Your search keyword '"Seetharam, Kushal"' showing total 22 results

1. Dynamics of spin-momentum entanglement from superradiant phase transitions

Author

Chelpanova, Oksana, Seetharam, Kushal, Rosa-Medina, Rodrigo, Reiter, Nicola, Finger, Fabian, Donner, Tobias, and Marino, Jamir

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics, Quantum Physics

Abstract

Exploring operational regimes of many-body cavity QED with multi-level atoms remains an exciting research frontier for their enhanced storage capabilities of intra-level quantum correlations. In this work, we consider an experimentally feasible many-body cavity QED model describing a four-level system, where each of those levels is formed from a combination of different spin and momentum states of ultra-cold atoms in a cavity. The resulting model comprises a pair of Dicke Hamiltonians constructed from pseudo-spin operators, effectively capturing two intertwined superradiant phase transitions. The phase diagram reveals regions featuring weak and strong entangled states of spin and momentum atomic degrees of freedom. These states exhibit different dynamical responses, ranging from slow to fast relaxation, with the added option of persistent entanglement temporal oscillations. We discuss the role of cavity losses in steering the system's dynamics into such entangled states and propose a readout scheme that leverages different light polarizations within the cavity. Our work paves the way to connect the rich variety of non-equilibrium phase transitions that occur in many-body cavity QED to the buildup of quantum correlations in systems with multi-level atom descriptions., Comment: 13+12 pages, 8+2 figures

Published

2023

2. Accelerating analysis of Boltzmann equations using Gaussian mixture models: Application to quantum Bose-Fermi mixtures

Author

Dolgirev, Pavel E., Seetharam, Kushal, Kanász-Nagy, Márton, Robens, Carsten, Yan, Zoe Z., Zwierlein, Martin, and Demler, Eugene

Subjects

Condensed Matter - Quantum Gases

Abstract

The Boltzmann equation is a powerful theoretical tool for modeling the collective dynamics of quantum many-body systems subject to external perturbations. Analysis of the equation gives access to linear response properties including collective modes and transport coefficients, but often proves intractable due to computational costs associated with multidimensional integrals describing collision processes. Here, we present a method to resolve this bottleneck, enabling the study of a broad class of many-body systems that appear in fundamental science contexts and technological applications. Specifically, we demonstrate that a Gaussian mixture model can accurately represent equilibrium distribution functions, thereby allowing efficient evaluation of collision integrals. Inspired by cold atom experiments, we apply this method to investigate the collective behavior of a quantum Bose-Fermi mixture of cold atoms in a cigar-shaped trap, a system that is particularly challenging to analyze. We focus on monopole and quadrupole collective modes above the Bose-Einstein transition temperature, and find a rich phenomenology that spans interference effects between bosonic and fermionic collective modes, dampening of these modes, and the emergence of hydrodynamics in various parameter regimes. These effects are readily verifiable experimentally., Comment: 32 page (19 pages of the main text), 10 figures (7 are in the main text)

Published

2023

3. Collective flow of fermionic impurities immersed in a Bose-Einstein Condensate

Author

Yan, Zoe Z., Ni, Yiqi, Chuang, Alexander, Dolgirev, Pavel E., Seetharam, Kushal, Demler, Eugene, Robens, Carsten, and Zwierlein, Martin

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Strongly Correlated Electrons, Physics - Atomic Physics, Quantum Physics

Abstract

Interacting mixtures of bosons and fermions are ubiquitous in nature. They form the backbone of the standard model of physics, provide a framework for understanding quantum materials and are of technological importance in helium dilution refrigerators. However, the description of their coupled thermodynamics and collective behaviour is challenging. Bose-Fermi mixtures of ultracold atoms provide a platform to investigate their properties in a highly controllable environment, where the species concentration and interaction strength can be tuned at will. Here we characterize the collective oscillations of spin-polarized fermionic impurities immersed in a Bose-Einstein condensate as a function of the interaction strength and temperature. For strong interactions, the Fermi gas perfectly mimics the superfluid hydrodynamic modes of the condensate, from low-energy quadrupole modes to high-order Faraday excitations. With an increasing number of bosonic thermal excitations, the dynamics of the impurities cross over from the collisionless to the hydrodynamic regime, reminiscent of the emergence of hydrodynamics in two-dimensional electron fluids., Comment: Published version

Published

2023

4. Platform tailored co-design of gate-based quantum simulation

Author

Seetharam, Kushal, Sels, Dries, and Demler, Eugene

Subjects

Quantum Physics

Abstract

The utility of near-term quantum computers and simulators is likely to rely upon software-hardware co-design, with error-aware algorithms and protocols optimized for the platforms they are run on. Here, we show how knowledge of noise in a system can be exploited to improve the design of gate-based quantum simulation algorithms. We concretely demonstrate this co-design in the context of a trapped ion quantum simulation of the dynamics of a Heisenberg spin model. Specifically, we derive a theoretical noise model describing unitary gate errors due to heating of the ions' collective motion, finding that the temporal correlations in the noise induce an optimal gate depth. We then illustrate how tailored feedforward control can be used to mitigate unitary gate errors and improve the simulation outcome. Our results provide a practical guide to the co-design of gate-based quantum simulation algorithms., Comment: 12 pages, 8 figures

Published

2021

5. Dynamical scaling of correlations generated by short- and long-range dissipation

Author

Seetharam, Kushal, Lerose, Alessio, Fazio, Rosario, and Marino, Jamir

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We study the spatio-temporal spreading of correlations in an ensemble of spins due to dissipation characterized by short- and long-range spatial profiles. We consider systems initially in an uncorrelated state, and find that correlations widen and contract in a novel pattern intimately related to both the dissipative nature of the dynamical channel and its spatial profile. Additionally, we make a methodological contribution by generalizing non-equilibrium spin-wave theory to the case of dissipative systems and derive equations of motion for any translationally invariant spin chain whose dynamics can be described by a combination of Hamiltonian interactions and dissipative Lindblad channels. Our work aims at extending the study of correlation dynamics to purely dissipative quantum simulators and compare them with the established paradigm of correlations spreading in hamiltonian systems., Comment: 10 pages, 2 figures, builds on topic introduced in arXiv:2101.06445v2

Published

2021

6. Digital quantum simulation of NMR experiments

Author

Seetharam, Kushal, Biswas, Debopriyo, Noel, Crystal, Risinger, Andrew, Zhu, Daiwei, Katz, Or, Chattopadhyay, Sambuddha, Cetina, Marko, Monroe, Christopher, Demler, Eugene, and Sels, Dries

Subjects

Quantum Physics, Physics - Chemical Physics

Abstract

Computational simulations of nuclear magnetic resonance (NMR) experiments are essential for extracting information about molecular structure and dynamics, but are often intractable on classical computers for large molecules such as proteins and protocols such as zero-field NMR. We demonstrate the first quantum simulation of a NMR spectrum, computing the zero-field spectrum of the methyl group of acetonitrile on a trapped-ion quantum computer. We reduce the sampling cost of the quantum simulation by an order of magnitude using compressed sensing techniques. Our work opens a new practical application for quantum computation, and we show how the inherent decoherence of NMR systems may enable the simulation of classically hard molecules on near-term quantum hardware., Comment: 5 pages + 3 figures (main text), 10 pages + 6 figures (supplementary material)

Published

2021

7. Quantum Cherenkov transition of finite momentum Bose polarons

Author

Seetharam, Kushal, Shchadilova, Yulia, Grusdt, Fabian, Zvonarev, Mikhail, and Demler, Eugene

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We investigate the behavior of a finite-momentum impurity immersed in a weakly interacting three-dimensional Bose-Einstein condensate (BEC) of ultra-cold atoms, giving a detailed account of the dynamical quantum Cherenkov transition discussed in Ref. [arXiv:2101.00030]. Using a time-dependent variational approach, we identify a transition in the far-from-equilibrium dynamics of the system after the attractive short-range impurity-boson interaction is quenched on. The transition occurs as the impurity's velocity crosses an interaction-dependent critical value, and manifests in the long-time behavior of the Loschmidt echo and average impurity velocity. This behavior is also reflected in the finite momentum ground state of the system, where the group velocity of the interaction-dressed impurity loses it's dependence on the total momentum of the system as the critical point is crossed. The transition we discuss should be experimentally observable via a variety of common protocols in ultracold atomic systems such as time-of-flight imaging, RF spectroscopy, Ramsey interferometry, and absorption imaging., Comment: 15 pages, 7 figures

Published

2021

8. Correlation engineering via non-local dissipation

Author

Seetharam, Kushal, Lerose, Alessio, Fazio, Rosario, and Marino, Jamir

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

Controlling the spread of correlations in quantum many-body systems is a key challenge at the heart of quantum science and technology. Correlations are usually destroyed by dissipation arising from coupling between a system and its environment. Here, we show that dissipation can instead be used to engineer a wide variety of spatio-temporal correlation profiles in an easily tunable manner. We describe how dissipation with any translationally-invariant spatial profile can be realized in cold atoms trapped in an optical cavity. A uniform external field and the choice of spatial profile can be used to design when and how dissipation creates or destroys correlations. We demonstrate this control by preferentially generating entanglement at a desired wavevector. We thus establish non-local dissipation as a new route towards engineering the far-from-equilibrium dynamics of quantum information, with potential applications in quantum metrology, state preparation, and transport., Comment: 6+10 pages, 4+2 figures

Published

2021

9. Dynamical quantum Cherenkov transition of fast impurities in quantum liquids

Author

Seetharam, Kushal, Shchadilova, Yulia, Grusdt, Fabian, Zvonarev, Mikhail B., and Demler, Eugene

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

The challenge of understanding the dynamics of a mobile impurity in an interacting quantum many-body medium comes from the necessity of including entanglement between the impurity and excited states of the environment in a wide range of energy scales. In this paper, we investigate the motion of a finite mass impurity injected into a three-dimensional quantum Bose fluid as it starts shedding Bogoliubov excitations. We uncover a transition in the dynamics as the impurity's velocity crosses a critical value which depends on the strength of the interaction between the impurity and bosons as well as the impurity's recoil energy. We find that in injection experiments, the two regimes differ not only in the character of the impurity velocity abatement, but also exhibit qualitative differences in the Loschmidt echo, density ripples excited in the BEC, and momentum distribution of scattered bosonic particles. The transition is a manifestation of a dynamical quantum Cherenkov effect, and should be experimentally observable with ultracold atoms using Ramsey interferometry, RF spectroscopy, absorption imaging, and time-of-flight imaging., Comment: 5 pages, 3 figures + 4 pages, 3 figures

Published

2020

10. Strong coupling Bose polarons out of equilibrium: Dynamical RG approach

Author

Grusdt, Fabian, Seetharam, Kushal, Shchadilova, Yulia, and Demler, Eugene

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Other Condensed Matter, Quantum Physics

Abstract

When a mobile impurity interacts with a surrounding bath of bosons, it forms a polaron. Numerous methods have been developed to calculate how the energy and the effective mass of the polaron are renormalized by the medium for equilibrium situations. Here we address the much less studied non-equilibrium regime and investigate how polarons form dynamically in time. To this end, we develop a time-dependent renormalization group approach which allows calculations of all dynamical properties of the system and takes into account the effects of quantum fluctuations in the polaron cloud. We apply this method to calculate trajectories of polarons following a sudden quench of the impurity-boson interaction strength, revealing how the polaronic cloud around the impurity forms in time. Such trajectories provide additional information about the polaron's properties which are challenging to extract directly from the spectral function measured experimentally using ultracold atoms. At strong couplings, our calculations predict the appearance of trajectories where the impurity wavers back at intermediate times as a result of quantum fluctuations. Our method is applicable to a broader class of non-equilibrium problems. We also apply it to calculate the spectral function and find good agreement with experimental results. At very strong couplings, we predict that quantum fluctuations lead to the appearance of a dark continuum with strongly suppressed spectral weight at low energies. While our calculations start from an effective Fr\"ohlich Hamiltonian describing impurities in a three-dimensional Bose-Einstein condensate, we also calculate the effects of additional terms in the Hamiltonian beyond the Fr\"ohlich paradigm. We demonstrate that the main effect of these additional terms on the attractive side of a Feshbach resonance is to renormalize the coupling strength of the effective Fr\"ohlich model., Comment: 19 pages, 7 figures, 2 appendices

Published

2017

11. Collective flow of fermionic impurities immersed in a Bose–Einstein condensate

Author

Yan, Zoe Z., Ni, Yiqi, Chuang, Alexander, Dolgirev, Pavel E., Seetharam, Kushal, Demler, Eugene, Robens, Carsten, and Zwierlein, Martin

Abstract

Interacting mixtures of bosons and fermions are ubiquitous in nature. They form the backbone of the standard model of physics, provide a framework for understanding quantum materials and are of technological importance in helium dilution refrigerators. However, the description of their coupled thermodynamics and collective behaviour is challenging. Bose–Fermi mixtures of ultracold atoms provide a platform to investigate their properties in a highly controllable environment, where the species concentration and interaction strength can be tuned at will. Here we characterize the collective oscillations of spin-polarized fermionic impurities immersed in a Bose–Einstein condensate as a function of the interaction strength and temperature. For strong interactions, the Fermi gas perfectly mimics the superfluid hydrodynamic modes of the condensate, from low-energy quadrupole modes to high-order Faraday excitations. With an increasing number of bosonic thermal excitations, the dynamics of the impurities cross over from the collisionless to the hydrodynamic regime, reminiscent of the emergence of hydrodynamics in two-dimensional electron fluids.

Published

2024

12. Dissipationless flow in a Bose-Fermi mixture

Author

Yan, Zoe Z., Ni, Yiqi, Chuang, Alexander, Dolgirev, Pavel E., Seetharam, Kushal, Demler, Eugene, Robens, Carsten, and Zwierlein, Martin

Subjects

Condensed Matter - Strongly Correlated Electrons, Quantum Physics, Strongly Correlated Electrons (cond-mat.str-el), Quantum Gases (cond-mat.quant-gas), Atomic Physics (physics.atom-ph), FOS: Physical sciences, Quantum Physics (quant-ph), Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

Interacting mixtures of bosons and fermions are ubiquitous in nature. They form the backbone of the standard model of physics, provide a framework for understanding quantum materials such as unconventional superconductors and two-dimensional electronic systems, and are of technological importance in $^3$He/$^4$He dilution refrigerators. Bose-Fermi mixtures are predicted to exhibit an intricate phase diagram featuring coexisting liquids, supersolids, composite fermions, coupled superfluids, and quantum phase transitions in between. However, their coupled thermodynamics and collective behavior challenge our understanding, in particular for strong boson-fermion interactions. Clean realizations of fully controllable systems are scarce. Ultracold atomic gases offer an ideal platform to experimentally investigate Bose-Fermi mixtures, as the species concentration and interaction strengths can be freely tuned. Here, we study the collective oscillations of a spin-polarized Fermi gas immersed in a Bose-Einstein condensate (BEC) as a function of the boson-fermion interaction strength and temperature. Remarkably, for strong interspecies interactions the fermionic collective excitations evolve to perfectly mimic the bosonic superfluid collective modes, and fermion flow becomes dissipationless. With increasing number of thermal excitations in the Bose gas, the fermions' dynamics exhibit a crossover from the collisionless to the hydrodynamic regime, reminiscent of the emergence of hydrodynamics in two-dimensional electron fluids. Our findings open the door towards understanding non-equilibrium dynamics of strongly interacting Bose-Fermi mixtures., 12 pages, 10 figures

Published

2023

13. Dynamical Quantum Cherenkov Transition of Fast Impurities in Quantum Liquids

Author

Seetharam, Kushal, primary, Shchadilova, Yulia, additional, Grusdt, Fabian, additional, Zvonarev, Mikhail B., additional, and Demler, Eugene, additional

Published

2021

14. Catalyzing the quantum leap

Author

Seetharam, Kushal, primary and DeMarco, Michael, additional

Published

2021

15. An Interview with Professor Sheila Jasanoff: on Lessons from Science, Technology, and Society

Author

Chang, Joan, primary, Shaarma, Manas, additional, and Seetharam, Kushal, additional

Published

2021

16. Federal R&D funding: the bedrock of national innovation

Author

Mandt, Rebecca, primary, Seetharam, Kushal, additional, and Chang, Chung Hon Michael, additional

Published

2020

17. Strong-coupling Bose polarons out of equilibrium: Dynamical renormalization-group approach

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Seetharam, Kushal, Grusdt, Fabian, Shchadilova, Yulia, Demler, Eugene, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Seetharam, Kushal, Grusdt, Fabian, Shchadilova, Yulia, and Demler, Eugene

Abstract

When a mobile impurity interacts with a surrounding bath of bosons, it forms a polaron. Numerous methods have been developed to calculate how the energy and the effective mass of the polaron are renormalized by the medium for equilibrium situations. Here, we address the much less studied nonequilibrium regime and investigate how polarons form dynamically in time. To this end, we develop a time-dependent renormalization-group approach which allows calculations of all dynamical properties of the system and takes into account the effects of quantum fluctuations in the polaron cloud. We apply this method to calculate trajectories of polarons following a sudden quench of the impurity-boson interaction strength, revealing how the polaronic cloud around the impurity forms in time. Such trajectories provide additional information about the polaron's properties which are challenging to extract directly from the spectral function measured experimentally using ultracold atoms. At strong couplings, our calculations predict the appearance of trajectories where the impurity wavers back at intermediate times as a result of quantum fluctuations. Our method is applicable to a broader class of nonequilibrium problems. As a check, we also apply it to calculate the spectral function and find good agreement with experimental results. At very strong couplings, we predict that quantum fluctuations lead to the appearance of a dark continuum with strongly suppressed spectral weight at low energies. While our calculations start from an effective Fröhlich Hamiltonian describing impurities in a three-dimensional Bose-Einstein condensate, we also calculate the effects of additional terms in the Hamiltonian beyond the Fröhlich paradigm. We demonstrate that the main effect of these additional terms on the attractive side of a Feshbach resonance is to renormalize the coupling strength of the effective Fröhlich model., National Science Foundation (U.S.) (Grant DMR-1308435), United States. Air Force Office of Scientific Research (Grant FA9550-16-1-0323)

Published

2018

18. Strong-coupling Bose polarons out of equilibrium: Dynamical renormalization-group approach

Author

Grusdt, Fabian, primary, Seetharam, Kushal, additional, Shchadilova, Yulia, additional, and Demler, Eugene, additional

Published

2018

19. Quasi-Static Magnetic Field Shielding Using Longitudinal Mu-Near-Zero Metamaterials

Author

Lipworth, Guy, primary, Ensworth, Joshua, additional, Seetharam, Kushal, additional, Lee, Jae Seung, additional, Schmalenberg, Paul, additional, Nomura, Tsuyoshi, additional, Reynolds, Matthew S., additional, Smith, David R., additional, and Urzhumov, Yaroslav, additional

Published

2015

20. Applying Reduced Precision Arithmetic to Detect Errors in Floating Point Multiplication

Author

Seetharam, Kushal, primary, Keh, Lance Co Ting, additional, Nathan, Ralph, additional, and Sorin, Daniel J., additional

Published

2013

21. Magnetic Metamaterial Superlens for Increased Range Wireless Power Transfer.

Author

Lipworth, Guy, Ensworth, Joshua, Seetharam, Kushal, Da Huang, Jae Seung Lee, Schmalenberg, Paul, Nomura, Tsuyoshi, Reynolds, Matthew S., Smith, David R., and Urzhumov, Yaroslav

Subjects

METAMATERIALS, WIRELESS power transmission, MAGNETIC materials, ELECTROMAGNETIC induction, ELECTRICAL engineering

Abstract

The ability to wirelessly power electrical devices is becoming of greater urgency as a component of energy conservation and sustainability efforts. Due to health and safety concerns, most wireless power transfer (WPT) schemes utilize very low frequency, quasi-static, magnetic fields; power transfer occurs via magneto-inductive (MI) coupling between conducting loops serving as transmitter and receiver. At the "long range" regime - referring to distances larger than the diameter of the largest loop - WPT efficiency in free space falls off as (1/d)6; power loss quickly approaches 100% and limits practical implementations of WPTto relatively tight distances between power source and device. A "superlens", however, can concentrate the magnetic near fields of a source. Here, we demonstrate the impact of a magnetic metamaterial (MM) superlens on long-range near-field WPT, quantitatively confirming in simulation and measurement at 13- 16 MHz the conditions under which the superlens can enhance power transfer efficiency compared to the lens-less free-space system. [ABSTRACT FROM AUTHOR]

Published

2014

22. Digital quantum simulation of NMR experiments.

Author

Seetharam K, Biswas D, Noel C, Risinger A, Zhu D, Katz O, Chattopadhyay S, Cetina M, Monroe C, Demler E, and Sels D

Abstract

Simulations of nuclear magnetic resonance (NMR) experiments can be an important tool for extracting information about molecular structure and optimizing experimental protocols but are often intractable on classical computers for large molecules such as proteins and for protocols such as zero-field NMR. We demonstrate the first quantum simulation of an NMR spectrum, computing the zero-field spectrum of the methyl group of acetonitrile using four qubits of a trapped-ion quantum computer. We reduce the sampling cost of the quantum simulation by an order of magnitude using compressed sensing techniques. We show how the intrinsic decoherence of NMR systems may enable the zero-field simulation of classically hard molecules on relatively near-term quantum hardware and discuss how the experimentally demonstrated quantum algorithm can be used to efficiently simulate scientifically and technologically relevant solid-state NMR experiments on more mature devices. Our work opens a practical application for quantum computation.

Published

2023