In this paper, we consider the behavior of random heteropolymers in a quenched disordered medium. We develop a field theory and obtain a mean‐field solution that allows for replica symmetry breaking. The presence of an external disorder leads to the formation of compact states; a homopolymeric effect. We compute the phase diagram for two classes of problems. First, we consider the situation wherein the bare heteropolymer prefers like segments to segregate, and second, we examine cases where the bare heteropolymer prefers unlike segments to mix. For the first class of systems, we find a phase diagram characterized by a replica symmetry broken phase that exists below a particular temperature. This temperature grows with the strength of the external disorder. In the second class of situations, the phase diagram is much richer. Here we find two replica symmetry broken phases with different patterns separated by a reentrant phase. The reentrant phase and one of the two replica symmetry broken phases are induced by interactions with the external disorder. The dependence of the location of the phase boundaries on the strength of the external disorder are elucidated. We discuss our results from a physical standpoint, and note the testable experimental consequences of our findings.

1.
M. Karplus and E. Shakhnovich, in Protein Folding, edited by T. E. Creighton (Freeman, New York, 1995), pp. 127–195.
2.
H. S.
Chan
and
K. A.
Dill
,
Phys. Today
46
,
24
(
1993
).
3.
H.
Frauenfelder
and
P. G.
Wolynes
,
Phys. Today
47
,
58
(
1994
).
4.
E. I.
Shakhnovich
and
A. M.
Gutin
,
Nature
346
,
773
(
1990
).
5.
R.
Goldstein
,
Z. A.
Luthey-Schulten
, and
P. G.
Wolynes
,
Proc. Natl. Acad. Sci. USA
89
,
9029
(
1992
).
6.
E. I.
Shakhnovich
,
A. M.
Gutin
,
Proc. Natl. Acad. Sci. USA
90
,
7195
(
1993
).
7.
C. D.
Sfatos
,
A. M.
Gutin
, and
E. I.
Shakhnovich
,
Phys. Rev. E
48
,
465
(
1993
).
8.
A.
Sali
,
E. I.
Shakhnovich
, and
M.
Karplus
,
Nature
369
,
248
(
1994
).
9.
G. H.
Fredrickson
and
S. T.
Milner
,
Phys. Rev. Lett.
67
,
835
(
1991
).
10.
G. H.
Fredrickson
,
S. T.
Milner
, and
L.
Leibler
,
Macromolecules
25
,
6341
(
1993
).
11.
A.
Nesarikar
and
M.
Olivera de La Cruz
,
J. Chem. Phys.
98
,
7385
(
1993
).
12.
L.
Gutman
and
A. K.
Chakraborty
,
J. Chem. Phys.
101
,
10074
(
1994
).
13.
C. M.
Marques
and
J. F.
Joanny
,
Macromolecules
23
,
268
(
1990
).
14.
J. F.
Joanny
,
J. Phys. II (France)
4
,
1281
(
1994
).
15.
A. K.
Chakraborty
and
G. H.
Fredrickson
,
Macromolecules
27
,
7079
(
1994
).
16.
A.
Baumgartner
and
M.
Muthukumar
,
J. Chem. Phys.
87
,
3082
(
1987
).
17.
S. F.
Edwards
and
M.
Muthukumar
,
J. Chem. Phys.
89
,
2435
(
1988
).
18.
J.
Machta
and
R. A.
Guyer
,
J. Phys. A
22
,
2539
(
1989
).
19.
M. E.
Cates
and
R. C.
Ball
,
J. Phys. (Fr.)
49
,
2009
(
1988
).
20.
J. D.
Honeycutt
and
D.
Thirumalai
,
J. Chem. Phys.
90
,
4542
(
1989
).
21.
K.
Leung
and
D.
Chandler
,
J. Chem. Phys.
102
,
1405
(
1995
).
22.
A. K.
Chakraborty
,
D.
Bratko
, and
D.
Chandler
,
J. Chem. Phys.
100
,
1528
(
1994
).
23.
J. P.
Bouchaud
and
A.
Georges
,
Phys. Rep. C
195
,
127
(
1990
).
24.
D. S.
Fisher
,
D.
Freidan
,
Z.
Qui
,
S. T.
Shenker
, and
S. H.
Shenker
,
Phys. Rev. A
31
,
3841
(
1985
).
25.
I. M.
Lifshitz
,
Sov. Phys. Usp.
7
,
549
(
1965
).
26.
J. M.
Luttinger
and
R.
Tao
,
Ann. Phys.
145
,
185
(
1983
).
27.
D. Chandler, in Les Houches, Part I, Liquids, Freezing and the Glass Transition, edited by D. Levesque, J. P. Hansen, and J. Zinn-Justin (Elsevier, New York, 1991), p. 193.
28.
F. S.
Bates
,
Science
251
,
898
(
1991
).
29.
F. S.
Bates
,
G. H.
Fredrickson
,
Annu. Rev. Phys. Chem.
41
,
525
(
1990
).
30.
E. L.
Thomas
,
D. C.
Anderson
,
C. S.
Henke
, and
D.
Hoffman
,
Nature
334
,
598
(
1988
).
31.
L.
Leibler
,
Macromolecules
13
,
1602
(
1980
).
32.
M.
Olivera de La Cruz
,
A. M.
Mayes
, and
B. W.
Swift
,
Macromolecules
25
,
944
(
1992
).
33.
J. D.
Vavsour
and
M. D.
Whitmore
,
Macromolecules
26
,
7070
(
1993
).
34.
K.
Almdal
,
J. H.
Rosedale
,
F. S.
Bates
,
G. D.
Wignall
, and
G. H.
Fredrickson
,
Phys. Rev. Lett.
61
,
2229
(
1988
).
35.
G. H.
Fredrickson
and
E.
Helfand
,
J. Chem. Phys.
87
,
697
(
1987
).
36.
E. I.
Shakhnovich
and
A. M.
Gutin
,
J. Phys. (Fr.)
50
,
1843
(
1989
).
37.
E. I.
Shakhnovich
and
A. M.
Gutin
,
J. Phys. A
22
,
1647
(
1989
).
38.
E. I.
Shakhnovich
and
A. M.
Gutin
,
Biophys. Chem.
34
,
187
(
1989
).
39.
T.
Garel
and
H.
Orland
,
Europhys. Lett.
6
,
307
(
1988
).
40.
J.
Bryngelson
and
P. G.
Wolynes
,
Proc. Natl. Acad. Sci. USA
84
,
7524
(
1987
).
41.
G.
Iori
,
E.
Marinara
, and
G.
Parisi
,
J. Phys. A. Math. Gen.
24
,
5349
(
1991
).
42.
G.
Iori
,
E.
Marinara
,
G.
Parisi
, and
M.
Vittoria-Struglia
,
Physica A
185
,
98
(
1992
).
43.
T.
Cosgrove
,
N. A.
Finch
, and
J. R. P.
Webster
,
Macromolecules
23
,
3353
(
1990
).
44.
A. Y.
Grosberg
and
E. I.
Shakhnovich
,
Sov. Phys. (JETP)
64
,
1284
(
1986
).
45.
G.
Parisi
,
J. Phys. A
13
,
1101
(
1980
).
46.
M. Mezard, G. Parisi, and M. A. Virasoro, Spin Glass Theory and Beyond (World Scientific, Singapore, 1987).
47.
M.
Mezard
and
G.
Parisi
,
J. Phys. (Fr.) I
1
,
809
(
1991
).
48.
V. S.
Pande
,
A. Y.
Grosberg
, and
T.
Tanaka
,
J. Phys. (Fr.) II
4
,
1771
(
1994
).
49.
R. P. Feynman and A. R. Hibbs, Quantum Mechanics and Path Integrals (McGraw-Hill, New York, 1965).
50.
R. P.
Feynman
and
F. L.
Vernon
, Jr.
,
Ann. Phys. (N.Y.)
24
,
118
(
1963
).
51.
R. P. Feynman, Statistical Mechanics (Addison-Wesley, Reading, 1972).
52.
S. F.
Edwards
and
P. W.
Anderson
,
J. Phys. F
5
,
965
(
1975
).
53.
I. M.
Lifshitz
,
A. Y.
Grossberg
, and
A. R.
Khokhlov
,
Rev. Mod. Phys.
50
,
683
(
1978
).
54.
M.
Mezard
,
G.
Parisi
,
N.
Sourlas
,
G.
Toulouse
, and
M.
Virasoro
,
J. Phys. (France)
45
,
843
(
1984
).
This content is only available via PDF.
You do not currently have access to this content.