Imaging of Submicroampere Currents in Bilayer Graphene Using a Scanning Diamond Magnetometer
M.L. Palm, W.S. Huxter, P. Welter, S. Ernst, P.J. Scheidegger, S. Diesch, K. Chang, P. Rickhaus, T. Taniguchi, K. Watanabe, K. Ensslin, and C.L. Degen
Phys. Rev. Applied 17, 054008 (2022) – Published 5 May 2022

Current imaging via scanning diamond magnetometry is a valuable tool in the study of transport phenomena, due to its applicability over a wide temperature range, but its sensitivity for resolving subtle features and small currents has remained limited. By implementing ac measurement protocols and phase-unwrapping schemes, the authors detect currents below 1 µA in bilayer graphene, and resolve minute variations on top of background signals. They also observe current-density variations due to a varying background potential, and discuss measurement-induced back-action and how to avoid it. These advances establish scanning diamond magnetometry as an excellent option for current imaging.

Show Abstract 
Graphene
Nanophysics
Quantum Physics
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Editors' Suggestion
Topological Characterization of Dynamic Chiral Magnetic Textures Using Machine Learning
Tim Matthies, Alexander F. Schäffer, Thore Posske, Roland Wiesendanger, and Elena Y. Vedmedenko
Phys. Rev. Applied 17, 054022 (2022) – Published 13 May 2022

Characterizing magnetic textures is important for applications in stochastic computing and memory devices based on magnetic skyrmions. Knowing the exact number of skyrmions is essential for these tasks, yet this count is particularly difficult to determine when dealing with quickly moving skyrmions at nonzero temperatures, where only time-averaged, smeared results are available. The present study uses machine-learning techniques to solve this problem successfully, to the benefit of future investigations in spintronic computation and memory applications.

Show Abstract 
Computational Physics
Magnetism
Spintronics
PDFHTML
Editors' Suggestion
Computational Verification and Experimental Validation of the Vibration-Attenuation Properties of a Geometrically Nonlinear Metamaterial Design
Kyriakos Alexandros Chondrogiannis, Andrea Colombi, Vasilis Dertimanis, and Eleni Chatzi
Phys. Rev. Applied 17, 054023 (2022) – Published 13 May 2022

Metamaterials continue to be conceptually intriguing for the manipulation of propagating waves. However, preventing low-frequency wave propagation proves to be challenging, due to limited metamaterial dimensions and mass. This study focuses on a metamaterial lattice featuring geometrically nonlinear behavior that can lead to negative stiffness, aimed at overcoming the requirement of large mass for low-frequency vibration attenuation. This approach can find application in structural engineering to protect against low-frequency excitations—such as earthquakes.

Show Abstract 
Acoustics
Geophysics
Metamaterials
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Editors' Suggestion
Viscosity-Limited Drift Instabilities in Two-Dimensional Electron Systems
Aleksandr S. Petrov and Dmitry Svintsov
Phys. Rev. Applied 17, 054026 (2022) – Published 16 May 2022

Terahertz technology suffers from a lack of efficient emitters, but dc excitation of plasma waves in two-dimensional electron systems (2DESs) is a promising solution. Ultrahigh-mobility 2DESs would help to avoid the Ohmic losses that have plagued the implementation of such devices, but reduced Ohmic loss comes at the cost of damping via viscous loss. The authors exploit a recently developed perturbative technique to develop a systematic treatment of viscosity-induced plasmon damping, and provide a powerful tool for optimizing plasmonic resonators.

Show Abstract 
Condensed Matter Physics
Optoelectronics
Plasmonics
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Editors' Suggestion
Quasi-Fermi-Level Phase Space and its Applications in Ambipolar Two-Dimensional Field-Effect Transistors
Zhao-Yi Yan, Kan-Hao Xue, Zhan Hou, Yang Shen, He Tian, Yi Yang, and Tian-Ling Ren
Phys. Rev. Applied 17, 054027 (2022) – Published 17 May 2022

Quasi-Fermi levels (QFLs) have become a canonical concept in semiconductor device modeling. However, a global model to cover both unipolar and ambipolar transport modes of two-dimensional field-effect transistors (2D FETs) based on QFLs is still needed, as it is challenging to capture quantitatively the effect of QFL splitting on transport. This work establishes a theoretical platform to account for that effect: the quasi-Fermi-level phase space (QFLPS). With QFLPS a unified picture of unipolar and ambipolar transport is drawn, the working modes of 2D FETs acquire more intuitive physical interpretations, and many valuable outcomes for device modeling and circuit design are realized.

Show Abstract 
Electronics
Semiconductor Physics
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Editors' Suggestion
Topological Field-Effect Transistor Based on Quasi-Two-Dimensional Tellurium Flakes
Bin Cheng, Lin Li, Nan Zhang, Ling Zhang, Xianglin Li, Zhiyong Lin, Hui Li, Zhengfei Wang, and Changgan Zeng
Phys. Rev. Applied 17, 054044 (2022) – Published 26 May 2022

The emergent topological semimetals have received considerable attention for developing innovative devices, mainly due to their novel topological electronic properties with high robustness against external perturbations. Progress has been hindered, though, due to a lack of tunability. Here the authors address this challenge by constructing a field-effect device based on thin flakes of tellurium, a semiconductor with a chiral Weyl node. In this device, the conducting and topological states can be simultaneously switched electrostatically, yielding giant modulations of both channel conductivity and chiral-anomaly-induced magnetoresistance.

Show Abstract 
Electronics
Semiconductor Physics
Topological Insulators
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LETTERS
Letter
Room-Temperature van der Waals Perpendicular Ferromagnet Through Interlayer Magnetic Coupling
Yi Cao, Xiaomin Zhang, Xian-Peng Zhang, Faguang Yan, Ziao Wang, Wenkai Zhu, Hao Tan, Vitaly N. Golovach, Houzhi Zheng, and Kaiyou Wang
Phys. Rev. Applied 17, L051001 (2022) – Published 10 May 2022

High-density spintronic applications such as digital memory require strong perpendicular magnetic anisotropy (PMA), to maintain data stability above room temperature, which so far has been beyond the reach of stacked van der Waals ferromagnets. Here the authors demonstrate that the interlayer exchange coupling in a magnetic multilayer can effectively tune the Curie temperature and PMA of sandwiched two-dimensional (2D) Fe
3
GeTe
2
. The successful realization of room-temperature 2D ferromagnets bearing fully nonvolatile out-of-plane spin information could bring 2D spintronic applications to reality.

Show Abstract 
Magnetism
Materials Science
Spintronics
PDFHTML
Letter
Reducing Spontaneous Orientational Polarization via Semiconductor Dilution Improves OLED Efficiency and Lifetime
Emmanuel O. Afolayan, Ibrahim Dursun, Chao Lang, Evgeny Pakhomenko, Marina Kondakova, Michael Boroson, Michael Hickner, Russell J. Holmes, and Noel C. Giebink
Phys. Rev. Applied 17, L051002 (2022) – Published 26 May 2022

The spontaneous alignment of molecular dipoles that occurs in many organic light-emitting diodes (OLEDs) is known to blunt their performance, but is not easy to control within a given device stack. This study shows that coevaporating a small amount of polyethylene in the electron-transport layer of an OLED dramatically reduces the spontaneous orientational polarization, leading to increased device efficiency and lifetime due to decreased exciton-polaron annihilation in the emissive layer. This result highlights the potential of semiconductor dilution to improve OLED performance, and provides a new means to understand exciton-polaron-driven degradation in blue OLEDs.

Show Abstract 
Energy Research
Optoelectronics
Semiconductor Physics
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ARTICLES
Spatiotemporal Metasurface to Control Electromagnetic Wave Scattering
Na Zhang, Ke Chen, Qi Hu, Jianmin Zhao, Junming Zhao, Tian Jiang, and Yijun Feng
Phys. Rev. Applied 17, 054001 (2022) – Published 2 May 2022
Show Abstract 
Metamaterials
Optics
PDFHTML
High-Performance Hyperentanglement Generation and Manipulation Based on Lithium Niobate Waveguides
Yiwen Huang, Juan Feng, Yuanhua Li, Zhantong Qi, Chuangyi Lu, Yuanlin Zheng, and Xianfeng Chen
Phys. Rev. Applied 17, 054002 (2022) – Published 2 May 2022
Show Abstract 
Photonics
Quantum Information
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Inversely Designed Second-Order Photonic Topological Insulator With Multiband Corner States
Yafeng Chen, Zhihao Lan, and Jie Zhu
Phys. Rev. Applied 17, 054003 (2022) – Published 2 May 2022
Show Abstract 
Metamaterials
Photonics
Topological Insulators
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Nonreciprocal Phonon Blockade in a Spinning Acoustic Ring Cavity Coupled to a Two-Level System
Xiao-Yu Yao, Hamad Ali, Fu-Li Li, and Peng-Bo Li
Phys. Rev. Applied 17, 054004 (2022) – Published 3 May 2022
Show Abstract 
Acoustics
Optics
Quantum Information
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Spin-Optical Dynamics and Quantum Efficiency of a Single V1 Center in Silicon Carbide
Naoya Morioka, Di Liu, Öney O. Soykal, Izel Gediz, Charles Babin, Rainer Stöhr, Takeshi Ohshima, Nguyen Tien Son, Jawad Ul-Hassan, Florian Kaiser, and Jörg Wrachtrup
Phys. Rev. Applied 17, 054005 (2022) – Published 3 May 2022
Show Abstract 
Photonics
Quantum Information
Semiconductor Physics
PDFHTML
Flopping-Mode Electric Dipole Spin Resonance in Phosphorus Donor Qubits in Silicon
F.N. Krauth, S.K. Gorman, Y. He, M.T. Jones, P. Macha, S. Kocsis, C. Chua, B. Voisin, S. Rogge, R. Rahman, Y. Chung, and M.Y. Simmons
Phys. Rev. Applied 17, 054006 (2022) – Published 4 May 2022
Show Abstract 
Magnetism
Quantum Information
Semiconductor Physics
PDFHTML
Spin-Photon Coupling for Atomic Qubit Devices in Silicon
Edyta N. Osika, Sacha Kocsis, Yu-Ling Hsueh, Serajum Monir, Cassandra Chua, Hubert Lam, Benoit Voisin, Michelle Y. Simmons, Sven Rogge, and Rajib Rahman
Phys. Rev. Applied 17, 054007 (2022) – Published 4 May 2022
Show Abstract 
Optoelectronics
Quantum Information
Semiconductor Physics
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Editors' Suggestion
Imaging of Submicroampere Currents in Bilayer Graphene Using a Scanning Diamond Magnetometer
M.L. Palm, W.S. Huxter, P. Welter, S. Ernst, P.J. Scheidegger, S. Diesch, K. Chang, P. Rickhaus, T. Taniguchi, K. Watanabe, K. Ensslin, and C.L. Degen
Phys. Rev. Applied 17, 054008 (2022) – Published 5 May 2022

Current imaging via scanning diamond magnetometry is a valuable tool in the study of transport phenomena, due to its applicability over a wide temperature range, but its sensitivity for resolving subtle features and small currents has remained limited. By implementing ac measurement protocols and phase-unwrapping schemes, the authors detect currents below 1 µA in bilayer graphene, and resolve minute variations on top of background signals. They also observe current-density variations due to a varying background potential, and discuss measurement-induced back-action and how to avoid it. These advances establish scanning diamond magnetometry as an excellent option for current imaging.

Show Abstract 
Graphene
Nanophysics
Quantum Physics
PDFHTML
Dipole-Engineering Strategy for Regulating the Electronic Contact of a Two-Dimensional 
Sb
X/Graphene (X = 
P
, 
As
, 
Bi
) van der Waals Interface
Jing Li, Wenqiang Liu, Wenhan Zhou, Jialin Yang, Hengze Qu, Yang Hu, and Shengli Zhang
Phys. Rev. Applied 17, 054009 (2022) – Published 5 May 2022
Show Abstract 
Nanophysics
Optoelectronics
Semiconductor Physics
PDFHTML
Multifunctional Two-Dimensional 
VSi
2
N
4
/
WSi
2
N
4
/
VSi
2
N
4
 Photodetector Driven by the Photogalvanic Effect
Li Shu, Liyu Qian, Xiang Ye, and Yiqun Xie
Phys. Rev. Applied 17, 054010 (2022) – Published 6 May 2022
Show Abstract 
Optoelectronics
Semiconductor Physics
Spintronics
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Nitrogen Decoration of Basal-Plane Dislocations in 
4
H
-
SiC
Jiajun Li, Hao Luo, Guang Yang, Yiqiang Zhang, Xiaodong Pi, Deren Yang, and Rong Wang
Phys. Rev. Applied 17, 054011 (2022) – Published 6 May 2022
Show Abstract 
Electronics
Semiconductor Physics
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Microwave Metasurface Cloaking for Freestanding Objects
Hakjune Lee and Do-Hoon Kwon
Phys. Rev. Applied 17, 054012 (2022) – Published 9 May 2022
Show Abstract 
Metamaterials
Optics
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High-
Q
 Microwave Dielectric Resonator for Axion Dark-Matter Haloscopes
R. Di Vora, D. Alesini, C. Braggio, G. Carugno, N. Crescini, D. D’Agostino, D. Di Gioacchino, P. Falferi, U. Gambardella, C. Gatti, G. Iannone, C. Ligi, A. Lombardi, G. Maccarrone, A. Ortolan, R. Pengo, A. Rettaroli, G. Ruoso, L. Taffarello, and S. Tocci
Phys. Rev. Applied 17, 054013 (2022) – Published 9 May 2022
Show Abstract 
Astrophysics
Magnetism
Optoelectronics
PDFHTML
Abruptly Autofocusing Twisted Optical Bottle Beams
You Wu, Zejia Lin, Chuangjie Xu, Danlin Xu, Haiqi Huang, Jiajia Zhao, Zhenwu Mo, Junjie Jiang, Haobin Yang, Liping Zhang, Hongzhan Liu, Dongmei Deng, and Lingling Shui
Phys. Rev. Applied 17, 054014 (2022) – Published 9 May 2022
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Optics
PDFHTML
Resonant Excitation-Induced Nonlinear Mode Coupling in a Microcantilever Resonator
Yanyan Li, Wenyao Luo, Zhixin Zhao, and Duo Liu
Phys. Rev. Applied 17, 054015 (2022) – Published 10 May 2022
Show Abstract 
Mechanics
Nonlinear Dynamics
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Wave Optics of Differential Absorption Spectroscopy in Thick-Junction Organic Solar Cells: Optical Artifacts and Correction Strategies
Bowen Sun, Oskar J. Sandberg, Dieter Neher, Ardalan Armin, and Safa Shoaee
Phys. Rev. Applied 17, 054016 (2022) – Published 10 May 2022
Show Abstract 
Energy Research
Optoelectronics
Semiconductor Physics
PDFHTML
Strong Angular-Momentum Optomechanical Coupling for Macroscopic Quantum Control
Yuan Liu, Yaoming Chu, Shaoliang Zhang, and Jianming Cai
Phys. Rev. Applied 17, 054017 (2022) – Published 11 May 2022
Show Abstract 
Mechanics
Optics
Quantum Physics
PDFHTML
Predicting Non-Markovian Superconducting-Qubit Dynamics from Tomographic Reconstruction
Haimeng Zhang, Bibek Pokharel, E.M. Levenson-Falk, and Daniel Lidar
Phys. Rev. Applied 17, 054018 (2022) – Published 11 May 2022
Show Abstract 
Optics
Quantum Information
Superconductivity
PDFHTML
Simple-Diffraction-Based Deep Learning to Reconstruct a High-Dimensional Orbital-Angular-Momentum Spectrum Via Single-Shot Measurement
Haoxu Guo, Xiaodong Qiu, and Lixiang Chen
Phys. Rev. Applied 17, 054019 (2022) – Published 11 May 2022
Show Abstract 
Optics
Quantum Physics
Quantum Information
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Incident-Angle-Dependent Extraordinary Transmission of the Terahertz Bull’s-Eye Structure
Yu Tokizane, Seigo Ohno, Yuma Takida, Jun-ichi Shikata, and Hiroaki Minamide
Phys. Rev. Applied 17, 054020 (2022) – Published 12 May 2022
Show Abstract 
Optics
Photonics
Plasmonics
PDFHTML
Multinode State Transfer and Nonlocal State Preparation via a Unidirectional Quantum Network
Hao Ai, Ying-Yü Fang, Cheng-Rui Feng, Zhihui Peng, and Ze-Liang Xiang
Phys. Rev. Applied 17, 054021 (2022) – Published 12 May 2022
Show Abstract 
Optics
Quantum Information
PDFHTML
Editors' Suggestion
Topological Characterization of Dynamic Chiral Magnetic Textures Using Machine Learning
Tim Matthies, Alexander F. Schäffer, Thore Posske, Roland Wiesendanger, and Elena Y. Vedmedenko
Phys. Rev. Applied 17, 054022 (2022) – Published 13 May 2022

Characterizing magnetic textures is important for applications in stochastic computing and memory devices based on magnetic skyrmions. Knowing the exact number of skyrmions is essential for these tasks, yet this count is particularly difficult to determine when dealing with quickly moving skyrmions at nonzero temperatures, where only time-averaged, smeared results are available. The present study uses machine-learning techniques to solve this problem successfully, to the benefit of future investigations in spintronic computation and memory applications.

Show Abstract 
Computational Physics
Magnetism
Spintronics
PDFHTML
Editors' Suggestion
Computational Verification and Experimental Validation of the Vibration-Attenuation Properties of a Geometrically Nonlinear Metamaterial Design
Kyriakos Alexandros Chondrogiannis, Andrea Colombi, Vasilis Dertimanis, and Eleni Chatzi
Phys. Rev. Applied 17, 054023 (2022) – Published 13 May 2022

Metamaterials continue to be conceptually intriguing for the manipulation of propagating waves. However, preventing low-frequency wave propagation proves to be challenging, due to limited metamaterial dimensions and mass. This study focuses on a metamaterial lattice featuring geometrically nonlinear behavior that can lead to negative stiffness, aimed at overcoming the requirement of large mass for low-frequency vibration attenuation. This approach can find application in structural engineering to protect against low-frequency excitations—such as earthquakes.

Show Abstract 
Acoustics
Geophysics
Metamaterials
PDFHTML
High-Order Pulse-Echo Ultrasound
Urs A.T. Hofmann, Sergio Pérez-López, Héctor Estrada, and Daniel Razansky
Phys. Rev. Applied 17, 054024 (2022) – Published 16 May 2022
Show Abstract 
Acoustics
Industrial Physics
Medical Physics
PDFHTML
Acoustic Beam Splitting and Cloaking Based on a Compressibility-Near-Zero Medium
Changqing Xu, Sibo Huang, Zhiwei Guo, Haitao Jiang, Yong Li, Ying Wu, and Hong Chen
Phys. Rev. Applied 17, 054025 (2022) – Published 16 May 2022
Show Abstract 
Acoustics
Metamaterials
PDFHTML
Editors' Suggestion
Viscosity-Limited Drift Instabilities in Two-Dimensional Electron Systems
Aleksandr S. Petrov and Dmitry Svintsov
Phys. Rev. Applied 17, 054026 (2022) – Published 16 May 2022

Terahertz technology suffers from a lack of efficient emitters, but dc excitation of plasma waves in two-dimensional electron systems (2DESs) is a promising solution. Ultrahigh-mobility 2DESs would help to avoid the Ohmic losses that have plagued the implementation of such devices, but reduced Ohmic loss comes at the cost of damping via viscous loss. The authors exploit a recently developed perturbative technique to develop a systematic treatment of viscosity-induced plasmon damping, and provide a powerful tool for optimizing plasmonic resonators.

Show Abstract 
Condensed Matter Physics
Optoelectronics
Plasmonics
PDFHTML
Editors' Suggestion
Quasi-Fermi-Level Phase Space and its Applications in Ambipolar Two-Dimensional Field-Effect Transistors
Zhao-Yi Yan, Kan-Hao Xue, Zhan Hou, Yang Shen, He Tian, Yi Yang, and Tian-Ling Ren
Phys. Rev. Applied 17, 054027 (2022) – Published 17 May 2022

Quasi-Fermi levels (QFLs) have become a canonical concept in semiconductor device modeling. However, a global model to cover both unipolar and ambipolar transport modes of two-dimensional field-effect transistors (2D FETs) based on QFLs is still needed, as it is challenging to capture quantitatively the effect of QFL splitting on transport. This work establishes a theoretical platform to account for that effect: the quasi-Fermi-level phase space (QFLPS). With QFLPS a unified picture of unipolar and ambipolar transport is drawn, the working modes of 2D FETs acquire more intuitive physical interpretations, and many valuable outcomes for device modeling and circuit design are realized.

Show Abstract 
Electronics
Semiconductor Physics
PDFHTML
Interdash Coupling within Dense Ensembles of Quantum Dashes: Comparison of 
In
As
/(
In
,
Al
,
Ga
)
As
/
In
P
 and 
In
As
/(
In
,
Al
)
As
/
In
P
 Systems
P. Holewa, M. Gawełczyk, A. Maryński, K. Ryczko, V. Liverini, M. Beck, J. Faist, G. Sęk, and M. Syperek
Phys. Rev. Applied 17, 054028 (2022) – Published 17 May 2022
Show Abstract 
Nanophysics
Optoelectronics
Semiconductor Physics
PDFHTML
Quantifying Power in Silicon Photonic Neural Networks
Alexander N. Tait
Phys. Rev. Applied 17, 054029 (2022) – Published 18 May 2022
Show Abstract 
Computational Physics
Optoelectronics
Photonics
PDFHTML
Far-Field Acoustic Subwavelength Imaging with Blind Structured Illumination and Joint-Sparsity Reconstruction
Jinuan Lin and Chu Ma
Phys. Rev. Applied 17, 054030 (2022) – Published 18 May 2022
Show Abstract 
Acoustics
PDFHTML
Laser Frequency-Offset Locking at 10-Hz-Level Instability Using Hybrid Electronic Filters
Vyacheslav Li, Fritz Diorico, and Onur Hosten
Phys. Rev. Applied 17, 054031 (2022) – Published 19 May 2022
Show Abstract 
Atomic and Molecular Physics
Optics
Optoelectronics
PDFHTML
Reduced Hysteresis and Enhanced Giant Magnetocaloric Effect in B-Doped all-d-Metal 
Ni
-
Co
-
Mn
-
Ti
-Based Heusler Materials
Fengqi Zhang, Ivan Batashev, Niels van Dijk, and Ekkes Bruck
Phys. Rev. Applied 17, 054032 (2022) – Published 19 May 2022
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Energy Research
Magnetism
Materials Science
PDFHTML
Breakdown of the Weak-Coupling Limit in Quantum Annealing
Yuki Bando, Ka-Wa Yip, Huo Chen, Daniel A. Lidar, and Hidetoshi Nishimori
Phys. Rev. Applied 17, 054033 (2022) – Published 20 May 2022
Show Abstract 
Quantum Information
PDFHTML
Determining the Thickness of the Dead Layer in Superconducting Film Using a Two-Coil Mutual-Inductance Technique
Ruozhou Zhang, Zhanyi Zhao, Mingyang Qin, Juan Xu, Wenxin Cheng, Yangmu Li, Qihong Chen, Jie Yuan, and Kui Jin
Phys. Rev. Applied 17, 054034 (2022) – Published 20 May 2022
Show Abstract 
Magnetism
Superconductivity
PDFHTML
Stability of Quantized Conductance Levels in Memristors with Copper Filaments: Toward Understanding the Mechanisms of Resistive Switching
Oleg G. Kharlanov, Boris S. Shvetsov, Vladimir V. Rylkov, and Anton A. Minnekhanov
Phys. Rev. Applied 17, 054035 (2022) – Published 23 May 2022
Show Abstract 
Condensed Matter Physics
Electronics
Nanophysics
PDFHTML
Large Antisymmetric Interlayer Exchange Coupling Enabling Perpendicular Magnetization Switching by an In-Plane Magnetic Field
Hiroto Masuda, Takeshi Seki, Yuta Yamane, Rajkumar Modak, Ken-ichi Uchida, Jun'ichi Ieda, Yong-Chang Lau, Shunsuke Fukami, and Koki Takanashi
Phys. Rev. Applied 17, 054036 (2022) – Published 23 May 2022
Show Abstract 
Magnetism
Materials Science
Spintronics
PDFHTML
Neural Networks Based on Ultrafast Time-Delayed Effects in Exciton Polaritons
R. Mirek, A. Opala, M. Furman, M. Król, K. Tyszka, B. Seredyński, W. Pacuski, J. Suffczyński, J. Szczytko, M. Matuszewski, and B. Piętka
Phys. Rev. Applied 17, 054037 (2022) – Published 23 May 2022
Show Abstract 
Computational Physics
Optoelectronics
Semiconductor Physics
PDFHTML
Universal Deterministic Quantum Operations in Microwave Quantum Links
Guillermo F. Peñas, Ricardo Puebla, Tomás Ramos, Peter Rabl, and Juan José García-Ripoll
Phys. Rev. Applied 17, 054038 (2022) – Published 24 May 2022
Show Abstract 
Photonics
Quantum Information
Superconductivity
PDFHTML
Spatiotemporal Analysis of Electromagnetic Field Coherence in Complex Media
Thomas Fromenteze, Matthieu Davy, Okan Yurduseven, Yann Marie-Joseph, and Cyril Decroze
Phys. Rev. Applied 17, 054039 (2022) – Published 24 May 2022
Show Abstract 
Materials Science
Optics
PDFHTML
Modeling of the Thermodiffusion-Induced Filament Formation in 
Ti
N
/
Ta
x
O
1
−
x
/
Ti
N
 Resistive-Switching Devices
Jingjia Meng, Enkui Lian, Jonathan D. Poplawsky, and Marek Skowronski
Phys. Rev. Applied 17, 054040 (2022) – Published 24 May 2022
Show Abstract 
Electronics
Nanophysics
Semiconductor Physics
PDFHTML
Unveiling Temperature-Dependence Mechanisms of Perpendicular Magnetic Anisotropy at 
Fe
/
Mg
O
 Interfaces
Fatima Ibrahim, Ali Hallal, Alan Kalitsov, Derek Stewart, Bernard Dieny, and Mairbek Chshiev
Phys. Rev. Applied 17, 054041 (2022) – Published 25 May 2022
Show Abstract 
Magnetism
Materials Science
Spintronics
PDFHTML
Bidirectional Deep Learning of Polarization Transfer in Liquid Crystals with Application to Quantum State Preparation
Dominik Vašinka, Martin Bielak, Michal Neset, and Miroslav Ježek
Phys. Rev. Applied 17, 054042 (2022) – Published 25 May 2022
Show Abstract 
Photonics
Quantum Physics
PDFHTML
Spontaneous Frequency Shift and Phase Delay of Coupled Terahertz Radiation Mediated by the Josephson Plasmon in a Cuprate Superconductor
Ryota Kobayashi, Ken Hayama, Shuma Fujita, Manabu Tsujimoto, and Itsuhiro Kakeya
Phys. Rev. Applied 17, 054043 (2022) – Published 25 May 2022
Show Abstract 
Optoelectronics
Superconductivity
PDFHTML
Editors' Suggestion
Topological Field-Effect Transistor Based on Quasi-Two-Dimensional Tellurium Flakes
Bin Cheng, Lin Li, Nan Zhang, Ling Zhang, Xianglin Li, Zhiyong Lin, Hui Li, Zhengfei Wang, and Changgan Zeng
Phys. Rev. Applied 17, 054044 (2022) – Published 26 May 2022

The emergent topological semimetals have received considerable attention for developing innovative devices, mainly due to their novel topological electronic properties with high robustness against external perturbations. Progress has been hindered, though, due to a lack of tunability. Here the authors address this challenge by constructing a field-effect device based on thin flakes of tellurium, a semiconductor with a chiral Weyl node. In this device, the conducting and topological states can be simultaneously switched electrostatically, yielding giant modulations of both channel conductivity and chiral-anomaly-induced magnetoresistance.

Show Abstract 
Electronics
Semiconductor Physics
Topological Insulators
PDFHTML
Quantum Confinement and Dielectric Deconfinement in Quasi-Two-Dimensional Perovskites: Their Roles in Light-Emitting Diodes
Raja Chakraborty, Goutam Paul, and Amlan J. Pal
Phys. Rev. Applied 17, 054045 (2022) – Published 27 May 2022
Show Abstract 
Energy Research
Optoelectronics
Semiconductor Physics
PDFHTML
Deep Learning of Multiresolution X-Ray Micro-Computed-Tomography Images for Multiscale Modeling
Samuel J. Jackson, Yufu Niu, Sojwal Manoorkar, Peyman Mostaghimi, and Ryan T. Armstrong
Phys. Rev. Applied 17, 054046 (2022) – Published 27 May 2022
Show Abstract