TY - JOUR
T1 - Tricritical trails on a square lattice with impenetrable linear boundary
T2 - Computer simulation and analytic bounds
AU - Chang, I. S.
AU - Meirovitch, H.
AU - Shapir, Y.
PY - 1990
Y1 - 1990
N2 - Using the scanning simulation method we study self-attracting trails (with energy per intersection) terminally attached to an impenetrable linear boundary on a square lattice, at their tricritical collapse transition. We obtain (with 95% confidence limits) that the partition function exponents are 1t=0.634-0.025 (for trails with one end attached to the boundary) and 11t=-0.440.02 (both ends are attached). These results differ significantly from the exact values (8/71.143 and (4/70.571, respectively, derived by Duplantier and Saleur (DS) [Phys. Rev. Lett. 59, 539 (1987)] for self-avoiding walks (SAW's) on a dilute hexagonal lattice at the FTHETA point. Our values are within the error bars of the numerical estimates of Seno and Stella for SAW's on the same lattice at the FTHETA point. The crossover exponent is calculated in several ways and the various results approximately converge to t0.71 if corrections to scaling are taken into account. This value is significantly larger than the DS exact value for the FTHET point =(3/70.43; it is also larger than recent numerical estimates of t for SAW's at the FTHETA point. These results suggest that tricritical trails are in a different universality class than SAW's in both the FTHETA and the FTHETA point. The results for the shape exponent t are consistent with the DS value (4/70.571. As expected the results for the tricritical temperature -/kBTt=1.0860.004 and the growth parameter t=2.99020.003 are equal to those obtained by the same method for trails on a square lattice without a boundary; these values are slightly smaller than their analytical upper bounds ln31.0986 and 3, respectively.
AB - Using the scanning simulation method we study self-attracting trails (with energy per intersection) terminally attached to an impenetrable linear boundary on a square lattice, at their tricritical collapse transition. We obtain (with 95% confidence limits) that the partition function exponents are 1t=0.634-0.025 (for trails with one end attached to the boundary) and 11t=-0.440.02 (both ends are attached). These results differ significantly from the exact values (8/71.143 and (4/70.571, respectively, derived by Duplantier and Saleur (DS) [Phys. Rev. Lett. 59, 539 (1987)] for self-avoiding walks (SAW's) on a dilute hexagonal lattice at the FTHETA point. Our values are within the error bars of the numerical estimates of Seno and Stella for SAW's on the same lattice at the FTHETA point. The crossover exponent is calculated in several ways and the various results approximately converge to t0.71 if corrections to scaling are taken into account. This value is significantly larger than the DS exact value for the FTHET point =(3/70.43; it is also larger than recent numerical estimates of t for SAW's at the FTHETA point. These results suggest that tricritical trails are in a different universality class than SAW's in both the FTHETA and the FTHETA point. The results for the shape exponent t are consistent with the DS value (4/70.571. As expected the results for the tricritical temperature -/kBTt=1.0860.004 and the growth parameter t=2.99020.003 are equal to those obtained by the same method for trails on a square lattice without a boundary; these values are slightly smaller than their analytical upper bounds ln31.0986 and 3, respectively.
UR - http://www.scopus.com/inward/record.url?scp=0009948743&partnerID=8YFLogxK
U2 - 10.1103/PhysRevA.41.1808
DO - 10.1103/PhysRevA.41.1808
M3 - Article
AN - SCOPUS:0009948743
SN - 1050-2947
VL - 41
SP - 1808
EP - 1822
JO - Physical Review A - Atomic, Molecular, and Optical Physics
JF - Physical Review A - Atomic, Molecular, and Optical Physics
IS - 4
ER -