s cons e q u e n c e of the d i f f e r e n t l a w s , we s h a l l follow a m o r e e m p i r i c a l a p p r o a c h , and define the quantities and r e g a r d the f i r s t and second + l a w s a s prooved by e x p e r i e n c e . +
M . P l a n c k f o r m u l a t e d that the sad fate of the would-be i n v e n t o r s of the p e r p e t u u m mobile is the s t r o n g e s t proof f o r the t r u t h of the f i r s t l a w .
© 1978 by Walter de Gruyter & Co., Berlin • New York Thermodynamics of Biological Processes.
6
If a s y s t e m , separated by fixed or movable walls from its environment, undergoes a change of state, this might involve a flow of heat to or from the system and work done by or on the s y s t e m . If a negative sign is assigned to energy which is delivered to the surroundings, the influx of heat is Q, while the work on or produced by the s y s t e m is A . T h e r e e x i s t s a variable of s t a t e , the internal energy U , which combines these two p a r a m e t e r s in the equation: A U »
AQ
A.A
(1.1)
V e r y often the work done is an expansion of a gas against an outside p r e s s u r e . Following the B o y l e - M a r i o t t e law we find: AA
- -pAV
and inserting this value in (1. 1): A U
-
AQ
-
f>AV
(1.2)
B y integrating ( 1 . 2 ) we could obtain the value of the internal energy U, but in the most experiments we a r e only interested in the change AU» when the s y s t e m p a s s e s from a state 1 to a state 2. The value of A Q is measured c a l o r i m e t r i c a l l y , while the following t e r m may be obtained by calculation f o r a known reaction o r by m a n o m e t r i c e x p e r i m e n t s . T h e r f o r e , we have to distinguish three different c a s e s : a) The c a l o r i m e t r i c v e s s e l is open to the surrounding, so that no change in p r e s s u r e can o c c u r , i . e .
Ap = 0.
b) The c a l o r i m e t r i c v e s s e l is closed, the p r e s s u r e changes ( A p t 0), but the volume stays constant, i. e.
A V = 0.
c) Although one of the two c a s e s a) and b) must be fullfilled, we have A V = A p = 0 , if no gaseous p a r t s a r e involved in the observed r e action. L e t us explain these differences with a simple example of great importance in biology. During glycolysis the sugar glucose is d e c o m posed by a chain of enzymes to ethanol or to l a c t i c acid. In the f i r s t
7
c a s e , the r e a c t i o n follows the equation: C
2 C 6H12°6 — > 2H5°H+2C02F o r s i m p l i c i t y , we take one mole of s u g a r dissolved in one l i t e r of w a t e r
which is contained in a two l i t e r v e s s e l . If it is open to a i r ( A p = 0), we have to c a l c u l a t e AV, which f o r two m o l e s of the gas is 2 x 2 2 . 4 l i t e r = 3 44, 800 cm . With a n o r m a l p r e s s u r e of 760 m m Hg we get: - p AV = 1 , 0 1 3 k p / c m 2 • 44, 800 c m 3 = 454 mkp = 4 , 4 5 0 J = 1060 c a l . The heat exchanged in this p r o c e s s is AQ = -17 k c a l / m o l e , so that the total change in i n t e r n a l e n e r g y i s : AlA=" A Q - - p A V =
-fe3Ymole .
It was a s s u m e d in o u r calculation that the w a t e r was s a t u r a t e d by c a r b o n dioxide s o that none of the gas g e n e r a t e d went into solution. The r o l e of work is s m a l l and negligible in m o s t biological e x p e r i m e n t s . When glucose is metabolized to l a c t i c acid the r e a c t i o n i s : C^H, „ O . *• 2CHOHCOOH o IZ b with no production of g a s . The change of the i n t e r n a l e n e r g y e q u a l s the production of h e a t , which a m o u n t s to -151 k J / m o l e = -36 k c a l / m o l e . The e r r o r due to neglecting work in the e n e r g y calculation inc r e a s e s with the amount of gas p r o d u c e d . In the c a s e of r e s p i r a t i o n of glucose, 6 m o l e s of c a r b o n dioxide a r e f o r m e d f o r each mole of g l u c o s e . T h e e f f e c t of work is thus t h r e e t i m e s a s high a s when ethanol is p r o duced, but a s the change in i n t e r n a l e n e r g y AU = - 6 7 8 k c a l / m o l e , the e n e r g y contribution f r o m work is negligible. Equation (1.1) is one f o r m u l a t i o n of the f i r s t law of t h e r m o d y n a m i c s : that a l l e n e r g y added to the s y s t e m is to be found in the i n t e r n a l e n e r g y . M o r e i m p r e s s i v e l y , e n e r g y is n e i t h e r c r e a t e d n o r d e s t r o y e d . T h i s law, f i r s t f o r m u l a t e d f o r p h y s i c a l (e. g. gaseous) s y s t e m s , was s u c c e s s f u l l y checked f o r biological entities as well. R u b n e r showed at the beginning of this c e n t u r y , in a s e r i e s of p a p e r s f o r m i c r o b i a l c u l t u r e s , that the e n e r g y content of the nutrient was c o m p l e t e l y divided into t h r e e p a r t s , the sum of which r e m a i n s constant: the e n e r g y wasted a s heat and t r a n s -
8 mitted to the surroundings, the energy stored a s c e l l m a t e r i a l ( m e a sured by bomb c a l o r i m e t r y ) and the energy left in the medium as m e t a bolites. L a t e r o n Sedlaczek (1964) repeated this m e a s u r e m e n t with higher a c c u r a c y for various b a c t e r i a , such as E . coli, P . v u l g a r i s , S. aureus and P . f l u o r e s c e n s . He compared the decrease, in heat content ( m e a sured as heat of combustion) between the initial and the final medium with the sum of energy converted to heat and the heat of combustion of the b a c t e r i a l c r o p . L e t us consider one example, the growth o f E . heat of combustion of the initial medium
- 17, 338 cal
heat of combustion of the final medium
- 16, 264 "
difference
coli:
1,074 "
heat of combustion of b a c t e r i a l crop
-
528 "
energy converted to heat during growth
-
468 " 996 cal
T h e r e is a discrepancy of 1 , 0 7 4 - 996 = 78 c a l o r 7. 3 % of the calculated heat, but when we take into account that the d e c r e a s e in energy content is found as a s m a l l difference between two l a r g e f i g u r e s , the d i s c r e pancy is negligible (78 c a l of 17, 338 c a l a r e just 0 . 4 %). T h e experiments a r e in full agreement with the f i r s t law.
Enthalpy H As shown above, the change in internal energy might be due to a heat flux and an expansion of gas against an outside p r e s s u r e . T h i s energy i s called the work of volume. As it is e s s e n t i a l in all reactions c o m bined with a production of gas, a new function is defined by: -H -
U
-ya.V
(1.3)
which is called the enthalpy of the s y s t e m . In differential f o r m we may write: A+t *» A U + A ( - p . v ) = A"U. + V A - p + -jo AV
9
and t o g e t h e r with (1.2) A t t « A Q - ' p A V + V A - p + - p A V ~ A Q + VA>|p .
(1.4)
In the c a s e that the p r e s s u r e does not change d u r i n g the e x p e r i m e n t (i. e. that the v e s s e l is open in a biological c a l o r i m e t e r ) , A p equals z e r o and the change in enthalpy is the heat consumed o r produced in the r e a c t i o n . As in m o s t r e a c t i o n s , the p r e s s u r e s t a y s constant, the i n c r e a s e in e n thalpy is the heat of r e a c t i o n of the p r o c e s s . We have pointed out above that the amount of work e n e r g y i s s m a l l c o m p a r e d with the h e a t . T h e r e f o r e , the v a l u e s obtained f o r the i n t e r n a l e n e r g y a r e n e a r l y the s a m e a s f o r the enthalpy; or put a n o t h e r way, a l though c a l o r i m e t r y e v a l u a t e s heat e x c h a n g e s , these v a l u e s can be taken f o r the enthalpy, too.
Temperature T B e f o r e we explain the next t h e r m o d y n a m i c v a r i a b l e of s t a t e , the e n t r o p y , we have f i r s t to i n t r o d u c e the t e m p e r a t u r e , well known f r o m the daily l i f e . In c o n t r a s t to i n t e r n a l e n e r g y , enthalpy and e n t r o p y , t e m p e r a t u r e is an intensive quantity which c h a r a c t e r i z e s the s t a t e of a s y s t e m . By definition two bodies in contact have the s a m e t e m p e r a t u r e (independ e n t l y of the s c a l e used) if t h e r e is no heat exchange between t h e m . N o r m a l l y two d i f f e r e n t s c a l e s f o r t e m p e r a t u r e a r e used: the C e l s i u s s c a l e with 100 c e n t i g r a d e between the two fixed points of w a t e r and the Kelvin s c a l e with only one fixed point (triple point of w a t e r ) set equal to 273. 15 K above absolute z e r o . It h a s r e c e n t l y been r e c o m m e n d e d that only this s c a l e should be u s e d . T e m p e r a t u r e is a v e r y i m p o r t a n t p a r a m e t e r f o r living s y s t e m s . Although one is usually i n t e r e s t e d only in changes in i n t e r n a l e n e r g y and enthalpy, one n e e d s to know the absolute value of the t e m p e r a t u r e r a t h e r than the change in t e m p e r a t u r e . N o r m a l life
is bound to a v e r y s m a l l r e g i o n of t e m p e r a t u r e , p e r -
10 h a p s (let us say) between 10 and 40 d e g r e e s c e n t i g r a d e . Some h i g h e r o r g a n i s m s have developed s p e c i a l s y s t e m s to withstand e x t r e m e t e m p e r a t u r e s , i. e . between - 1 0 0 ° C and p e r h a p s +55° C at the upper end. Howe v e r , t h e r m o p h i l i c o r g a n i s m s a r e known, e s p e c i a l l y b a c t e r i a and a l g a e , which a r e s o well adapted to t h e i r biotops that they even grow n e a r +100° C, and one b e l i e v e s that life m a y e x i s t a s long a s liquid w a t e r is p r e s e n t . On the o t h e r hand, the f r e e z i n g of w a t e r at l o w e r t e m p e r a t u r e s l i m i t s life at the l o w e r l i m i t , although the f r e e z i n g point m a y be shifted by high c o n c e n t r a t i o n s of s a l t s o r o r g a n i c s u b s t a n c e s .
Entropy S A v e r y e s s e n t i a l but often m i s u s e d and m i s i n t e r p r e t e d t h e r m o d y n a m i c value of s t a t e i s the e n t r o p y of the s y s t e m , an extensive f i g u r e like i n t e r nal e n e r g y , enthalpy and v o l u m e . If at a given t e m p e r a t u r e T an amount Q of heat is exchanged with the s u r r o u n d i n g s , it is a c c o m p a n i e d by a r e v e r s i b l e change in entropy: A S
-
A O .
/ T
.
A c c o r d i n g to the second law of t h e r m o d y n a m i c s , total entropy can not diminish in an isolated s y s t e m . In the ideal r e v e r s i b l e e x p e r i m e n t it s t a y s constant (being a function of s t a t e !), but in a l l r e a l isolated s y s t e m s , the entropy tends to r e a c h a m a x i m u m . In this way, the i n c r e a s e in e n tropy is closely connected to the p a s s a g e of time; it is " t i m e ' s a r r o w " . B o l t z m a n n was able to explain this tendency of e n t r o p y to a t t a i n a m a x i m a l value by his s t a t i s t i c a l t h e o r y . He showed that e n t r o p y is c o m bined with the probability "F^. of a s t a t e by the equation: £
-
¿rv
P
T
(1.5)
11 with k the Boltzmann-constant.
A s a system always tends to more
probable states, the increase in entropy is to be deduced. An increase in entropy as demanded by the second law corresponds (see (1.5)) to an increase of probability, i. e. a loss of order. As growing organisms seem to contradict this statement, it was often argued that the second law could not hold true for living matter. However, this law deals only with isolated systems, and no organism may be isolated from its environment f o r long. If we want to use the concept in the classical way, we have to build up an isolated system of organism plus environment. In this new system, there is a small (living) part the entropy of which decreases at the expense of the larger (inanimate) one. In spite of the partial diminution, the total change in entropy is always positive. Following Schrödinger (1945) we ascertain that living matter draws a steady stream of negative entropy ("Negentropy") from the environment, compensating in this way for its own continuous production of entropy: animals are feeding on negentropy! The same idea was published 90 years ago by the Austrian physicist Boltzmann (see Broda, 1970) in a very modern form: "Der allgemeine Lebenskampf der Lebewesen ist daher nicht ein Kampf um die Grundstoffe - auch nicht um Energie, welche in F o r m von Wärme leider unverwandelbar, in jedem Körper reichlich vorhanden ist - sondern ein Kampf um die Entropie (more exactly: Negentropy E. B . ) , welche durch den Übergang der Energie von der heißen Sonne zur kalten Erde disponibel wird. Diesen Übergang möglichst auszunützen, breiten die Pflanzen die unermess-
+
Shannon (1948) deduced an identical looking equation for the information content of a state. This was the reason for introducing the name "entropy" into information theory, too. Although there are some similarities between the negative entropy and the information, this connection should not be overestimated (a dimension of J per degree for information is useless).
12
liehen F l ä c h e n i h r e r B l ä t t e r aus und zwingen Sonnenenergie in noch une r f o r s c h t e r W e i s e , ehe sie auf das Temperaturniveau der E r d o b e r fläche herabsinkt, chemische Synthesen auszuführen, von denen man in unseren L a b o r a t o r i e n noch keine Ahnung hat. " + Let us illustrate these facts with two e x a m p l e s . (1) Animals feed on plants or other animals and take t h e i r negentropy from them. But where do the plants get their negentropy? They a r e the f i r s t step in producing m a c r o m o l e c u l e s from carbon dioxide and water in the p r e s e n c e of light and in diminishing the entropy of the s u b s t a n c e s . The temperature of the sun T surface of the earth T g
( 5 , 5 0 0 K) is nearly 20 times that of the s (290 K). According to the laws of radiation, the
maximum intensity of an emitted spectrum corresponds to the t e m p e r a ture of the s o u r c e . T h e r e f o r e , if an amount Q of s o l a r radiation is absorbed on earth and reemitted there is a change in entropy: AS " qr ~ — T«. Ts
=
Gl(4 - 4 ) I«, is
>
A S may be calculated: A S = 150 n c a l / d e g . mole with n the number of quanta n e c e s s a r y for the formation of one molecule of sugar in photosynthis: 6 C
+
0
2
+
6 H
2
0 —
C6H1206+ 6 02
" T h e general struggle for existence among living things is therefore not competition for b a s i c substance - nor for energy, which is abundantly in the inconvertible form of heat, in e v e r y body, but for the entropy (more exactly: negentropy E . B . ) , which b e c o m e s available in the transit of energy from the hot sun to the cold e a r t h . In order to take best advantage of this transition, the plants spread out the i m m e a s u r a b l e surface of their l e a v e s and force the s u n ' s energy, before it sinks to the temperature of the e a r t h ' s u r f a c e , to c a r r y out chemical syntheses of which we in our l a b o r a t o r i e s a r e s t i l l totally ignorant. "
13
with an entropy d e c r e a s e of A S = - 4 0 c a l / d e g . m o l e . Roughly 3 quanta a r e used p e r mole CO , so that +450 c a l / d e g . mole compensate for - 40 c a l / d e g . m o l e . An efficiency of 10 per cent suffices to fullfill the r e quirements of the second law (Britten, Gamov, 1961). M o r e o v e r one may calculate a m a x i m a l density of plants for the total s u r f a c e of e a r t h , so that the entropy change by growth and t e r m a l denaturation equals the s o l a r entropy influx. T h i s density could be a s 4 2 2 high as 2 . 1 0 / g / c m of plants compared with approximately 1 / g / c m found on the earth (Stein, 1960). (2) L e t us choose another example which shows that the limit of the second law is never touched. The multiplication of a m i c r o o r g a n i s m may be written (Morowitz, 1960): 1 c e l l + substrate
—
2
c e l l s + metabolites.
Different parts of growth have to be distinguished: condensation of nutrients into the cell; arranging of substrate molecules into c e l l s t r u c t u r e , i n c r e a s e in entropy during the metabolism of the substrate; heat flux to the environment. The destruction of substrate to 0 . 0 3 g waste m a t e r i a l per g new c e l l m a t e r i a l would be enough to meet the second law. Instead of this we find a figure of 4 . 9 5 for E . c o l i . The entropy production is thus 150 times bigger than n e c e s s a r y . In c a l o r i m e t r i c experiments with yeast we find during fermentation a A S of + 128 c a l / d e g . mole to be compared with a negentropy of c e l l s of - 7 c a l / d e g . m o l e . Even if the reaction v e s s e l guides all the metabolic heat into the environment, the entropy flux i s - 85 c a l / d e g . mole, keeping the balance positive, as n e c e s s a r y for the second law.
F r e e Energy F According to the f i r s t law of thermodynamics the maximum work A which can be obtained f r o m a reaction is given by: A A =» L M - - A G l
14
and t o g e t h e r with ( 1 . 5 ) f o r r e v e r s i b l e c o n d i t i o n s : AA -
A U - T A S = AT 7 .
T h i s c h a n g e in i n t e r n a l e n e r g y d i m i n u i s h e d by t h e e n t r o p y t e r m i s i n t r o d u c e d a s the f r e e e n e r g y F . If AU i s i n d e p e n d e n t of t e m p e r a t u r e ,
the
d i f f e r e n t i a t i o n of A A l e a d s to: d A / oLT =
-
AS
and A=F = A U - T . o t A / c L T
(1. 7)
the e q u a t i o n of Gibbs and H e l m h o l t z . Only at T = 0 o r with a v e r y s m a l l t e m p e r a t u r e c o e f f i c i e n t of the m a x i m a l w o r k i s t h e r e a d i r e c t c o n v e r s i o n of i n t e r n a l e n e r g y to w o r k .
F r e e E n t h a l p y (Gibbs F r e e E n e r g y ) G In the s a m e w a y a s f o r the f r e e e n e r g y a s e c o n d " f r e e " f i g u r e i s i n t r o d u c e d by Gj -
4+ -
T. S
(1.8)
o r in the d i f f e r e n t i a l f o r m ( A T = 0); AG] = A t t -
T.AS .
(1.9)
T h e c h a n g e in the f r e e e n t h a l p y i s e s s e n t i a l f o r the d i r e c t i o n of a r e a c t i o n . A c h e m i c a l s y s t e m c a n v a r y i t s s t a t e s p o n t a n e o u s l y only if t h i s c h a n g e i s c o m b i n e d with a n e g a t i v e A G , i . e . the r e v e r s i b l e r e a c t i o n p r o d u c e s w o r k . T h e n e g a t i v e s i g n of A G m a y b e due to a s t r o n g e x o thermic effect ( A H