Universal Short-Time Conductance Behavior Emerges between Two Adjacent Reservoirs

Er’el Granot

doi:10.3390/condmat9010015

Universal Short-Time Conductance Behavior Emerges between Two Adjacent Reservoirs

Er’el Granot

הנדסת חשמל ואלקטרוניקה

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תקציר

When a shutter, which differentiates between two adjacent particles’ reservoirs with a voltage gap, is lifted, a current emerges. In this paper, the temporal dynamics of this emerging current is analyzed. The main results are as follows: (A) the current’s prefactor in the short-time behavior is related to the long-time frequencies, by which the current converges to its equilibrium value (the conductance quantum unit 2e²/h). (B) In the short-time regime, the current is proportional to the square root of the time. (C) The maximum overshoot conductance is bounded by G_max = ζe²/h, where ζ is a universal value which is very close to Euler’s number. (D) Most of these results are valid for a thin wire in 3D, even in the presence of electron–electron interactions.

שפה מקורית	אנגלית
מספר המאמר	15
כתב עת	Condensed Matter
כרך	9
מספר גיליון	1
מזהי עצם דיגיטלי (DOIs)	https://doi.org/10.3390/condmat9010015
סטטוס פרסום	פורסם - מרץ 2024

גישה למסמך

10.3390/condmat9010015

קבצים וקישורים אחרים

Link to publication in Scopus

פורמט ציטוט ביבליוגרפי

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title = "Universal Short-Time Conductance Behavior Emerges between Two Adjacent Reservoirs",

abstract = "When a shutter, which differentiates between two adjacent particles{\textquoteright} reservoirs with a voltage gap, is lifted, a current emerges. In this paper, the temporal dynamics of this emerging current is analyzed. The main results are as follows: (A) the current{\textquoteright}s prefactor in the short-time behavior is related to the long-time frequencies, by which the current converges to its equilibrium value (the conductance quantum unit 2e2/h). (B) In the short-time regime, the current is proportional to the square root of the time. (C) The maximum overshoot conductance is bounded by Gmax = ζe2/h, where ζ is a universal value which is very close to Euler{\textquoteright}s number. (D) Most of these results are valid for a thin wire in 3D, even in the presence of electron–electron interactions.",

keywords = "conductance, instantaneous current, quantum conductance, short-time dynamics, universal dynamics",

author = "Er{\textquoteright}el Granot",

note = "Publisher Copyright: {\textcopyright} 2024 by the author.",

year = "2024",

month = mar,

doi = "10.3390/condmat9010015",

language = "אנגלית",

volume = "9",

journal = "Condensed Matter",

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N2 - When a shutter, which differentiates between two adjacent particles’ reservoirs with a voltage gap, is lifted, a current emerges. In this paper, the temporal dynamics of this emerging current is analyzed. The main results are as follows: (A) the current’s prefactor in the short-time behavior is related to the long-time frequencies, by which the current converges to its equilibrium value (the conductance quantum unit 2e2/h). (B) In the short-time regime, the current is proportional to the square root of the time. (C) The maximum overshoot conductance is bounded by Gmax = ζe2/h, where ζ is a universal value which is very close to Euler’s number. (D) Most of these results are valid for a thin wire in 3D, even in the presence of electron–electron interactions.

AB - When a shutter, which differentiates between two adjacent particles’ reservoirs with a voltage gap, is lifted, a current emerges. In this paper, the temporal dynamics of this emerging current is analyzed. The main results are as follows: (A) the current’s prefactor in the short-time behavior is related to the long-time frequencies, by which the current converges to its equilibrium value (the conductance quantum unit 2e2/h). (B) In the short-time regime, the current is proportional to the square root of the time. (C) The maximum overshoot conductance is bounded by Gmax = ζe2/h, where ζ is a universal value which is very close to Euler’s number. (D) Most of these results are valid for a thin wire in 3D, even in the presence of electron–electron interactions.

KW - conductance

KW - instantaneous current

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JO - Condensed Matter

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Universal Short-Time Conductance Behavior Emerges between Two Adjacent Reservoirs

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