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Quantum Information Science for Fundamental Physics

17–22 Feb 2020
US/Mountain timezone

Contribution List

37 / 37
1. Perspectives on Quantum Information Science for Fundamental Physics
John Preskill (Caltech)
18/02/2020, 08:00
2. Quantum electromagnetic sensors and the search for axion dark matter below 1 micro-eV
Kent Irwin (Stanford University)
18/02/2020, 08:40
3. New Ideas in Dark Matter Detection
Kathryn Zurek
18/02/2020, 09:40
4. Quantum technologies for gravitational wave detectors
Nergis Mavalvala (MIT)
18/02/2020, 10:20
5. Comments on QI in accelerating cosmology (phenomenological and thought-experimental)
Eva Silverstein (Stanford)
18/02/2020, 16:30
6. Quantum entropy generated by dynamical evolution
Josephine Suh
18/02/2020, 17:00

We introduce the notion of a time density matrix which captures a probabilistic ensemble of systems in specified states at different times. The quantum entropy of a time density matrix quantifies the information needed to track the unitary evolution of an arbitrary quantum system. As such it can grow with time, and is a finer probe of the dynamics of the system than the quantum entropy of a...
8. Sensing, Entanglement, and Scrambling
Alexey Gorshkov
19/02/2020, 08:00

We will begin by discussing optimal entanglement-based protocols for measuring spatially varying fields with a sensor network. We will then discuss fast protocols for preparing the required entangled states and lower bounds on the preparation time. Finally, we will discuss applications of these and related bounds to quantum information scrambling.
9. Advanced Characterization and Sensing with Squeezed Optomechanical Systems
Raphael Pooser (Oak Ridge National Laboratory)
19/02/2020, 08:30

In this talk I will outline quantum-enhanced sensing modalities for nanoscale displacement and phase
sensing. Optomechanical devices use optical readout of micro/nano-electromechanical systems (MEMS)
displacement in order to transduce displacement and phase signals. New detection modes that focus on
ultrasonic measurements have brought the shot noise of the optical field into play when...
10. Cavity Optomechanics: Generating Mechanical Interference Fringes and Brillouin Optomechanical Strong Coupling
Michael Vanner (Imperial College, London)
19/02/2020, 09:30

Cavity quantum optomechanics utilizes electromagnetic fields to generate and study quantum states of motion of macroscopic mechanical oscillators. The field has undergone significant growth recently owing to its significant promise for both quantum technology development and to test the foundations of physics. Our new team at Imperial College London - the Quantum Measurement Lab - pursue a...
11. Quantum Control of Harmonic Oscillator Motional States of Ions
Dietrich Leibfried
19/02/2020, 10:00

This talk will give an overview of recent work on quantum control of the har- monic oscillator states of motion realized with trapped ions at NIST. We prepare non-classical states of the motion of a single Be+ or Mg+ ion, such as approxi- mately pure number states of ion motion up to n = 100 [1], coherent superpo- sitions of the ground state with number states up to n = 16 [1] and squeezing to...
39. Quantum Computing and the Entanglement Frontier
John Preskill (Caltech)
19/02/2020, 17:30
12. Replica Wormholes and the Black Hole Interior
Geoff Penington (Stanford University)
20/02/2020, 08:00

Naïve semiclassical arguments suggest that the entropy of Hawking radiation should continue to grow even at very late times, a result that is inconsistent with the unitarity of quantum mechanics. In this talk, I will argue that a more careful replica trick calculation shows that the gravitational path integral becomes dominated (at late times) by saddles containing spacetime wormholes. These...
13. A Traversable Wormhole Teleportation Protocol in the SYK Model
Ping Gao
20/02/2020, 08:30
14. Superconducting Kinetic Inductance Technologies for Submillimeter Single-Photon Detection and Quantum-Limited Amplification for Spectroscopy in Space
Omid Noroozian
20/02/2020, 10:00
15. Superconducting Nanowire Detectors for rare event searches
Sae Woo Nam
20/02/2020, 10:30
17. Axion and Gravitational Waves from Black Hole Superradiance
Masha Baryakhtar (NYU)
20/02/2020, 16:30

Theories beyond the Standard Model of particle physics often predict new, light, feebly interacting particles whose discovery requires novel search strategies. A light particle, the QCD axion, elegantly solves the outstanding strong-CP problem of the Standard Model; cousins of the QCD axion can also appear, and are natural dark matter candidates. I will show how rotating black holes turn into...
18. Searching for Dark Matter with Athermal Phonon Detectors Throughout the Mass Range from 50meV through 500MeV
Matt Pyle (Berkeley)
20/02/2020, 17:00

Substantial astronomical observations have established that approximately 25% of the energy density of the universe is composed of cold non-baryonic dark matter, whose detection and characterization could be key to improving our understanding of the laws of physics. Over the past three decades, physicists have largely focused on searching for dark matter within the 10 GeV-1 TeV range (WIMPs),...
19. ABRACADABRA-10cm: Searching for Axions and Preparing for DMRadio-m3
Lindley Winslow (MIT)
20/02/2020, 17:30
20. Dark Matter Detection with Magnons and Phonons
K. Zhang
20/02/2020, 18:30
21. Plasmons and Excesses in Low-Threshold Dark Matter Experiments
Yoni Kahn (UIUC)
20/02/2020, 19:00

Spectacular advances in dark matter detection experiments, using a variety of detector materials, have pushed energy thresholds below 60 eV and charge detection to single-charge resolution. Eleven such low-threshold experiments have observed an unexplained excess of events at low energies. Surprisingly, the excess rates of ~ 10 Hz/kg in semiconductor detectors are the same to within a factor...
26. Synthesis of Quantum-Noise-"Free" Systems
Rana Adhikari
21/02/2020, 08:00

The sensitivity of quantum-noise limited systems can be greatly increased by engineering the quantum correlations of the probing field either externally (e.g. squeezed light) or internally (e.g. strong nonlinearities and/or coherent quantum control). Techniques used in the optimization of classical electrical circuits can be applied to the maximization of SNR in the context of the quantum...
24. Mechanical architectures for fundamental physics detection
Dan Carney
21/02/2020, 08:30

Mechanical sensing technologies in the classical and quantum regimes have been demonstrated across an enormous range of frequency and mass scales. I'll overview some ideas about using these sensing techniques to look a diverse variety of dark matter candidates, including ultra-light (m < meV) and ultra-heavy (m > m_GUT) fields. The theory of quantum backaction-evading measurements, especially...
25. A Supersonically expanding BEC: An expanding universe in the lab
Gretchen Campbell
21/02/2020, 09:00

The massive scale of the universe makes the experimental study of cosmological inflation
difficult. This has led to an interest in developing analogous systems using table top
experiments. One possible system for such simulations is an expanding atomic quantum gas.
In recent experiments, we have modeled the basic features of an expanding universe by
drawing parallels with an expanding...
22. Quantum Gravity in the Lab
Stefan Leichenauer
21/02/2020, 10:00

The trend of theoretical advances in AdS/CFT suggests that quantum gravity is broadly applicable as an effective description of chaotic many-body physics. Experimental realizations of such systems are now coming online, with more progress expected in the next few years. We can and should use tools of quantum gravity to describe the physics of these experiments. I will sketch one possible...
23. Hidden Space-times in Quantum Spin Chains
Charles Cao
21/02/2020, 10:30

It has been suggested that space-time geometries can emerge from quantum entanglement in the context of AdS/CFT and beyond. Inspired by travel-time tomography in seismology, we construct a geometry detector that quantitatively determines whether classical space-times can actually emerge from certain entanglement patterns. Then we explicitly reconstruct the best-fit emergent holographic...
27. Precision searches for new physics using optically levitated sensors
David Moore (Yale)
21/02/2020, 16:30
28. Exploring sensing and quantum measurement with membrane cavity optomechanics
Cindy Regal (University of Colorado)
21/02/2020, 17:00
29. Quantum metamaterial for nondestructive microwave photon detection
Alexandre Blais
21/02/2020, 18:00

Detecting traveling photons is an essential primitive for many quantum information processing tasks. We propose a single-photon detector operating in the microwave domain based on a nonlinear metamaterial built from a large number of coupled Josephson junctions. By trading local nonlinearity for large spatial extent, this approach allows for a large detection bandwidth. Using numerical...
30. TBD
Dave Schuster (Chicago)
21/02/2020, 18:30
31. HAYSTAC and the Search for Dark Matter Axions above 10 micro-eV
Reina Maruyama (Yale)
21/02/2020, 19:00
32. Quantum algorithms for pattern recognition in high-energy physics experiments
Heather Gray
22/02/2020, 08:00
33. Quantum Algorithms for High Energy Physics Simulations
Christian Bauer
22/02/2020, 08:30
16. Axion Searches from Micro-eV to Milli-eV
Andrew Sonnenschein
22/02/2020, 09:30
34. First results of DarkSRF: a dark photon search using SRF cavities
Anna Grasselino (Fermilab)
22/02/2020, 10:00
37. Panel discussion: Strategies for Advancing QIS and Fundamental Science (Raphael Bousso, Joe Lykken, Yoshihisa Yamamoto, Maria Spiropulu + ...)
Aaron Chou, Joe Lykken (Fermilab), Kathryn Zurek, Konrad Lehnert, Maria Spiropulu (Caltech), Raphael Bousso (Berkeley)
22/02/2020, 10:30

Gathering the perspective of leaders in quantum computing, quantum gravity, HEP theory and experiment. Where do we think each of the fields is going? What are near-term opportunities for cross-fertilization? How can we make best use of the opportunities offered by the National Quantum Initiative, by investments made by industry, and by the HEP Snowmass process? What are the long-term...
36. Entanglement normalization in effective field theories
Daniele Alves
38. Summary/reflection (Aaron Chou, Konrad Lehnert, Brian Swingle, Kathryn Zurek)
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