FR-A6.1P.2

Enhancing Bandwidth and Sensitivity of Rydberg Atom Based Sensors

Nikunjkumar Prajapati, Samuel Berweger, Andrew Rotunno, Alexandra Artusio-Glimpse, Noah Schlossberger, Dangka Shylla, William Watterson, Mathew Simons, Christopher Holloway, NIST, United States
Session:
Quantum Technology Related to Electromagnetics II Oral
Track:
AP-S: Antenna Applications and Emerging Technologies
Location:
Teatrino: 0-18
Session Time:
Fri, 19 Jul, 13:40 - 17:20
Presentation Time:
Fri, 19 Jul, 14:00 - 14:20
Session Co-Chairs:
Thomas Roth, Purdue University and Paolo Rocca, ELEDIA@UniTN - University of Trento and Weng Chew, Purdue University
Presentation
Discussion
Session FR-A6.1P
FR-A6.1P.1: Colinear Three Photon Approach to Rydberg Atom-Based Sensors
Harald Kübler, Stephanie Bohaichuk, Florian Christaller, Vijin Venu, Matthias Schmidt, Chang Liu, James Shaffer, Quantum Valley Ideas Laboratories, Canada
FR-A6.1P.2: Enhancing Bandwidth and Sensitivity of Rydberg Atom Based Sensors
Nikunjkumar Prajapati, Samuel Berweger, Andrew Rotunno, Alexandra Artusio-Glimpse, Noah Schlossberger, Dangka Shylla, William Watterson, Mathew Simons, Christopher Holloway, NIST, United States
FR-A6.1P.3: Simulation of a Rydberg RF sensor based on modulation transfer
Mickael Branco, Duc-Anh Trinh, Alienor Rouxel, Perrine Berger, Sacha Welinski, Fabienne Goldfarb, Fabien Bretenaker, University Paris-Saclay, France
FR-A6.1P.4: Fast Simulation of Many-Body Rydberg Atomic Systems for Quantum Sensing
Xinyi Y. I. Xu, Zhejiang University, China; Guoda Xie, Anhui University, China; Lei Ying, Zhejiang University, China; Jinpeng Yuan, Shanxi University, China; Wei E. I. Sha, Zhejiang University, China
FR-A6.1P.5: Field-Based Formalism for Calculating Qubit-Qubit Exchange Coupling Rates for Transmon Qubits
Ghazi Khan, Thomas Roth, Purdue University, United States
FR-A6.1P.6: A $\delta$-free approach to quantization of transmission lines connected to lumped circuits
Carlo Forestiere, Giovanni Miano, University of Naples, Italy
FR-A6.1P.7: Hybrid Numerical Modeling Method for Josephson Traveling Wave Parametric Amplifiers
Samuel Elkin, Purdue University, United States; Michael Haider, Technical University of Munich, United States; Thomas Roth, Purdue University, United States
FR-A6.1P.8: Quantum Entanglement Computation Using Canonical Quantization in a Waveguide and Scattering Theory
Jie Zhu, Purdue University, United States; Dong-Yeop Na, Pohang University of Science and Technology, Korea (South); Weng Chew, Purdue University, United States
FR-A6.1P.9: What is the Directivity of a Quantum Antenna System? Fundamental Considerations and Examples
Said Mikki, Zhejiang University/University of Illinois Urbana Champaign Institute, China
FR-A6.1P.10: Study on the Spectrum Splitting by Dielectric Loading for Room-Temperature Optical Quantum Bits Design
Boyuan Zhang, Jie Zhu, PURDUE UNIVERSITY, United States; Dong-Yeop Na, Pohang University of Science and Technology, United States; Thomas Roth, Weng Cho Chew, Purdue University, United States
Resources
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