Resonant-tunnelling conductance of a finite-size amorphous sample

Er'el Granot

doi:10.1088/0953-8984/11/43/318

Resonant-tunnelling conductance of a finite-size amorphous sample

Er'el Granot

פרסום מחקרי: פרסום בכתב עת › מאמר › ביקורת עמיתים

תקציר

The conductivity of an amorphous sample at low temperatures is calculated. While Mott's variable range hopping theory considers infinite samples, the proposed formalism treats finite ones. It turns out that this is a crucial difference. The model predicts a transition temperature (T_c) between two conductivity behaviours: ln(σ) ∼ -(T₂^L/T)^1/3 for T < T_c, and ln(σ) ∼ -(T₂^H/T)^1/2 for T > T_c (the transition temperature, T_c, depends on the Fermi energy and on the sample's characteristics). The former resembles the simple two-dimensional Mott conductivity behaviour, while the latter resembles the Efrös and Shklovskiǐ conductivity theory. We also show a simple connection between these temperatures: T_c = (T₂^H)³/(T₂^L)².

שפה מקורית	אנגלית
עמודים (מ-עד)	8547-8553
מספר עמודים	7
כתב עת	Journal of Physics Condensed Matter
כרך	11
מספר גיליון	43
מזהי עצם דיגיטלי (DOIs)	https://doi.org/10.1088/0953-8984/11/43/318
סטטוס פרסום	פורסם - 1 נוב׳ 1999
פורסם באופן חיצוני	כן

גישה למסמך

10.1088/0953-8984/11/43/318

קבצים וקישורים אחרים

Link to publication in Scopus

פורמט ציטוט ביבליוגרפי

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title = "Resonant-tunnelling conductance of a finite-size amorphous sample",

abstract = "The conductivity of an amorphous sample at low temperatures is calculated. While Mott's variable range hopping theory considers infinite samples, the proposed formalism treats finite ones. It turns out that this is a crucial difference. The model predicts a transition temperature (Tc) between two conductivity behaviours: ln(σ) ∼ -(T2L/T)1/3 for T < Tc, and ln(σ) ∼ -(T2H/T)1/2 for T > Tc (the transition temperature, Tc, depends on the Fermi energy and on the sample's characteristics). The former resembles the simple two-dimensional Mott conductivity behaviour, while the latter resembles the Efr{\"o}s and Shklovskiǐ conductivity theory. We also show a simple connection between these temperatures: Tc = (T2H)3/(T2L)2.",

author = "Er'el Granot",

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AB - The conductivity of an amorphous sample at low temperatures is calculated. While Mott's variable range hopping theory considers infinite samples, the proposed formalism treats finite ones. It turns out that this is a crucial difference. The model predicts a transition temperature (Tc) between two conductivity behaviours: ln(σ) ∼ -(T2L/T)1/3 for T < Tc, and ln(σ) ∼ -(T2H/T)1/2 for T > Tc (the transition temperature, Tc, depends on the Fermi energy and on the sample's characteristics). The former resembles the simple two-dimensional Mott conductivity behaviour, while the latter resembles the Efrös and Shklovskiǐ conductivity theory. We also show a simple connection between these temperatures: Tc = (T2H)3/(T2L)2.

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JO - Journal of Physics Condensed Matter

JF - Journal of Physics Condensed Matter

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Resonant-tunnelling conductance of a finite-size amorphous sample

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