Your search keyword '"Mahiro Abe"' showing total 5 results

1. Atom Interferometry with Floquet Atom Optics

Author

Thomas Wilkason, Megan Nantel, Jan Rudolph, Yijun Jiang, Benjamin E. Garber, Hunter Swan, Samuel P. Carman, Mahiro Abe, and Jason M. Hogan

Subjects

Condensed Matter::Quantum Gases, Quantum Physics, Atomic Physics (physics.atom-ph), FOS: Physical sciences, General Physics and Astronomy, Physics::Atomic Physics, Quantum Physics (quant-ph), Physics - Atomic Physics

Abstract

Floquet engineering offers a compelling approach for designing the time evolution of periodically driven systems. We implement a periodic atom-light coupling to realize Floquet atom optics on the strontium ${}^1\!S_0\,\text{-}\, {}^3\!P_1$ transition. These atom optics reach pulse efficiencies above $99.4\%$ over a wide range of frequency offsets between light and atomic resonance, even under strong driving where this detuning is on the order of the Rabi frequency. Moreover, we use Floquet atom optics to compensate for differential Doppler shifts in large momentum transfer atom interferometers and achieve state-of-the-art momentum separation in excess of $400~\hbar k$. This technique can be applied to any two-level system at arbitrary coupling strength, with broad application in coherent quantum control., Comment: 5 pages, 3 figures, plus supplemental material

Published

2022

2. QMATCH: Quantum Measurement of Atomic Charge

Author

Jason Hogan, Thomas Wilkason, Hunter Swan, Jan Rudolph, Yijun Jiang, Megan Nantel, Samuel Carman, Mahiro Abe, and Benjamin Garber

Published

2022

3. 401 $\hbar k$ Atom Interferometry with Floquet Atom Optics

Author

Benjamin Garber, Jason Hogan, Mahiro Abe, Samuel Carman, Yijun Jiang, Hunter Swan, Thomas Wilkason, Jan Rudolph, and Megan Nantel

Published

2022

4. Magnetic shield design for atom interferometry over a 100m baseline

Author

Benjamin Garber, Jason Hogan, Thomas Wilkason, Hunter Swan, Jan Rudolph, Megan Nantel, Samuel Carman, Mahiro Abe, and Yijun Jiang

Published

2022

5. Optimizing the efficiency of Fabry-Perot interferometers with silicon-substrate mirrors

Author

Mahiro Abe, Stephen C. Parshley, Gordon J. Stacey, Michael D. Niemack, Nicholas F. Cothard, Thomas Nikola, Eve M. Vavagiakis, Brian J. Koopman, Kenneth J. Vetter, Patricio A. Gallardo, and German Cortes-Medellin

Subjects

Materials science, Silicon, business.industry, Bolometer, FOS: Physical sciences, chemistry.chemical_element, Metamaterial, Substrate (electronics), 01 natural sciences, 7. Clean energy, law.invention, 010309 optics, Finesse, chemistry, law, Optical cavity, 0103 physical sciences, Deep reactive-ion etching, Optoelectronics, Astrophysics - Instrumentation and Methods for Astrophysics, business, Instrumentation and Methods for Astrophysics (astro-ph.IM), Fabry–Pérot interferometer

Abstract

We present the novel design of microfabricated, silicon-substrate based mirrors for use in cryogenic Fabry-Perot Interferometers (FPIs) for the mid-IR to sub-mm/mm wavelength regime. One side of the silicon substrate will have a double-layer metamaterial anti-reflection coating (ARC) anisotropically etched into it and the other side will be metalized with a reflective mesh pattern. The double-layer ARC ensures a reflectance of less than 1% at the surface substrate over the FPI bandwidth. This low reflectance is required to achieve broadband capability and to mitigate contaminating resonances from the silicon surface. Two silicon substrates with their metalized surfaces facing each other and held parallel with an adjustable separation will compose the FPI. To create an FPI with nearly uniform finesse over the FPI bandwidth, we use a combination of inductive and capacitive gold meshes evaporated onto the silicon substrate. We also consider the use of niobium as a superconducting reflective mesh for long wavelengths to eliminate ohmic losses at each reflection in the resonating cavity of the FPI and thereby increase overall transmission. We develop these silicon-substrate based FPIs for use in ground (e.g. CCAT-prime), air (e.g. HIRMES), and future space-based telescopes (e.g. the Origins Space Telescope concept). Such FPIs are well suited for spectroscopic imaging with the upcoming large IR/sub-mm/mm TES bolometer detector arrays. Here we present the fabrication and performance of multi-layer, plasma-etched, silicon metamaterial ARC, as well as models of the mirrors and FPIs., Comment: Presented at SPIE Advances in Optical and Mechanical Technologies for Telescopes and Instrumentation III, June 14, 2018

Published

2018