Physical Review Applied - February 2024

Physical Review Applied View Email Online   Volume 21, Issue 2 February 2024   View Issue   Advertisement Congratulations to the 2024 Outstanding Referees In this year, 2024, 156 Outstanding Referees were selected from the 91,600 currently active referees. The honorees come from over 42 different countries and will be recognized at the upcoming March Meeting. Read more.     Advertisement Physical Review Applied seeks a new Lead Editor The American Physical Society is conducting an international search for a new Lead Editor of Physical Review Applied, our premier journal for Applied Physics Research. The Lead Editor is the lead scientific advisor to the journal and chairs the Editorial Board. They provide community oversight of the journal's content and direction, strategically advising the journal's Chief Editor in a consultative capacity. The role is key in helping to shape the journal's long-term goals, and growing and elevating the journal within the community. 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Join today to start connecting with a community of more than 50,000 physicists.   HIGHLIGHTED ARTICLES Editors' Suggestion Three-wave-mixing quantum-limited kinetic inductance parametric amplifier operating at 6 T near 1 K S. Frasca, C. Roy, G. Beaulieu, and P. Scarlino Phys. Rev. Applied 21, 024011 (2024) – Published 6 February 2024 Parametric amplifiers are essential in modern quantum technology, for enhancing weak signals with the minimal added noise of half a photon, and for working at higher temperatures and magnetic fields than Josephson junctions can handle. The authors present a kinetic inductance parametric amplifier (KIPA) that excels in dynamic range, operational temperature, and magnetic field resilience, and offers quantum-limited amplification. This KIPA's robust performance and compatibility promise transformative impacts on quantum information processing and low-temperature quantum research.     Editors' Suggestion Quantum light-field microscopy for volumetric imaging with extreme depth of field Yingwen Zhang, Duncan England, Antony Orth, Ebrahim Karimi, and Benjamin Sussman Phys. Rev. Applied 21, 024029 (2024) – Published 14 February 2024 Light-field microscopy (LFM) extracts volumetric data from a specimen by simultaneously capturing the positional and angular information of light rays emanating from the sample. While conventional LFM requires a compromise between depth of field (DOF) and resolution, this work introduces a quantum approach to eliminate this compromise by harnessing position-momentum entanglement of photon pairs. Compared to conventional LFM at the same resolution, the quantum approach can yield up to tenfold improvement in DOF. This work illustrates the power of utilizing multidimensional entanglement in microscopy and hopefully will inspire further innovations in the field.     Editors' Suggestion Nonreciprocal spin-wave transport in an asymmetric three-dimensional magnonic coupler A.A. Grachev, S.A. Odintsov, E.N. Beginin, and A.V. Sadovnikov Phys. Rev. Applied 21, 024031 (2024) – Published 15 February 2024 The use of elementary quanta of magnetic excitation—magnons, or spin waves—as carriers of information attracts more and more interest, as transferring the magnetic moment (spin) of an electron without transferring its electric charge avoids the heat generation inherent in CMOS technology. This study aims to exploit directed spin-wave propagation in a structure composed of parallel stripes of thin-film yttrium iron garnet, forming an asymmetric three-dimensional coupler geometry. This approach has the potential to enhance the density of functional elements in three-dimensional magnonic networks.     Editors' Suggestion Quantitative measurement of figure of merit for transverse thermoelectric conversion in Fe/Pt metallic multilayers Takumi Yamazaki, Takamasa Hirai, Takashi Yagi, Yuichiro Yamashita, Ken-ichi Uchida, Takeshi Seki, and Koki Takanashi Phys. Rev. Applied 21, 024039 (2024) – Published 21 February 2024 Metallic multilayers play a pivotal role in spintronics and also have recently attracted attention as spin-caloritronic materials for energy conversion, but their thermoelectric performance has not been quantified. This study of Fe/Pt multilayers presents a method to evaluate the figure of merit for transverse thermoelectric conversion in thin-film stacks. A multilayered structure reduces thermal conductivity and notably enhances the figure of merit. Interestingly, epitaxial multilayers exhibit better thermoelectric performance than their polycrystalline counterparts, due to their higher transverse thermoelectric coefficient and electron-transport anisotropy.     Editors' Suggestion Fast and reliable entanglement distribution with quantum repeaters: Principles for improving protocols using reinforcement learning Stav Haldar, Pratik J. Barge, Sumeet Khatri, and Hwang Lee Phys. Rev. Applied 21, 024041 (2024) – Published 21 February 2024 Tomorrow's quantum technologies for communication, sensing, and distributed computing will rely on networks with entanglement shared between spatially separated nodes. The authors provide improved protocols and policies for entanglement distribution along a chain of nodes, accounting for practical limitations such as photon losses, nonideal measurements, and quantum memories with short coherence times. These policies feature dynamic, state-dependent memory cutoffs and collaboration between nodes, all of which are quantified. Nesting policies for small repeater chains yields policies for large chains that improve upon a swap-as-soon-as-possible approach, and thus pave the way to scaling up.     LETTERS Letter Metamaterial route to light-induced generation of a subwavelength static magnetic field Shiqiang Zhao, Yongzheng Wen, Chen Wang, Jingbo Sun, and Ji Zhou Phys. Rev. Applied 21, L021001 (2024) – Published 14 February 2024 For applications in magnetism and spintronics, generating a static magnetic field using light would significantly boost speed and storage density of information. Unfortunately, despite decades of development there are still limitations at the frontiers of photonics and magnetism, such as spatial confinement and degrees of manipulation freedom. Researchers now demonstrate that these drawbacks can be overcome by harnessing metamaterials to generate a static driving force under pumping light. This force compels the electrons to move unidirectionally and induce a static magnetic field, at a scale of 1/1000 of the operating wavelength, with ultrafast time response.     ARTICLES Four-terminal graphene-superconductor thermal switch controlled by the superconducting phase difference Peng-Yi Liu, Yue Mao, and Qing-Feng Sun Phys. Rev. Applied 21, 024001 (2024) – Published 1 February 2024   Elastic bound modes in the continuum in architected beams Adib Rahman and Raj Kumar Pal Phys. Rev. Applied 21, 024002 (2024) – Published 1 February 2024   Integrated pulsed optically pumped Rb atomic clock with frequency stability of 10−15 Qiang Hao, Shaojie Yang, Jun Ruan, Peter Yun, and Shougang Zhang Phys. Rev. Applied 21, 024003 (2024) – Published 1 February 2024   Enhancement of thermionic power generation via engineered microstructures Chace Franey, Bakir M. Al-Ameri, Greg I. Acosta, and Mohammad Ghashami Phys. Rev. Applied 21, 024004 (2024) – Published 1 February 2024   Stability of ternary interfaces and its effects on ideal switching characteristics in inverted coplanar organic transistors Keito Murata, Gyo Kitahara, Satoru Inoue, Toshiki Higashino, Satoshi Matsuoka, Shunto Arai, Reiji Kumai, and Tatsuo Hasegawa Phys. Rev. Applied 21, 024005 (2024) – Published 2 February 2024   Measuring the anisotropic conductivity of rub-aligned doped semiconducting polymer films: The role of electrode geometry Quynh M. Duong, Diego Garcia Vidales, Charlene Z. Salamat, Sarah H. Tolbert, and Benjamin J. Schwartz Phys. Rev. Applied 21, 024006 (2024) – Published 2 February 2024   Equivalent-circuit model that quantitatively describes domain-wall conductivity in ferroelectric LiNbO3 Manuel Zahn, Elke Beyreuther, Iuliia Kiseleva, Ahmed Samir Lotfy, Conor J. McCluskey, Jesi R. Maguire, Ahmet Suna, Michael Rüsing, J. Marty Gregg, and Lukas M. Eng Phys. Rev. Applied 21, 024007 (2024) – Published 5 February 2024   Fast high-fidelity quantum nondemolition readout of a superconducting qubit with tunable transverse couplings Bryan T. Gard, Zachary Parrott, Kurt Jacobs, José Aumentado, and Raymond W. Simmonds Phys. Rev. Applied 21, 024008 (2024) – Published 5 February 2024   Fully analytical design of electromagnetic transmissive metagratings for highly efficient extreme-angle beam refraction and reflection Zhen Tan, Jianjia Yi, Badreddine Ratni, and Shah Nawaz Burokur Phys. Rev. Applied 21, 024009 (2024) – Published 5 February 2024   Control of the magnetic anisotropy in multirepeat Pt/Co/Al heterostructures using magnetoionic gating Tristan da Câmara Santa Clara Gomes, Tanvi Bhatnagar-Schöffmann, Sachin Krishnia, Yanis Sassi, Dedalo Sanz-Hernández, Nicolas Reyren, Marie-Blandine Martin, Frederic Brunnett, Sophie Collin, Florian Godel, Shimpei Ono, Damien Querlioz, Dafiné Ravelosona, Vincent Cros, Julie Grollier, Pierre Seneor, and Liza Herrera Diez Phys. Rev. Applied 21, 024010 (2024) – Published 6 February 2024   Editors' Suggestion Three-wave-mixing quantum-limited kinetic inductance parametric amplifier operating at 6 T near 1 K S. Frasca, C. Roy, G. Beaulieu, and P. Scarlino Phys. Rev. Applied 21, 024011 (2024) – Published 6 February 2024 Parametric amplifiers are essential in modern quantum technology, for enhancing weak signals with the minimal added noise of half a photon, and for working at higher temperatures and magnetic fields than Josephson junctions can handle. The authors present a kinetic inductance parametric amplifier (KIPA) that excels in dynamic range, operational temperature, and magnetic field resilience, and offers quantum-limited amplification. This KIPA's robust performance and compatibility promise transformative impacts on quantum information processing and low-temperature quantum research.     Efficient quantum digital signatures over long distances with likely bit strings Ji-Qian Qin, Zong-Wen Yu, and Xiang-Bin Wang Phys. Rev. Applied 21, 024012 (2024) – Published 6 February 2024   Fiber-type optomechanical array using high-Q microbottle resonators Motoki Asano, Hiroshi Yamaguchi, and Hajime Okamoto Phys. Rev. Applied 21, 024013 (2024) – Published 7 February 2024   Bidirectionally injection-locked coupled microring GaN lasers Shinji Tohi, Gal Harari, Takumi Ito, Yaakov Lumer, Miguel A. Bandres, Kunimichi Omae, and Mordechai Segev Phys. Rev. Applied 21, 024014 (2024) – Published 7 February 2024   Fluxonium qubits in a flip-chip package Aaron Somoroff, Patrick Truitt, Adam Weis, Jacob Bernhardt, Daniel Yohannes, Jason Walter, Konstantin Kalashnikov, Mario Renzullo, Raymond A. Mencia, Maxim G. Vavilov, Vladimir E. Manucharyan, Igor V. Vernik, and Oleg A. Mukhanov Phys. Rev. Applied 21, 024015 (2024) – Published 7 February 2024   Scalable protocol to mitigate ZZ crosstalk in universal quantum gates Yan Liang, Ming-Jie Liang, Sai Li, Z. D. Wang, and Zheng-Yuan Xue Phys. Rev. Applied 21, 024016 (2024) – Published 8 February 2024   State-independent robust heat-bath algorithmic cooling of nuclear spins Krishna Shende, Arvind, and Kavita Dorai Phys. Rev. Applied 21, 024017 (2024) – Published 8 February 2024   Characterizing non-Markovian off-resonant errors in quantum gates Ken Xuan Wei, Emily Pritchett, David M. Zajac, David C. McKay, and Seth Merkel Phys. Rev. Applied 21, 024018 (2024) – Published 8 February 2024   Control of quantum coherence of photons exploiting quantum entanglement Dianzhen Cui, Xi-Lin Wang, X.X. Yi, and Li-Ping Yang Phys. Rev. Applied 21, 024019 (2024) – Published 9 February 2024   Maximization of rf-signal recovery in quantum microwave photonics systems Yaqing Jin, Xinghua Li, Ye Yang, Ruifang Dong, Xiao Xiang, Runai Quan, Huibo Hong, Tao Liu, Mingtao Cao, Baihong Li, Xiaofei Zhang, Ming Li, and Shougang Zhang Phys. Rev. Applied 21, 024020 (2024) – Published 9 February 2024   Substrate-induced spin-torque-like signal in spin-torque ferromagnetic resonance measurement Dingsong Jiang, Hetian Chen, Guiping Ji, Yahong Chai, Chenye Zhang, Yuhan Liang, Jingchun Liu, Witold Skowroński, Pu Yu, Di Yi, and Tianxiang Nan Phys. Rev. Applied 21, 024021 (2024) – Published 9 February 2024   Stabilizing two-qubit entanglement with dynamically decoupled active feedback Sacha Greenfield, Leigh Martin, Felix Motzoi, K. Birgitta Whaley, Justin Dressel, and Eli M. Levenson-Falk Phys. Rev. Applied 21, 024022 (2024) – Published 12 February 2024   High-resolution coincidence counting system for large-scale photonics applications Josef Hloušek, Jan Grygar, Michal Dudka, and Miroslav Ježek Phys. Rev. Applied 21, 024023 (2024) – Published 12 February 2024   Dynamic evolution of S0–S3 at the oxygen-evolving complex with spin markers under photoelectric polarization Pei-Ying Huo, Wei-Zhou Jiang, Rong-Yao Yang, and Xiu-Rong Zhang Phys. Rev. Applied 21, 024024 (2024) – Published 12 February 2024   Topologically controlled multiskyrmions in photonic gradient-index lenses Yijie Shen, Chao He, Zipei Song, Binguo Chen, Honghui He, Yifei Ma, Julian A.J. Fells, Steve J. Elston, Stephen M. Morris, Martin J. Booth, and Andrew Forbes Phys. Rev. Applied 21, 024025 (2024) – Published 13 February 2024   Real-time adaptive estimation of decoherence timescales for a single qubit Muhammad Junaid Arshad, Christiaan Bekker, Ben Haylock, Krzysztof Skrzypczak, Daniel White, Benjamin Griffiths, Joe Gore, Gavin W. Morley, Patrick Salter, Jason Smith, Inbar Zohar, Amit Finkler, Yoann Altmann, Erik M. Gauger, and Cristian Bonato Phys. Rev. Applied 21, 024026 (2024) – Published 13 February 2024   Statistical approach based on the Stoner-Wohlfarth model for the switching field in a misoriented magnet array Donghyeon Lee, Jungmin Park, Donghyeon Han, Suzuki Ippei, Takahashi Yukiko, Sujung Noh, Jisung Lee, JoonHyun Kwon, Hansaem Lee, and Sanghoon Kim Phys. Rev. Applied 21, 024027 (2024) – Published 13 February 2024   High-Q Mie resonators for refractive-index sensing Esmaeel Zanganeh, Zarina Sadrieva, Polina Kapitanova, and Andrey Bogdanov Phys. Rev. Applied 21, 024028 (2024) – Published 14 February 2024   Editors' Suggestion Quantum light-field microscopy for volumetric imaging with extreme depth of field Yingwen Zhang, Duncan England, Antony Orth, Ebrahim Karimi, and Benjamin Sussman Phys. Rev. Applied 21, 024029 (2024) – Published 14 February 2024 Light-field microscopy (LFM) extracts volumetric data from a specimen by simultaneously capturing the positional and angular information of light rays emanating from the sample. While conventional LFM requires a compromise between depth of field (DOF) and resolution, this work introduces a quantum approach to eliminate this compromise by harnessing position-momentum entanglement of photon pairs. Compared to conventional LFM at the same resolution, the quantum approach can yield up to tenfold improvement in DOF. This work illustrates the power of utilizing multidimensional entanglement in microscopy and hopefully will inspire further innovations in the field.     Theory of superconducting qubits beyond the lumped-element approximation Ari Mizel Phys. Rev. Applied 21, 024030 (2024) – Published 15 February 2024   Editors' Suggestion Nonreciprocal spin-wave transport in an asymmetric three-dimensional magnonic coupler A.A. Grachev, S.A. Odintsov, E.N. Beginin, and A.V. Sadovnikov Phys. Rev. Applied 21, 024031 (2024) – Published 15 February 2024 The use of elementary quanta of magnetic excitation—magnons, or spin waves—as carriers of information attracts more and more interest, as transferring the magnetic moment (spin) of an electron without transferring its electric charge avoids the heat generation inherent in CMOS technology. This study aims to exploit directed spin-wave propagation in a structure composed of parallel stripes of thin-film yttrium iron garnet, forming an asymmetric three-dimensional coupler geometry. This approach has the potential to enhance the density of functional elements in three-dimensional magnonic networks.     Light-field ghost imaging A. Paniate, G. Massaro, A. Avella, A. Meda, F.V. Pepe, M. Genovese, M. D'Angelo, and I. Ruo-Berchera Phys. Rev. Applied 21, 024032 (2024) – Published 15 February 2024   Cascaded degenerate four-wave mixing generation in thin-film lithium tantalate microdisk cavity Xiongshuo Yan, Miao Xue, Tingge Yuan, Jiangwei Wu, Rui Ge, Yuping Chen, and Xianfeng Chen Phys. Rev. Applied 21, 024033 (2024) – Published 16 February 2024   On-demand single-electron source via single-cycle acoustic pulses Shunsuke Ota, Junliang Wang, Hermann Edlbauer, Yuma Okazaki, Shuji Nakamura, Takehiko Oe, Arne Ludwig, Andreas D. Wieck, Hermann Sellier, Christopher Bäuerle, Nobu-Hisa Kaneko, Tetsuo Kodera, and Shintaro Takada Phys. Rev. Applied 21, 024034 (2024) – Published 16 February 2024   Floquet analysis of frequency collisions Kentaro Heya, Moein Malekakhlagh, Seth Merkel, Naoki Kanazawa, and Emily Pritchett Phys. Rev. Applied 21, 024035 (2024) – Published 16 February 2024   Optoelectronic and transport properties of vacancy-ordered double-perovskite halides: A first-principles study Supriti Ghorui, Jiban Kangsabanik, M. Aslam, and Aftab Alam Phys. Rev. Applied 21, 024036 (2024) – Published 20 February 2024   Exceptional-point degeneracy as a desirable operation point for an oscillator array with discrete nonlinear gain and radiative elements Alireza Nikzamir and Filippo Capolino Phys. Rev. Applied 21, 024037 (2024) – Published 20 February 2024   Doped VS2 as a high-performance electrode material for rechargeable Mg-ion batteries Yingfang Li, Kunlun Wu, Haoran Luo, Meng Li, Lei Wang, Kuan Sun, and Yujie Zheng Phys. Rev. Applied 21, 024038 (2024) – Published 20 February 2024   Editors' Suggestion Quantitative measurement of figure of merit for transverse thermoelectric conversion in Fe/Pt metallic multilayers Takumi Yamazaki, Takamasa Hirai, Takashi Yagi, Yuichiro Yamashita, Ken-ichi Uchida, Takeshi Seki, and Koki Takanashi Phys. Rev. Applied 21, 024039 (2024) – Published 21 February 2024 Metallic multilayers play a pivotal role in spintronics and also have recently attracted attention as spin-caloritronic materials for energy conversion, but their thermoelectric performance has not been quantified. This study of Fe/Pt multilayers presents a method to evaluate the figure of merit for transverse thermoelectric conversion in thin-film stacks. A multilayered structure reduces thermal conductivity and notably enhances the figure of merit. Interestingly, epitaxial multilayers exhibit better thermoelectric performance than their polycrystalline counterparts, due to their higher transverse thermoelectric coefficient and electron-transport anisotropy.     Phase-controlled improvement of photon lifetime in coupled superconducting cavities Changqing Wang, Oleksandr S. Melnychuk, Crispin Contreras-Martinez, Yao Lu, Yuriy M. Pischalnikov, Oleg Pronitchev, Bianca Giaccone, Roman Pilipenko, Silvia Zorzetti, Sam Posen, Alexander Romanenko, and Anna Grassellino Phys. Rev. Applied 21, 024040 (2024) – Published 21 February 2024   Editors' Suggestion Fast and reliable entanglement distribution with quantum repeaters: Principles for improving protocols using reinforcement learning Stav Haldar, Pratik J. Barge, Sumeet Khatri, and Hwang Lee Phys. Rev. Applied 21, 024041 (2024) – Published 21 February 2024 Tomorrow's quantum technologies for communication, sensing, and distributed computing will rely on networks with entanglement shared between spatially separated nodes. The authors provide improved protocols and policies for entanglement distribution along a chain of nodes, accounting for practical limitations such as photon losses, nonideal measurements, and quantum memories with short coherence times. These policies feature dynamic, state-dependent memory cutoffs and collaboration between nodes, all of which are quantified. Nesting policies for small repeater chains yields policies for large chains that improve upon a swap-as-soon-as-possible approach, and thus pave the way to scaling up.     Determining the lifetime of the 5s5p3P0o metastable state in 87Sr from the electric dipole matrix element Xiao-Tong Lu, Feng Guo, Yan-Yan Liu, Jing-Jing Xia, Guo-Dong Zhao, Ying-Xin Chen, Ye-Bing Wang, Ben-Quan Lu, and Hong Chang Phys. Rev. Applied 21, 024042 (2024) – Published 22 February 2024   Effects of four-phonon interaction and vacancy defects on the thermal conductivity of the low-temperature phase of SnSe Pan Zhang, Dan Jin, Mi Qin, Zhenhua Zhang, Yong Liu, Ziyu Wang, Zhihong Lu, Rui Xiong, and Jing Shi Phys. Rev. Applied 21, 024043 (2024) – Published 22 February 2024   Interface-induced Berry-curvature dipole and second-order nonlinear Hall effect in two-dimensional Fe5GeTe2 Jinrui Zhong, Huimin Peng, Xiaocui Wang, Qi Feng, Yuqing Hu, Qiuli Li, Yongkai Li, Wei Jiang, Zhiwei Wang, and Junxi Duan Phys. Rev. Applied 21, 024044 (2024) – Published 22 February 2024   Bistable polymer-stabilized cholesteric-liquid-crystal window based on flexoelectric and dielectric effects Ziyuan Zhou, Xinfang Zhang, Suman Halder, Lang Hu, and Deng-Ke Yang Phys. Rev. Applied 21, 024045 (2024) – Published 23 February 2024   Thermal-property optimization dominated by the stoichiometric ratio in W-Si superconducting single-photon detectors Zhi Qin, Han Bao, Tao Xu, Shi Chen, Shuchao Yang, Haojie Li, Zhihe Wang, Xuecou Tu, Labao Zhang, Qingyuan Zhao, Xiaoqing Jia, Guanghao Zhu, Lin Kang, Jian Chen, and Peiheng Wu Phys. Rev. Applied 21, 024046 (2024) – Published 23 February 2024   Improved coherence in optically defined niobium trilayer-junction qubits Alexander Anferov, Kan-Heng Lee, Fang Zhao, Jonathan Simon, and David I. Schuster Phys. Rev. Applied 21, 024047 (2024) – Published 23 February 2024   Assessing trajectory-dependent electronic energy loss of keV ions by a binary collision approximation code R. Holeňák, E. Ntemou, S. Lohmann, M. Linnarsson, and D. Primetzhofer Phys. Rev. Applied 21, 024048 (2024) – Published 26 February 2024   Control of multimodal topological edge modes in magnetoelastic lattices Taehwa Lee, Bertin Many Manda, Xiaopeng Li, Ziqi Yu, Georgios Theocharis, and Chiara Daraio Phys. Rev. Applied 21, 024049 (2024) – Published 26 February 2024   Magnetization-switching dynamics driven by chiral coupling B.B. Vermeulen, M. Gama Monteiro, D. Giuliano, B. Sorée, S. Couet, K. Temst, and V.D. Nguyen Phys. Rev. Applied 21, 024050 (2024) – Published 26 February 2024   Niobium quantum interference microwave circuits with monolithic three-dimensional nanobridge junctions Kevin Uhl, Daniel Hackenbeck, Janis Peter, Reinhold Kleiner, Dieter Koelle, and Daniel Bothner Phys. Rev. Applied 21, 024051 (2024) – Published 27 February 2024   Impact of random alloy fluctuations on the carrier distribution in multicolor (In,Ga)N/GaN quantum well systems Michael O'Donovan, Patricio Farrell, Julien Moatti, Timo Streckenbach, Thomas Koprucki, and Stefan Schulz Phys. Rev. Applied 21, 024052 (2024) – Published 27 February 2024   Hybrid diamond quantum sensor with submicrokelvin resolution under ambient conditions Musang Gong, Jiahe Xu, Min Yu, Liyin Zhang, Qipeng Li, Ning Wang, and Jianming Cai Phys. Rev. Applied 21, 024053 (2024) – Published 27 February 2024   Measurement of near-field thermal radiation between multilayered metamaterials Sen Zhang, Yongdi Dang, Xinran Li, Naeem Iqbal, Yi Jin, Pankaj K. Choudhury, Mauro Antezza, Jianbin Xu, and Yungui Ma Phys. Rev. Applied 21, 024054 (2024) – Published 28 February 2024   Far-field superresolution shape reconstruction of objects using level-set-based geometrical full-waveform inversion Xiao Yin and Fan Shi Phys. Rev. Applied 21, 024055 (2024) – Published 28 February 2024   Disentangling superconductor and dielectric microwave losses in submicrometer Nb/SiO2 interconnects using a multimode microstrip resonator Cougar A. T. Garcia, Nancyjane Bailey, Chris Kirby, Joshua A. Strong, Vladimir V. Talanov, Anna Yu. Herr, and Steven M. Anlage Phys. Rev. Applied 21, 024056 (2024) – Published 28 February 2024   Analog spin simulators: How to keep the amplitude homogeneous W. Verstraelen, P. Deuar, M. Matuszewski, and T.C.H. Liew Phys. Rev. Applied 21, 024057 (2024) – Published 29 February 2024   Kinemon: An inductively shunted transmon artificial atom Daria Kalacheva, Gleb Fedorov, Julia Zotova, Shamil Kadyrmetov, Alexey Kirkovskii, Aleksei Dmitriev, and Oleg Astafiev Phys. Rev. Applied 21, 024058 (2024) – Published 29 February 2024   Tunable compact on-chip superconducting switch Julia Zotova, Alexander Semenov, Rui Wang, Yu Zhou, Oleg Astafiev, and Jaw-Shen Tsai Phys. Rev. Applied 21, 024059 (2024) – Published 29 February 2024     American Physical Society: 1 Physics Ellipse, College Park, MD 20740 ©2024 American Physical Society | All rights reserved   You are receiving this email because you are subscribed to Table of Content alerts. If you no longer wish to receive these emails, please update your preferences.