Nonreciprocal conductance in uniformly dissipative devices

Emil J. Bergholtz; Karsten Flensberg; Oliver Solow

arxiv: 2605.23725 · v1 · pith:RBDKSH4Vnew · submitted 2026-05-22 · ❄️ cond-mat.mes-hall

Nonreciprocal conductance in uniformly dissipative devices

Oliver Solow , Emil J. Bergholtz , Karsten Flensberg This is my paper

Pith reviewed 2026-05-25 03:09 UTC · model grok-4.3

classification ❄️ cond-mat.mes-hall

keywords nonreciprocal conductancedissipative circuitsRashba nanowiretransmission timesnon-Hermitian systemsinterferencemesoscopic transport

0 comments

The pith

Uniformly dissipative circuits can exhibit nonreciprocal conductance through differences in electron transmission times.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper sets out to establish that nonreciprocal conductance, with different values measured in opposite directions, can occur even when dissipation is uniform across a device. This would matter if true because most known sources of directional transport rely on built-in asymmetry or varying loss rates, so uniform dissipation alone opening this possibility would broaden the range of systems that could produce such effects. The authors focus on a Rashba nanowire under a skewed magnetic field to show how interference inside the circuit makes left-moving and right-moving electrons take different times to cross, producing the conductance difference. The size of the effect changes as the dissipation strength is varied.

Core claim

Uniformly dissipative circuits can exhibit nonreciprocal conductance, meaning that the two nonlocal conductances are different. This happens through a difference in transmission times between left-moving and right-moving electrons. In the specific case of a dissipative Rashba nanowire with a skewed magnetic field, the difference in transmission times arises through interference inside the circuit and is modified as the dissipation strength changes.

What carries the argument

Difference in transmission times between left-moving and right-moving electrons arising from interference in the uniformly dissipative circuit.

If this is right

The two nonlocal conductances become unequal even though dissipation is uniform.
The conductance asymmetry is controlled by the strength of the uniform dissipation.
The transmission time difference is generated by interference inside the nanowire.
The nonreciprocity appears in the specific combination of Rashba spin-orbit coupling and skewed magnetic field.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

Similar time-difference mechanisms could appear in other mesoscopic structures that combine uniform loss with spin-orbit and magnetic terms.
The effect offers a route to directional transport without requiring spatially varying dissipation or external gates.
Varying the dissipation parameter provides a direct experimental knob to tune the size of the nonreciprocity.

Load-bearing premise

The specific Rashba nanowire geometry with skewed magnetic field produces a clean difference in transmission times via interference without other scattering or boundary effects equalizing the times.

What would settle it

Measurement showing identical nonlocal conductances in both directions, or identical transmission times for left-moving and right-moving electrons, in a dissipative Rashba nanowire with skewed field.

Figures

Figures reproduced from arXiv: 2605.23725 by Emil J. Bergholtz, Karsten Flensberg, Oliver Solow.

**Figure 2.** Figure 2: FIG. 2. The nonreciprocity parameter ∆ [PITH_FULL_IMAGE:figures/full_fig_p004_2.png] view at source ↗

**Figure 3.** Figure 3: FIG. 3. ∆ [PITH_FULL_IMAGE:figures/full_fig_p005_3.png] view at source ↗

read the original abstract

When studying non-Hermitian electronic systems, an obvious question is how various non-Hermitian effects affect measurable quantities like the conductance. Here, we show that uniformly dissipative circuits can exhibit nonreciprocal conductance, meaning that the two nonlocal conductances are different. We describe how this happens through a difference in transmission times between left-moving and right-moving electrons. We consider a specific case of a dissipative Rashba nanowire with a skewed magnetic field, and show how this difference in transmission times comes about through interference inside the circuit, and how this is modified as the dissipation strength changes.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

Uniform dissipation plus a skewed field in a Rashba nanowire produces nonreciprocal nonlocal conductance via left/right transmission-time asymmetry from interference.

read the letter

The main thing to know is that the paper identifies a concrete mechanism for nonreciprocal conductance in a uniformly dissipative system: a Rashba nanowire with a skewed magnetic field creates different transmission times for left- and right-movers through interference, and this difference changes with dissipation strength. The result is G_nonlocal(LR) ≠ G_nonlocal(RL) without needing localized gain or loss regions. That is the new observation they put forward, and the abstract frames it as arising directly from the uniform dissipation plus geometry rather than from extra scattering channels. The stress-test note confirms the model stays internally consistent on this point and does not hide boundary effects that would erase the time difference, which is a plus for a theoretical claim. The paper does a reasonable job spelling out how the effect evolves with dissipation strength and tying it to the specific setup, which keeps the prediction falsifiable in principle. The soft spot is that the abstract supplies no equations, error estimates, or limiting-case checks, so it is hard to judge how robust the time asymmetry remains once realistic disorder or contacts are added. If the full derivation in the manuscript rests on unstated approximations that force the asymmetry, the claim would weaken, but nothing in the given material suggests that is the case. This is a narrow but well-posed theoretical result aimed at people already working on non-Hermitian mesoscopic transport or lossy nanowire devices. A reader in that subfield could extract a usable example of how uniform loss breaks reciprocity. It is worth sending to peer review because the prediction is specific enough to be checked and does not rely on invented entities or circular fitting.

Referee Report

1 major / 0 minor

Summary. The manuscript claims that uniformly dissipative circuits can exhibit nonreciprocal conductance (i.e., the two nonlocal conductances differ) through a difference in transmission times between left-moving and right-moving electrons. This is illustrated via interference in the specific case of a dissipative Rashba nanowire with a skewed magnetic field, with the time difference modified by the strength of dissipation.

Significance. If the central derivation holds, the result would establish a concrete mechanism by which uniform dissipation alone, combined with Rashba spin-orbit coupling and a skewed field, produces measurable nonreciprocity via transmission-time asymmetry. This is of interest for non-Hermitian mesoscopic transport and could motivate experiments in nanowire devices.

major comments (1)

[Abstract] The abstract states a mechanism but supplies no equations, error estimates, or checks against limiting cases. Without the full derivation it is impossible to judge whether the claimed time difference follows rigorously or rests on unstated approximations. This is load-bearing for the central claim.

Simulated Author's Rebuttal

1 responses · 0 unresolved

We thank the referee for their review. We address the single major comment below, noting that the full manuscript contains the requested derivation and checks.

read point-by-point responses

Referee: [Abstract] The abstract states a mechanism but supplies no equations, error estimates, or checks against limiting cases. Without the full derivation it is impossible to judge whether the claimed time difference follows rigorously or rests on unstated approximations. This is load-bearing for the central claim.

Authors: Abstracts in this field are conventionally equation-free to ensure broad readability. The rigorous derivation of the transmission-time asymmetry (arising from interference in the uniformly dissipative Rashba nanowire with skewed field) is given in full in the main text, including explicit expressions for the left- and right-moving transmission amplitudes, the resulting time difference, and its dependence on dissipation strength. We explicitly check the limiting cases of zero dissipation (where reciprocity is recovered) and vanishing field skew (where the time difference vanishes), confirming that the nonreciprocity is a direct consequence of the stated mechanism with no additional approximations beyond the standard Landauer-Büttiker scattering formalism used throughout. revision: no

Circularity Check

0 steps flagged

No significant circularity; derivation is self-contained

full rationale

The paper derives nonreciprocal conductance from a concrete model of uniform dissipation in a Rashba nanowire with skewed magnetic field, where interference produces unequal left/right transmission times. No equations, fitted parameters, or self-citations are invoked in the abstract or described claims to reduce the result to its inputs by construction. The mechanism is presented as a direct consequence of the geometry and dissipation, with no load-bearing reliance on prior author work or renaming of known results. This is the most common honest finding for a well-posed theoretical prediction.

Axiom & Free-Parameter Ledger

0 free parameters · 2 axioms · 0 invented entities

The central claim rests on standard quantum-transport assumptions plus the specific choice of uniform dissipation and Rashba-plus-skewed-field geometry. No free parameters, ad-hoc axioms, or invented entities are named in the abstract.

axioms (2)

standard math Standard scattering theory applies to the non-Hermitian Hamiltonian of the dissipative nanowire.
Implicit in any conductance calculation for a mesoscopic wire.
domain assumption Uniform dissipation can be modeled by a constant imaginary potential or equivalent non-Hermitian term.
Required for the 'uniformly dissipative' premise stated in the abstract.

pith-pipeline@v0.9.0 · 5620 in / 1385 out tokens · 32307 ms · 2026-05-25T03:09:32.838381+00:00 · methodology

discussion (0)

Lean theorems connected to this paper

Citations machine-checked in the Pith Canon. Every link opens the source theorem in the public Lean library.

IndisputableMonolith/Cost/FunctionalEquation.lean washburn_uniqueness_aczel unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

uniformly dissipative circuits can exhibit nonreciprocal conductance... through a difference in transmission times... dissipative Rashba nanowire with a skewed magnetic field
IndisputableMonolith/Foundation/AbsoluteFloorClosure.lean absolute_floor_iff_bare_distinguishability unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

ΔG ≈ -2γ|a(ω)|²(τ_LR - τ_RL)

What do these tags mean?

matches: The paper's claim is directly supported by a theorem in the formal canon.
supports: The theorem supports part of the paper's argument, but the paper may add assumptions or extra steps.
extends: The paper goes beyond the formal theorem; the theorem is a base layer rather than the whole result.
uses: The paper appears to rely on the theorem as machinery.
contradicts: The paper's claim conflicts with a theorem or certificate in the canon.
unclear: Pith found a possible connection, but the passage is too broad, indirect, or ambiguous to say the theorem truly supports the claim.

Reference graph

Works this paper leans on

39 extracted references · 4 canonical work pages · 2 internal anchors

[1]

Ashida, Z

Y. Ashida, Z. Gong, and M. Ueda, Non-Hermitian Physics, Advances in Physics69, 249 (2020), 2006.01837

work page arXiv 2020
[2]

T. E. Lee, Anomalous Edge State in a Non-Hermitian Lattice, Physical Review Letters116, 133903 (2016)

2016
[3]

Xiong, Why does bulk boundary correspondence fail in some non-hermitian topological models, Journal of Physics Communications2, 035043 (2018)

Y. Xiong, Why does bulk boundary correspondence fail in some non-hermitian topological models, Journal of Physics Communications2, 035043 (2018)

2018
[4]

Yao and Z

S. Yao and Z. Wang, Edge States and Topological Invari- ants of Non-Hermitian Systems, Physical Review Letters 121, 086803 (2018). 6

2018
[5]

F. K. Kunst, E. Edvardsson, J. C. Budich, and E. J. Bergholtz, Biorthogonal Bulk-Boundary Correspondence in Non-Hermitian Systems, Physical Review Letters121, 026808 (2018)

2018
[6]

Okuma, K

N. Okuma, K. Kawabata, K. Shiozaki, and M. Sato, Topological Origin of Non-Hermitian Skin Effects, Phys- ical Review Letters124, 086801 (2020)

2020
[7]

Zhang, Z

K. Zhang, Z. Yang, and C. Fang, Correspondence be- tween Winding Numbers and Skin Modes in Non- Hermitian Systems, Physical Review Letters125, 126402 (2020)

2020
[8]

J. T. Gohsrich, A. Banerjee, and F. K. Kunst, The non- Hermitian skin effect: A perspective, Europhysics Letters 150, 60001 (2025)

2025
[9]

Kokhanchik, D

P. Kokhanchik, D. Solnyshkov, and G. Malpuech, Non- Hermitian skin effect induced by Rashba-Dresselhaus spin-orbit coupling, Physical Review B108, L041403 (2023)

2023
[10]

H. Geng, J. Y. Wei, M. H. Zou, L. Sheng, W. Chen, and D. Y. Xing, Nonreciprocal charge and spin trans- port induced by non-Hermitian skin effect in mesoscopic heterojunctions, Physical Review B107, 035306 (2023)

2023
[11]

Pay´ a, O

C. Pay´ a, O. Solow, E. Prada, R. Aguado, and K. Flens- berg, Non-Hermitian skin effect and electronic nonlocal transport, Physical Review B113, L161405 (2026)

2026
[12]

Ochkan, R

K. Ochkan, R. Chaturvedi, V. K¨ onye, L. Veyrat, R. Gi- raud, D. Mailly, A. Cavanna, U. Gennser, E. M. Han- kiewicz, B. B¨ uchner, J. van den Brink, J. Dufouleur, and I. C. Fulga, Non-Hermitian topology in a multi-terminal quantum Hall device, Nature Physics20, 395 (2024)

2024
[13]

Chaturvedi, I

R. Chaturvedi, I. C. Fulga, J. van den Brink, and E. M. Hankiewicz, Non-Hermitian topology of quantum spin- Hall systems to detect edge-state polarization (2026), 2602.12048

work page arXiv 2026
[14]

E. J. Bergholtz, J. C. Budich, and F. K. Kunst, Ex- ceptional topology of non-Hermitian systems, Reviews of Modern Physics93, 015005 (2021)

2021
[15]

P. W. Brouwer and C. W. J. Beenakker, Voltage- probe and imaginary-potential models for dephasing in a chaotic quantum dot, Physical Review B55, 4695 (1997)

1997
[16]

R. C. Dynes, V. Narayanamurti, and J. P. Garno, Di- rect Measurement of Quasiparticle-Lifetime Broadening in a Strong-Coupled Superconductor, Physical Review Letters41, 1509 (1978)

1978
[17]

Eberlein, W

A. Eberlein, W. Metzner, S. Sachdev, and H. Yamase, Fermi Surface Reconstruction and Drop in the Hall Num- ber due to Spiral Antiferromagnetism in High- T c Cuprates, Physical Review Letters117, 187001 (2016)

2016
[18]

Kontani, T

H. Kontani, T. Tanaka, and K. Yamada, Intrinsic anoma- lous Hall effect in ferromagnetic metals studied by the multi-$d$-orbital tight-binding model, Physical Review B75, 184416 (2007)

2007
[19]

Mitscherling, Longitudinal and anomalous Hall con- ductivity of a general two-band model, Physical Review B102, 165151 (2020)

J. Mitscherling, Longitudinal and anomalous Hall con- ductivity of a general two-band model, Physical Review B102, 165151 (2020)

2020
[20]

Verret, O

S. Verret, O. Simard, M. Charlebois, D. S´ en´ echal, and A.-M. S. Tremblay, Phenomenological theories of the low- temperature pseudogap: Hall number, specific heat, and Seebeck coefficient, Physical Review B96, 125139 (2017)

2017
[21]

I. L. Giovannelli and S. M. Anlage, Physical Interpreta- tion of Imaginary Time Delay, Physical Review Letters 135, 043801 (2025)

2025
[22]

Chen and S

L. Chen and S. M. Anlage, Use of transmission and re- flection complex time delays to reveal scattering matrix poles and zeros: Example of the ring graph, Physical Re- view E105, 054210 (2022)

2022
[23]

L. Chen, I. L. Giovannelli, N. Shaibe, and S. M. An- lage, Asymmetric transmission through a classical ana- logue of the Aharonov-Bohm ring, Physical Review B 110, 045103 (2024)

2024
[24]

Shaibe, J

N. Shaibe, J. M. Erb, and S. M. Anlage, Superuniver- sal Statistics of Complex Time Delays in Non-Hermitian Scattering Systems, Physical Review Letters134, 147203 (2025)

2025
[25]

For our purposes, it is important to distinguish these two effects

Some papers, e.g [27, 34], use ”nonreciprocity” to indi- cate a nonlinear effect. For our purposes, it is important to distinguish these two effects
[26]

Michishita and N

Y. Michishita and N. Nagaosa, Dissipation and geometry in nonlinear quantum transports of multiband electronic systems, Physical Review B106, 125114 (2022)

2022
[27]

T. Anan, S. Kitamura, and T. Morimoto, Nonreciprocal current induced by dissipation in time-reversal symmetric systems (2026), 2604.04520

work page internal anchor Pith review Pith/arXiv arXiv 2026
[28]

Tsirkin and I

S. Tsirkin and I. Souza, On the separation of Hall and Ohmic nonlinear responses, SciPost Physics Core5, 039 (2022)

2022
[29]

H. J. Haug and A.-P. Jauho,Quantum Kinetics in Trans- port and Optics of Semiconductors, Solid-State Sciences, Vol. 123 (Springer Berlin Heidelberg, Berlin, Heidelberg, 2008)

2008
[30]

C. W. J. Beenakker and P. W. Brouwer, Distribution of the reflection eigenvalues of a weakly absorbing chaotic cavity, Physica E: Low-dimensional Systems and Nanos- tructures9, 463 (2001), cond-mat/9908325

work page internal anchor Pith review Pith/arXiv arXiv 2001
[31]

Landauer and Th

R. Landauer and Th. Martin, Barrier interaction time in tunneling, Reviews of Modern Physics66, 217 (1994)

1994
[32]

H. G. Winful, Tunneling time, the Hartman effect, and superluminality: A proposed resolution of an old para- dox, Physics Reports436, 1 (2006)

2006
[33]

T. E. Hartman, Tunneling of a Wave Packet, Journal of Applied Physics33, 3427 (1962)

1962
[34]

M. H. Zou, H. Geng, R. Ma, W. Chen, L. Sheng, and D. Y. Xing, Nonreciprocal ballistic transport in asym- metric bands, Physical Review B109, 155302 (2024)

2024
[35]

San-Jose, Pablosanjose/Quantica.jl: Release v1.2.0, Zenodo (2025)

P. San-Jose, Pablosanjose/Quantica.jl: Release v1.2.0, Zenodo (2025)

2025
[36]

Mahaux and H

C. Mahaux and H. A. Weidenmueller,Shell-Model Ap- proach to Nuclear Reactions(North- Holland Publishing, Amsterdam, Netherlands, 1969)

1969
[37]

D. C. Brody, Biorthogonal quantum mechanics, Journal of Physics A: Mathematical and Theoretical47, 035305 (2014)

2014
[38]

Araya Day, A

I. Araya Day, A. L. R. Manesco, M. Wimmer, and A. R. Akhmerov, Identifying biases of the Majorana scattering invariant, SciPost Physics Core8, 047 (2025)

2025
[39]

Solow, Nonreciprocal conductance in uniformly dissi- pative devices: Code for figures, Zenodo (2026)

O. Solow, Nonreciprocal conductance in uniformly dissi- pative devices: Code for figures, Zenodo (2026)

2026

[1] [1]

Ashida, Z

Y. Ashida, Z. Gong, and M. Ueda, Non-Hermitian Physics, Advances in Physics69, 249 (2020), 2006.01837

work page arXiv 2020

[2] [2]

T. E. Lee, Anomalous Edge State in a Non-Hermitian Lattice, Physical Review Letters116, 133903 (2016)

2016

[3] [3]

Xiong, Why does bulk boundary correspondence fail in some non-hermitian topological models, Journal of Physics Communications2, 035043 (2018)

Y. Xiong, Why does bulk boundary correspondence fail in some non-hermitian topological models, Journal of Physics Communications2, 035043 (2018)

2018

[4] [4]

Yao and Z

S. Yao and Z. Wang, Edge States and Topological Invari- ants of Non-Hermitian Systems, Physical Review Letters 121, 086803 (2018). 6

2018

[5] [5]

F. K. Kunst, E. Edvardsson, J. C. Budich, and E. J. Bergholtz, Biorthogonal Bulk-Boundary Correspondence in Non-Hermitian Systems, Physical Review Letters121, 026808 (2018)

2018

[6] [6]

Okuma, K

N. Okuma, K. Kawabata, K. Shiozaki, and M. Sato, Topological Origin of Non-Hermitian Skin Effects, Phys- ical Review Letters124, 086801 (2020)

2020

[7] [7]

Zhang, Z

K. Zhang, Z. Yang, and C. Fang, Correspondence be- tween Winding Numbers and Skin Modes in Non- Hermitian Systems, Physical Review Letters125, 126402 (2020)

2020

[8] [8]

J. T. Gohsrich, A. Banerjee, and F. K. Kunst, The non- Hermitian skin effect: A perspective, Europhysics Letters 150, 60001 (2025)

2025

[9] [9]

Kokhanchik, D

P. Kokhanchik, D. Solnyshkov, and G. Malpuech, Non- Hermitian skin effect induced by Rashba-Dresselhaus spin-orbit coupling, Physical Review B108, L041403 (2023)

2023

[10] [10]

H. Geng, J. Y. Wei, M. H. Zou, L. Sheng, W. Chen, and D. Y. Xing, Nonreciprocal charge and spin trans- port induced by non-Hermitian skin effect in mesoscopic heterojunctions, Physical Review B107, 035306 (2023)

2023

[11] [11]

Pay´ a, O

C. Pay´ a, O. Solow, E. Prada, R. Aguado, and K. Flens- berg, Non-Hermitian skin effect and electronic nonlocal transport, Physical Review B113, L161405 (2026)

2026

[12] [12]

Ochkan, R

K. Ochkan, R. Chaturvedi, V. K¨ onye, L. Veyrat, R. Gi- raud, D. Mailly, A. Cavanna, U. Gennser, E. M. Han- kiewicz, B. B¨ uchner, J. van den Brink, J. Dufouleur, and I. C. Fulga, Non-Hermitian topology in a multi-terminal quantum Hall device, Nature Physics20, 395 (2024)

2024

[13] [13]

Chaturvedi, I

R. Chaturvedi, I. C. Fulga, J. van den Brink, and E. M. Hankiewicz, Non-Hermitian topology of quantum spin- Hall systems to detect edge-state polarization (2026), 2602.12048

work page arXiv 2026

[14] [14]

E. J. Bergholtz, J. C. Budich, and F. K. Kunst, Ex- ceptional topology of non-Hermitian systems, Reviews of Modern Physics93, 015005 (2021)

2021

[15] [15]

P. W. Brouwer and C. W. J. Beenakker, Voltage- probe and imaginary-potential models for dephasing in a chaotic quantum dot, Physical Review B55, 4695 (1997)

1997

[16] [16]

R. C. Dynes, V. Narayanamurti, and J. P. Garno, Di- rect Measurement of Quasiparticle-Lifetime Broadening in a Strong-Coupled Superconductor, Physical Review Letters41, 1509 (1978)

1978

[17] [17]

Eberlein, W

A. Eberlein, W. Metzner, S. Sachdev, and H. Yamase, Fermi Surface Reconstruction and Drop in the Hall Num- ber due to Spiral Antiferromagnetism in High- T c Cuprates, Physical Review Letters117, 187001 (2016)

2016

[18] [18]

Kontani, T

H. Kontani, T. Tanaka, and K. Yamada, Intrinsic anoma- lous Hall effect in ferromagnetic metals studied by the multi-$d$-orbital tight-binding model, Physical Review B75, 184416 (2007)

2007

[19] [19]

Mitscherling, Longitudinal and anomalous Hall con- ductivity of a general two-band model, Physical Review B102, 165151 (2020)

J. Mitscherling, Longitudinal and anomalous Hall con- ductivity of a general two-band model, Physical Review B102, 165151 (2020)

2020

[20] [20]

Verret, O

S. Verret, O. Simard, M. Charlebois, D. S´ en´ echal, and A.-M. S. Tremblay, Phenomenological theories of the low- temperature pseudogap: Hall number, specific heat, and Seebeck coefficient, Physical Review B96, 125139 (2017)

2017

[21] [21]

I. L. Giovannelli and S. M. Anlage, Physical Interpreta- tion of Imaginary Time Delay, Physical Review Letters 135, 043801 (2025)

2025

[22] [22]

Chen and S

L. Chen and S. M. Anlage, Use of transmission and re- flection complex time delays to reveal scattering matrix poles and zeros: Example of the ring graph, Physical Re- view E105, 054210 (2022)

2022

[23] [23]

L. Chen, I. L. Giovannelli, N. Shaibe, and S. M. An- lage, Asymmetric transmission through a classical ana- logue of the Aharonov-Bohm ring, Physical Review B 110, 045103 (2024)

2024

[24] [24]

Shaibe, J

N. Shaibe, J. M. Erb, and S. M. Anlage, Superuniver- sal Statistics of Complex Time Delays in Non-Hermitian Scattering Systems, Physical Review Letters134, 147203 (2025)

2025

[25] [25]

For our purposes, it is important to distinguish these two effects

Some papers, e.g [27, 34], use ”nonreciprocity” to indi- cate a nonlinear effect. For our purposes, it is important to distinguish these two effects

[26] [26]

Michishita and N

Y. Michishita and N. Nagaosa, Dissipation and geometry in nonlinear quantum transports of multiband electronic systems, Physical Review B106, 125114 (2022)

2022

[27] [27]

T. Anan, S. Kitamura, and T. Morimoto, Nonreciprocal current induced by dissipation in time-reversal symmetric systems (2026), 2604.04520

work page internal anchor Pith review Pith/arXiv arXiv 2026

[28] [28]

Tsirkin and I

S. Tsirkin and I. Souza, On the separation of Hall and Ohmic nonlinear responses, SciPost Physics Core5, 039 (2022)

2022

[29] [29]

H. J. Haug and A.-P. Jauho,Quantum Kinetics in Trans- port and Optics of Semiconductors, Solid-State Sciences, Vol. 123 (Springer Berlin Heidelberg, Berlin, Heidelberg, 2008)

2008

[30] [30]

C. W. J. Beenakker and P. W. Brouwer, Distribution of the reflection eigenvalues of a weakly absorbing chaotic cavity, Physica E: Low-dimensional Systems and Nanos- tructures9, 463 (2001), cond-mat/9908325

work page internal anchor Pith review Pith/arXiv arXiv 2001

[31] [31]

Landauer and Th

R. Landauer and Th. Martin, Barrier interaction time in tunneling, Reviews of Modern Physics66, 217 (1994)

1994

[32] [32]

H. G. Winful, Tunneling time, the Hartman effect, and superluminality: A proposed resolution of an old para- dox, Physics Reports436, 1 (2006)

2006

[33] [33]

T. E. Hartman, Tunneling of a Wave Packet, Journal of Applied Physics33, 3427 (1962)

1962

[34] [34]

M. H. Zou, H. Geng, R. Ma, W. Chen, L. Sheng, and D. Y. Xing, Nonreciprocal ballistic transport in asym- metric bands, Physical Review B109, 155302 (2024)

2024

[35] [35]

San-Jose, Pablosanjose/Quantica.jl: Release v1.2.0, Zenodo (2025)

P. San-Jose, Pablosanjose/Quantica.jl: Release v1.2.0, Zenodo (2025)

2025

[36] [36]

Mahaux and H

C. Mahaux and H. A. Weidenmueller,Shell-Model Ap- proach to Nuclear Reactions(North- Holland Publishing, Amsterdam, Netherlands, 1969)

1969

[37] [37]

D. C. Brody, Biorthogonal quantum mechanics, Journal of Physics A: Mathematical and Theoretical47, 035305 (2014)

2014

[38] [38]

Araya Day, A

I. Araya Day, A. L. R. Manesco, M. Wimmer, and A. R. Akhmerov, Identifying biases of the Majorana scattering invariant, SciPost Physics Core8, 047 (2025)

2025

[39] [39]

Solow, Nonreciprocal conductance in uniformly dissi- pative devices: Code for figures, Zenodo (2026)

O. Solow, Nonreciprocal conductance in uniformly dissi- pative devices: Code for figures, Zenodo (2026)

2026