Invited talks
I1: Advancing Quantum Metrology and Biotechnology
Paras N. Prasad
University at Buffalo
This talk will present our vision for advancing quantum metrology and biotechnology via accelerated discovery of enabling materials and architectures, including novel chiral quantum metasurfaces, topological photonic crystal waveguides, and quantum-defect-engineered two-dimensional (2D) materials. This will be achieved by tightly integrating Artificial Intelligence/Machine Learning (AI/ML)-powered framework with the state-of-the-art nanotechnology platform. The motivation for this ambitious plan is grounded in the fact that quantum metrology and sensing with non-classical states of light (entangled photon pairs, Fock states, or squeezed light) can surpass the fundamental quantum shot-noise limit, enabling ultrahigh sensitivity for biological, pharmaceutical, and environmental measurements. Integrated quantum lab-on-a-chip devices based on nanopatterning and defect engineering in 2D materials, particularly hBN and MBenes, can provide scalable platforms for magnetic, electric and thermal field mapping, as well as for enantio-selective detection/biosensing. To this point, we also propose to augment quantitative Raman spectrometry-based biochemical mapping of live cells via introducing a new direction of Quantum Ramanomics, which involves Stimulated Raman Spectroscopy (SRS) with squeezed light and provides considerable gain in sensitivity, chemical specificity and spatial resolution. This will reveal more details of molecular changes as a function of disease progression and thus will lead to molecular diagnostics at a single cell level, followed by advances in therapy. In our strategy, the AI/ML plays a major role as it has a well-documented capacity to accelerate materials discovery and pinpoint non-trivial correlations in large data sets.
I2: Spin-lattice coupling in layered antiferromagnets
Zhong Lin
Binghamton University
Layered antiferromagnetic semiconductors, such as transition‐metal thiophosphates, offer a versatile platform for investigating spin–lattice coupling and magneto‐optical phenomena in two dimensions. Using polarization‐resolved Raman spectroscopy, we examine how lattice vibrations respond to the emergence of magnetic order in these van der Waals materials. Below the Néel temperature, certain phonon modes display pronounced polarization anisotropy and helicity dependence, evidencing magnetically induced symmetry breaking in the absence of net magnetization. Angular polarization measurements further reveal significant phase shifts between optical helicities, providing a direct and resonant optical probe of spin–lattice correlations and magnetic symmetry in layered antiferromagnetic semiconductors.
I3: Physics and applications of Andreev spin qubits
Valla Fatemi
Cornell University
Superconducting qubits and semiconducting qubits are two leading solid-state platforms for quantum computation, each coming with distinct strengths and challenges. Hybrid structures made of both semiconductors and superconductors aim to combine the best features of both platforms. One such hybrid structure is the Andreev spin qubit, which hosts a microscopic, fermionic spin degree of freedom inside a Josephson weak link. The key feature is the spin-dependent supercurrent – this physics enables long-range, quantum coherent interactions between spins despite their microscopic size, offering new architectural opportunities based on this hybrid system.
In this talk, I will first present an introduction to Andreev spin qubits and what is unique in relation to both quantum dot spin qubits and superconducting qubits (see also [1] for related perspectives). I will then describe a new insight as to how we can use Kramers’ theorem to our advantage for designing error-correction modules [2], followed by our recent experiments developing the hardware to better understand coherence of Andreev spins hosted in InAs nanowires [3]. Finally, I will conclude with key future challenges and opportunities for this platform.
[1] A. M. Bozkurt and V. Fatemi, “Josephson tunnel junction arrays and Andreev weak links: what’s the difference?,” in Spintronics XVI, SPIE, Sep. 2023, pp. 35–43. doi: 10.1117/12.2678477.
[2] H. Lu, I. A. Day, A. R. Akhmerov, B. van Heck, and V. Fatemi, “Kramers-protected hardware-efficient error correction with Andreev spin qubits,” Dec. 20, 2024, arXiv: arXiv:2412.16116. doi: 10.48550/arXiv.2412.16116.
[3] H. Lu et al., “Andreev spin relaxation time in a shadow-evaporated InAs weak link,” Jan. 20, 2025, arXiv: arXiv:2501.11627. doi: 10.48550/arXiv.2501.11627.
I4: Correlated Nanoelectronics and Programmable Quantum Matter: Platforms for the Second Quantum Revolution
Jeremy Levy
University of Pittsburgh
The second quantum revolution—our growing ability to manipulate quantum states for computation, simulation, and sensing—demands novel approaches to control quantum matter at nanoscale dimensions. In this talk, I will explore how our research at the intersection of correlated nanoelectronics, nanophotonics, and programmable quantum materials forms a unified approach to quantum technologies. Beginning with LaAlO3/SrTiO3 interfaces, I'll demonstrate how nanoscale reconfigurability enables the discovery of exotic quantum phases, including electron pairing outside the superconducting state and degenerate quantum liquids formed from bound states of multiple electrons. This reconfigurability extends to our emerging work with superconducting KTaO3, where we've recently demonstrated nanoscale SQUIDs with remarkable kinetic inductance and gate-tunable properties, and to silicon-based reprogrammable nanoelectronic devices. I'll then discuss how we've expanded this paradigm to van der Waals materials using ultra-low-voltage electron beam lithography to create arbitrary electrostatic patterns unbound by crystal symmetries, establishing a powerful analog quantum simulation platform akin to the quantum gas microscope for cold atoms. Throughout these material systems, we leverage nanophotonic capabilities, including rewritable photodetectors and selective difference frequency generation with over 100 THz bandwidth at nanojunctions, offering unprecedented spatial resolution for THz spectroscopy and optoelectronic functionality. These complementary approaches—spanning complex oxides, silicon, and van der Waals materials—share a common vision: creating quantum systems where electronic, magnetic, and optical properties can be programmed with nanoscale precision, enabling both fundamental insights into quantum matter and practical pathways toward quantum information technologies.
I5: Building compact qubits from van der Waals heterostructures
James C. Hone
Columbia University
This talk will review our efforts to use layered heterostructures of two-dimensional materials to create compact superconducting qubits. This work requires synthesis of ultra-pure crystals of transition metal dichalcogenides (TMDs). Using a two-step flux synthesis technique, with imaging by STM for defect quantification, we have reduced defect densities by roughly three orders of magnitude. For qubits, we combine superconducting NbSe2 with semiconducting WSe2 to create merged-element transmons (MET), where a single heterostructure acts as a Josephson junction and capacitor. We have studied the dc response of these Josephson junctions over a wide range in WSe2 thickness, which allows for predictive device design. We show that the resulting MET devices meet the design specifications for frequency and nonlinearity, and can achieve coherence. The measured coherence time matches that determined from independent microwave loss measurements.
Bio: James C. Hone is a Wang Fong-Jen Professor and Chair of Mechanical Engineering, Columbia University. A leading expert in two-dimensional materials and van der Waals heterostructures, he has developed methods for synthesizing and studying graphene, MoS₂, and related systems. Hone’s research integrates mechanical, electrical, and optical probes to uncover emergent nanoscale phenomena. His group has contributed extensively to advancing atomically thin materials for applications in quantum science, electronics, and photonics.
I6: Helping students become Leaders of the Second Quantum Revolution using Research-based tools and tips for Learning and Teaching
Chandralekha Singh
University of Pittsburgh
We are in the midst of the second quantum revolution. To help improve student understanding of quantum concepts, we have been conducting investigation of the difficulties that students have in learning quantum mechanics and using research as a guide to develop Quantum Interactive Learning Tutorials (QuILTs) as well as tools for peer-instruction. The goal of QuILTs and peer-instruction tools is to actively engage students in the learning process and to help them build links between the formalism and the conceptual aspects of quantum mechanics. The QuILTs are based upon research in physics education and employ active-learning strategies and adapt visualization tools, e.g., from Open-Source Physics, PhET and QuVis. These learning tools focus on helping students integrate qualitative and quantitative understanding without compromising technical content. This workshop is targeted at both instructors and students who would like to supplement their existing course material with research-based field-tested tools that provide scaffolding support to learn quantum mechanics and a high degree of interactivity. We will especially focus on learning tools that connect with the second quantum revolution concepts such as basics of quantum computing, Bloch sphere, quantum key distribution using entanglement as well as non-orthogonal polarization states of light that can be taught using simple two-level quantum systems. This work is supported by the National Science Foundation.
I7: Interface-Induced Superconductivity in Quantum Anomalous Hall Insulators
Cui-Zu Chang
Pennsylvania State University
When two different electronic materials are brought together, the resultant interface often shows unexpected quantum phenomena, including interfacial superconductivity and Fu-Kane topological superconductivity (TSC). In this talk, I will first briefly talk about our recent progress on the quantum anomalous Hall (QAH) effect in magnetic topological insulator (TI) multilayers. Next, I will focus on our recent discovery of interfacial superconductivity in QAH/iron chalcogenide heterostructures. We employed molecular beam epitaxy (MBE) to synthesize heterostructures formed by stacking together two magnetic materials, a ferromagnetic TI with the QAH state and an antiferromagnetic iron chalcogenide (FeTe). We discovered emergent interface-induced superconductivity in these heterostructures and demonstrated the trifecta occurrence of superconductivity, ferromagnetism, and topological band structure in the QAH layer, the three essential ingredients of chiral TSC. The unusual coexistence of ferromagnetism and superconductivity can be attributed to the high upper critical magnetic field that exceeds the Pauli paramagnetic limit for conventional superconductors at low temperatures. The QAH/FeTe heterostructures with robust superconductivity and atomically sharp interfaces provide an ideal wafer-scale platform for the exploration of chiral TSC and Majorana physics, constituting an important step toward scalable topological quantum computation.
I8: Josephson Junctions: Topology, Spintronics, Noise
Igor Žutić
University at Buffalo
Josephson junctions (JJs) are superconducting devices key to a wide range of applications, from quantum computing to exquisite precision sensing, as well as versatile platforms to study fundamental phenomena [1] and recently recognized by the Nobel Prize in Physics. By focusing on high-quality Al/InAs-based JJs we demonstrate topological superconductivity [2] which could host Majorana bound states with non-Abelian statistics for a fault-tolerant quantum computing [3]. While such Majorana states remain elusive, the same JJs supports spin-triplet superconductivity and superconducting diode effect, both important for superconducting spintronics [4]. By predicting novel mechanism to drive JJs by gate-controlled spin-orbit coupling, these JJs may offer an energy-efficient hardware for neuromorphic computing and artificial intelligence [5,6]. Unlike the common understanding that the Josephson effect requires two superconductors, our giant shot-noise measurements in ferromagnet/superconductor junctions suggest that only one superconductor is needed [7].
[1] F. Tafuri (ed.), Fundamentals and Frontiers of the Josephson Effect (Springer, 2019).
[2] M. C. Dartiailh, W. Mayer, J. Yuan, K. S. Wickramasinghe, A. Matos-Abiague, I. Žutić, and J. Shabani, Phys. Rev. Lett. 126, 036802 (2021).
[3] T. Zhou, M. C. Dartiailh, K. Sardashti, J. E. Han, A. Matos-Abiague, J. Shabani, and I.Žutić, Nat. Commun. 13, 1738 (2022).
[4] M. Amundsen, J. Linder, J. W. A. Robinson, I. Žutić, and N. Banerjee, Rev. Mod. Phys 96, 021003 (2024).
[5] D. Monroe, M. Alidoust, and I. Žutić, Phys. Rev. Applied 18, L031001 (2022)
[6] D. Monroe, C. Shen, D. Tringali, M. Alidoust, T. Zhou, and I. Žutić, Appl. Phys. Lett. 125, 012601 (2024).
[7] C. Gonzales-Ruano et al., Nat. Commun. (in press), arXiv:2509.15983.
I9: Recent advances in optical nanoscopy with quantum materials
Mengkun Liu
Stony Brook University
In this talk, I will introduce two emerging optical nanoscopy techniques and the new science they enable. These techniques, namely magneto-scanning near-field optical microscopy (m-SNOM) and BOlometric Superconducting Optical Nanoscopy (BOSON), can dramatically expand our ability to probe quantum materials at the nanoscale. Using m-SNOM, we demonstrate Landau-level nanoscopy that directly visualizes Landau quantization and magneto-polariton formation with 10 nm spatial resolution. A waveguide quantum electrodynamics (QED) framework reveals spatially resolved hybridization between magnetic excitations due to Landau level transitions and phonon polaritons, yielding universal scaling behaviors and design principles for nano-cavities with tunable light–matter coupling. With BOSON, we integrate superconducting transition-edge sensors with near-field optics to achieve ultra-sensitive detection of nano-light at below nanowatt power levels. This platform enables nanoscale imaging of Cooper pair dynamics and confined bosonic modes in low-dimensional systems, offering a new pathway toward quantum-limited spectroscopy and single-polariton detection. I will conclude by discussing future directions, including the integration of these techniques for exploring THz quantum optics, polaritonic circuitry, and strongly correlated quantum phases in complex materials.
I10: Lattice and Superlattice Engineering of Quantum Materials
Aravind Devarakonda
Columbia University
Manipulating materials at the atomic scale often drives advances in fundamental condensed matter physics. In this talk, I will introduce our newly established group’s approach combining materials synthesis, advanced characterization, and device fabrication to achieve such control to ultimately create new quantum materials.
First, I will highlight a new family of bulk van der Waals (vdW) superlattices derived from transition metal dichalcogenides, where reduced dimensionality and both in-plane and out-of-plane structural modulations give rise to novel electronic phases, for example, unconventional, spatially modulated superconductivity; I will connect these results from bulk compounds to contemporary work on other periodically modulated structures such as moiré materials. Then I will discuss the van der Waals metal Pd5AlI2, where a particular combination of atomic orbitals (i.e., chemistry) “decorating” a primitive square lattice gives rise to an electronic structure analogous to the 2D Lieb lattice model.
I will conclude by looking forward and outlining our efforts to combine materials synthesis with nanoscale strain control that promise to unlock new ways of manipulating structure, symmetry, and novel quantum behavior therein.
Poster presentations
P1: Geometric Scaling and Gluon Saturation at the EIC
Rojae Mighty, Tu Zhoudunming, Arjun Kumar
Stony Brook University
P2: Spatial Variations in the Charge Density Wave State in 1T-TiSe₂
Susree Mohapatra, Ghilles Ainouche, Resmi Sudheer and Michael C. Boyer
Clark University
P3: Harnessing NDR for self-sustainable electrical oscillations in single crystals of vanadium oxides
Nitin Kumar, Nicholas Jerla, George Agbeworvi, Priyanka Vadnere, Sangit Baskota, Sarbajit Banerjee, Sambandamurthy Ganapathy
Department of Physics, University at Buffalo, The State University of New York, Buffalo, NY 14260, USA
Department of Chemistry, Texas A&M University, College Station, TX 77843-0200, USA
P4: Optimal Experimental Design for Quantum Circuit Patterning
Kristofer Reyes, P. Baity, A. Hoisie, N. Isenberg, T. Kaleem, P. Love, J. McKinney, G. Park, N. Urban, B-J Yoon, E. Yelton, S. Weeden
University at Buffalo
Brookhaven National Laboratory
Syracuse University
University of Wisconsin-Madison
P5: (withdrawn)
P6: X-ray Observation of the Gamma-Ray Emitting Radio Galaxy NGC 4261
Elizabeth Kuhlkin, Dr. Ka-Wah Wong
Department of Physics, SUNY Brockport
P7: Materials Analysis for Topological Superconductivity
Joseph Cordone, Daniel Titcombe, Ji Ung Lee
Department of Physics, University at Albany
College of Nanotechnology, Science, and Engineering, University at Albany
P8: Development Of a High Vacuum Based Analysis System for Determining the Reliability of MEMS Devices
Alvar Garza, Meghan Herbert, Anthony Valenti,Carl A. Ventrice, Jr. Matthew Strohmayer, Joleyn Brewer, Christopher Nassar, and Christopher Keimel
Department of Nanoscale Science & Engineering, University at Albany
Menlo Microsystems, Inc. Albany
P9: Path Integral Monte Carlo for Open-Boundary Bosonic Lattices
Liam Jones, Hatem Barghathi, Adrian Del Maestro
University at Buffalo
University of Tennessee, Knoxville
P10: Edge and Hinge modes observed in Bi(110) islands on NdBi
Divyanshi Sar1, Mingda Gong1, Luka Khizanishvilli1, Jose A. Moreno6,7, Juan Schmidt4,5, Kendall Ramos2, Salvador Barraza-Lopez2,3, Paul C. Canfield4,5 and Pegor Aynajian1
1. Departmentt of Physics, Applied Physics and Astronomy, Binghamton University, Binghamton, New York 13902, USA,
2. University of Arkansas, Fayetteville, AR 72701, USA,
3. MonArk NSF Quantum Foundry, University of Arkansas, Fayetteville, AR 72701, USA,
4. Department of Physics and Astronomy, Iowa State University, Ames, IA 50011, USA,
5. Ames National Laboratory, Iowa State University, Ames, IA 50011, USA,
6. Laboratorio de Bajas Temperaturas y Altos Campos Magnéticos, Departamento de Física de la Materia Condensada, Instituto Nicolás Cabrera and Condensed Matter Physics Center (IFIMAC), Universidad Autónoma de Madrid, E-28049 Madrid, Spain,
7. Unidad Asociada de Bajas Temperaturas y Altos Campos Magnéticos, UAM, CSIC, Cantoblanco, E-28049 Madrid, Spain
P11: Scanning Tunneling Microscopy Studies of Magnetic Topological Phases in Layered Eu-Based Compounds
Luka Khizanishvili, Anika Tabassum Raisa, Divyanshi Sar, Mingda Gong, Tetiana Romanova, Erekle Jmukhadze, Hannah Park, Dariusz Kaczorowski, Wei-Cheng Lee, and Pegor Aynajian
Department of Physics, Applied Physics and Astronomy, Binghamton University
Institute of Low Temperature and Structure Research, Polish Academy of Sciences, Okólna 2, 50-422 Wrocław, Poland
P12: Optimizing Higher-Order Photon Correlation Using Machine Learning for Novel Sensing Technology
Yasmin Sarhan¹, Umadini Ranasinge¹, Abigail L. Stressinger², Guangpeng Xu¹, James Berry² and Tim Thomay¹*
1 Department of Physics, State University of New York at Buffalo, Buffalo
2 Department of Biology, State University of New York at Buffalo, Buffalo
P13: Electronics and Optoelectronics with Carbon Nanotube Films
Vasili Perebeinos1 , Davoud Adinehloo1, Viktor Labuntsov1 , Weilu Gao2, Ali Mojibpour3, Rui Xu3, Jacques Doumani3, Nina Hong4, Anna-Christina Samaha5, Weiran Tu3, Fuyang Tay3, Elizabeth Blackert3, Jiaming Luo3, Mario El Tahchi5, Jun Lou3, Yohei Yomogida6, Kazuhiro Yanagi6, Riichiro Saito6, Andrey Baydin3, Hanyu Zhu3, and Junichiro Kono3
1 University at Buffalo
2 University of Utah
3 Rice University
4 J. A. Woollam Co. Inc.
5 Lebanese University
6 Tokyo Metropolitan University
P14: Giant Second Harmonic Generation from Wafer-Scale Aligned Chiral Carbon Nanotubes
Viktor Labuntsov(1); Rui Xu(2); Jacques Doumani(3, 4); Nina Hong(5); Anna-Christina Samaha(6, 7); Weiran Tu(2); Fuyang Tay(3, 4); Elizabeth Blackert(2); Jiaming Luo(2, 4); Mario Tahchi(6, 7); Weilu Gao(8); Jun Lou(2); Yohei Yomogida(9); Kazuhiro Yanagi(9); Riichiro Saito(9, 10, 11); Vasili Perebeinos(1); Andrey Baydin(3, 4); Junichiro Kono(2, 3, 4); Hanyu Zhu(2, 3, 4)
1. University at Buffalo, Buffalo, NY, United States.
2. Department of Materials Science and NanoEngineering, Rice University, Houston, TX, United States.
3. Department of Electrical and Computer Engineering, Rice University, Houston, TX, United States.
4. Smalley-Curl Institute, Rice University, Houston, TX, United States.
5. J.A. Woollam Company, Inc., Lincoln, NE, United States.
6. Laboratory of Biomaterials and Intelligent Materials, Lebanese University, Jdeidet, Lebanon.
7. Department of Physics, Lebanese University, Jdeidet, Lebanon.
8. Department of Electrical and Computer Engineering, The University of Utah, Salt Lake City, UT, United States.
9. Department of Physics, Tokyo Metropolitan University, Tokyo, Japan.
10. Department of Physics, Tohoku University, Sendai, Japan.
11. Department of Physics, National Taiwan Normal University, Taipei, Taiwan.
P15: Evolution of microwave spectroscopy in topological planar Josephson junctions
David S. Brandao1, Baris Pekerten1, Bailey Bussiere1, Jong E. Han1, Javad Shabani2, Igor Zutic1
1 Department of Physics, University at Buffalo, State University of New York
2 Center for Quantum Information Physics, Department of Physics, New York University
P16: Constrained Superradiance
Luis Fernando dos Prazeres, Hossein Hosseinabadi, Jamir Marino
University at Buffalo
JGU Mainz
P17: Mechanisms for oxygen vacancy defect migration in SrTiO3/NiO heterostructures
Anish More, Dr. Pratik Dholabhai
P18: Growth and Characterization of Rare Earth Intermetallics EuGa4 and EuAl4
Kevin Euscher, Nawanath Budhathoki, Sangit Baskota, Changjiang Liu
University at Buffalo Department of Physics
P19: Disorder-Assisted Adiabaticity in Interaction Pulses
ShangJie, Liou
University at Buffalo, Department of Physics
P20: Kohn-Sham Hamiltonian Mapping with Machine Learning for Nonadiabatic Molecular Dynamics
Mohammad Shakiba, Alexey V. Akimov
Department of Chemistry, State University of New York at Buffalo
P21: Determining Effect of Encapsulation Environment on Resistance of MEMS Switches
Meghan Herbert1, Matthew Strohmayer2, Joleyn Brewer2, Christopher Nassar2, Christopher Keimel2, and Carl A. Ventrice, Jr.3
1 Department of Electrical and Computer Engineering, University at Albany
2 Menlo Microsystems, Inc., 257 Fuller Road, Albany, New York 12203
3 Department of Nanoscale Science & Engineering, University at Albany
P22: Scalable quantum circuits for many-body quantum optics simulations
Vincent P. Iglesias-Cardinale, Shreekanth S. Yuvarajan, Herbert F. Fotso
University at Buffalo
P23: Modeling Mixed-Order Quantum Phase Transitions through Network Interdependency
Stanley Goodwin and Dr. Xiangyi Meng
Department of Physics, Applied Physics, and Astronomy, Rensselaer Polytechnic Institute, Troy, NY 12180
P24: Determining The Number of Trials For The Direct Detection of Quantum Entanglement Through the Human Visual System
Pinki Chahal
University at Buffalo
P25: Enabling the OAM degree of freedom at SANS
Priyanka Rajendra Vadnere
University at Buffalo
P26: Stripe antiferromagnetism and chiral superconductivity in tWSe2
Erekle Jmukhadze, Sam Olin, Allan H. MacDonald, Wei-Cheng Lee
Binghamton University
UT Austin
P27: Engineering Nontrivial Topological Phase Transitions using Trivial Rashba Monolayers
Arjyama Bordoloi, Daniel Kaplan, Sobhit Singh
Department of Mechanical Engineering, University of Rochester, New York 14627, USA
Center for Materials Theory, Department of Physics and Astronomy, Rutgers University, Piscataway, New Jersey 08854-8019, USA
P28: Suppression of auxetic behavior in black phosphorus with sulfur substitution
Hayden Groeschel1, Arjyama Bordoloi1, Sobhit Singh1,2
1 Department of Mechanical Engineering, University of Rochester, New York 14627
2 Materials Science Program, University of Rochester, New York 14627, USA
P29: Cavity Mediated Two-Qubit Gate: Tuning to Optimal Performance with NISQ Era Quantum Simulations
Shreekanth S. Yuvarajan, Vincent Iglesias-Cardinale, Herbert F. Fotso
University at Buffalo, SUNY
P30: Nonequilibrium dynamics of a disordered binary alloy
Aly Abuelmaged, Eric Dohner, Shang-Jie Liou, Herbert F Fotso
Department of Physics, University at Buffalo SUNY, Buffalo, New York 14260, USA
Earth Resources Technology Inc, Greenbelt, MD, 20770, USA
P31: Absorption spectrum splitting in a pulse-driven three-level system
Anthony Gullo
University at Buffalo
P32: TetraCal: A 4D Calorimeter Prototype for Next Generation High Energy Detectors
Carlos Perez Lara
Hofstra University
P33:Making Nano-Shapes to Capture Forever Chemicals
Avery Di Iulio (1), Rachel Fister (2), Nicholas S. Bingham (2), Kristen L.S. Repa (1)
1 Department of Physics, SUNY Brockport
2 Department of Physics & the Frontier Institute for Research in Sensor Technologies, University of Maine
P34: Microwave irradiation in topological superconducting chains
B. Bussiere, D. S. Brandão, B. Pekerten, J. Marino, J. E. Han, I. Žutić
P35: Path Entanglement from a Lossless Beam Splitter
Chris J. Gravina, Brian Data Lee, and Edwin E. Hach,
School of Physics and Astronomy, Rochester Institute of Technology, Rochester, New York, USA
P36: Defect-induced Nonlinear Response of Hexagonal Boron Nitride
Olga Savkina1 , Cecilia L.A.V. Campos2 , Davoud Adinehloo1 , Alexander Baev2, Andrey Kuzmin2, Igor Aharonovich3 ,Vasili Perebeinos1 ,and Paras N.Prasad2
1 Department of Electrical Engineering, University at Buffalo
2 Department of Chemistry and The Institute for Lasers, Photonics, and Biophotonics, University at Buffalo
3 University of Technology Sydney
P37: Phonon-assisted Coherent Transport in Armchair Carbon Nanotube Films
Davoud Adinehloo, Weilu Gao, Ali Mojibpour, Junichiro Kono, and Vasili Perebeinos
University at Buffalo
University of Utah
Rice University
P38: Impact of crystallinity on the circular and linear dichroism signals in chiral perovskite
Reshna Shrestha, Wanyi Nie
University at Buffalo
P39: Growth and Investigation of Superconducting Iron Selenide
Sangit Baskota, Nawanath Budhathoki, Kevin Euscher, Changjiang Liu
Department of Physics, University at Buffalo, SUNY, Buffalo, New York 14260
P40: Pressure-Dependent Nonlinear Optical Responses of Materials in Diamond Anvil Cells
Henry Glover, Terry-Ann Suer, Samuel Crossley, Khanh Kieu
P41: Development of an Atomic Layer Deposition System for Fusion-Relevant Materials and Components
Tyler Liao 1, Luke Herter 1, Mark Wittman 1, Matthew Sharpe 1 , Jeffrey Woodward 2, Alexander Kozen 3, Zachary Robinson 1
1 The University of Rochester’s Laboratory for Laser Energetics
2 The United States Naval Research Laboratory
3 The University of Vermont, Department of Physics and Astronomy
P42: Entropic Dynamics approach to the classical limit of Quantum Mechanics: decoupling of the center of mass motion for a mesoscopic particle
Fatimah Judayba 1,2 and Ariel Caticha 1
1 Department of Physics, University at Albany–SUNY, Albany, NY 12222, USA
2 Jazan University, College of Science, Department of Physical Sciences, Physics Division, P.O. Box 114, 45142, Jazan, Kingdom of Saudi Arabia
P43: Gate-Tunable Josephson Parametric Amplifier with Sn-InAs nanowires
Amritesh Sharma1, Amrita Purkayastha1, Shreyas Asodekar1, Subhayan Sinha1, An-Hsi Chen2, Connor P. Dempsey3, Chris Palmstrøm3, Moïra Hocevar2, Kun Zuo4, Michael Hatridge5, Sergey Frolov1
1 Department of Physics and Astronomy, University of Pittsburgh, Pittsburgh, PA, 15260
2 Univ. Grenoble Alpes, CNRS, Grenoble INP, Institut Néel, 38000 Grenoble, France
3 Electrical and Computer Engineering, University of California Santa Barbara, CA, 93106, USA
4 ARC Centre of Excellence for Engineered Quantum Systems, UNSW, NSW 2006, Australia
5 Applied Physics, Yale University, New Haven, CT 06511
P44: Phonon Softening in Chalcogenide Perovskites (BaHfS3, BaZrS3) Probed by THz Time-Domain Spectroscopy
Arif Ullah, Haolei Hui, Lauren Samson, Hao Zeng, Andrea Markelz and John Cerne
Department of Physics, University at Buffalo, SUNY
P45: Heterogeneous integration of diamond and AlN using a semiconductor grafting technique
Xuanyu Zhou, Chenyu Wang, Jie Zhou, Matthias Muehle, Katherine Fountaine, Vincent Gambin, Zhenqiang Ma, Jung-Hun Seo
Department materials design and innovation, University at Buffalo
P46: Interfacial Design of 2D Energy-Efficient Nanoelectronics
Huamin Li
University at Buffalo