New Criticality of 1D Fermions

A.A. Belavin; Al.B. Zamolodchikov; B. Duplantier; D.A. Kastor; F. David; G. Forgacs; H. Li; H.B. Thacker; J. Frohn; J. Villain; J.J. Rajasekaran; L. Balents; M. Kardar; M. Lässig; M. Lässig; M. Mutz; M.E. Fisher; M.E. Fisher; M.E. Fisher; M.P.M. den Nijs; Michael Lässig; R. Lipowsky; R. Netz; R. Netz; R. Netz; T.W. Burkhardt

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New Criticality of 1D Fermions

Authors: A.A. Belavin
Al.B. Zamolodchikov
B. Duplantier
D.A. Kastor
F. David
G. Forgacs
H. Li
H.B. Thacker
J. Frohn
J. Villain
J.J. Rajasekaran
L. Balents
M. Kardar
M. Lässig
M. Lässig
M. Mutz
M.E. Fisher
M.E. Fisher
M.E. Fisher
M.P.M. den Nijs
Michael Lässig
R. Lipowsky
R. Netz
R. Netz
R. Netz
T.W. Burkhardt
Publication date: 8 July 1994
Publisher: 'American Physical Society (APS)'
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Abstract

One-dimensional massive quantum particles (or 1+1-dimensional random walks) with short-ranged multi-particle interactions are studied by exact renormalization group methods. With repulsive pair forces, such particles are known to scale as free fermions. With finite

m

-body forces (m = 3,4,...), a critical instability is found, indicating the transition to a fermionic bound state. These unbinding transitions represent new universality classes of interacting fermions relevant to polymer and membrane systems. Implications for massless fermions, e.g. in the Hubbard model, are also noted. (to appear in Phys. Rev. Lett.)Comment: 10 pages (latex), with 2 figures (not included

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