Melting, reentrant ordering and peak effect for Wigner crystals with quenched and thermal disorder

Abstract: We consider simulations of Wigner crystals in solid state systems interacting with random quenched disorder in the presence of thermal fluctuations. When quenched disorder is absent, there is a well defined melting temperature determined by the proliferation of topological defects, while for zero temperature, there is a critical quenched disorder strength above which topological defects proliferate. When both thermal and quenched disorder are present, these effects compete, and the thermal fluctuations can red… Show more

“…For T/T m = 1.03, the system is disordered for all values of F p and the velocity is even higher but has a gradual drop with increasing F p , and the same trend occurs for T/T m = 1.36. A more detailed study of the general phase diagram for the disordered and ordered phases as a function of pinning strength versus temperature appears in [76]. The results in figures 1 and 2 indicate that the system exhibits three distinct regimes.…”

“…Throughout this work we fix n = 0.208 and n p = 0.25. At T = 0 and in the absence of quenched disorder, the charges form a triangular lattice that has a well defined melting transition temperature T m [76]. Additionally, when T = 0 there is a well defined quenched disorder strength above which the system disorders [76].…”

“…At T = 0 and in the absence of quenched disorder, the charges form a triangular lattice that has a well defined melting transition temperature T m [76]. Additionally, when T = 0 there is a well defined quenched disorder strength above which the system disorders [76]. We represent the charges using a previously studied model [52,65,[75][76][77][78][79][80], where the equation of motion for charge i is…”

“…Additionally, when T = 0 there is a well defined quenched disorder strength above which the system disorders [76]. We represent the charges using a previously studied model [52,65,[75][76][77][78][79][80], where the equation of motion for charge i is…”

“…We consider samples with F p = 0.5, a pinning strength at which the charges are disordered for T/T m = 0, so the system is in a strongly disordered glass phase. The T/T m = 0 plastic depinning that occurs in this regime was studied in detail in [76], where a pinned phase, a filamentary flow phase, a disordered flow phase, and a dynamically ordered moving smectic phase (MS) appear in sequence as a function of increasing drive.…”

Noise and thermal depinning of Wigner crystals

“…For T/T m = 1.03, the system is disordered for all values of F p and the velocity is even higher but has a gradual drop with increasing F p , and the same trend occurs for T/T m = 1.36. A more detailed study of the general phase diagram for the disordered and ordered phases as a function of pinning strength versus temperature appears in [76]. The results in figures 1 and 2 indicate that the system exhibits three distinct regimes.…”

“…Throughout this work we fix n = 0.208 and n p = 0.25. At T = 0 and in the absence of quenched disorder, the charges form a triangular lattice that has a well defined melting transition temperature T m [76]. Additionally, when T = 0 there is a well defined quenched disorder strength above which the system disorders [76].…”

“…At T = 0 and in the absence of quenched disorder, the charges form a triangular lattice that has a well defined melting transition temperature T m [76]. Additionally, when T = 0 there is a well defined quenched disorder strength above which the system disorders [76]. We represent the charges using a previously studied model [52,65,[75][76][77][78][79][80], where the equation of motion for charge i is…”

“…Additionally, when T = 0 there is a well defined quenched disorder strength above which the system disorders [76]. We represent the charges using a previously studied model [52,65,[75][76][77][78][79][80], where the equation of motion for charge i is…”

“…We consider samples with F p = 0.5, a pinning strength at which the charges are disordered for T/T m = 0, so the system is in a strongly disordered glass phase. The T/T m = 0 plastic depinning that occurs in this regime was studied in detail in [76], where a pinned phase, a filamentary flow phase, a disordered flow phase, and a dynamically ordered moving smectic phase (MS) appear in sequence as a function of increasing drive.…”

Noise and thermal depinning of Wigner crystals