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14 results on '"Shojaee, Ezad"'

1. Constraints on Gaussian Error Channels and Measurements for Quantum Communication

Author

Kwiatkowski, Alex, Shojaee, Ezad, Agrawal, Sristy, Kyle, Akira, Rau, Curtis, Glancy, Scott, and Knill, Emanuel

Subjects
Quantum Physics
Abstract

Joint Gaussian measurements of two quantum systems can be used for quantum communication between remote parties, as in teleportation or entanglement swapping protocols. Many types of physical error sources throughout a protocol can be modeled by independent Gaussian error channels acting prior to measurement. In this work we study joint Gaussian measurements on two modes $\mathsf{A}$ and $\mathsf{B}$ that take place after independent single-mode Gaussian error channels, for example loss with parameters $l_\mathsf{A}$ and $l_\mathsf{B}$ followed by added noise with parameters $n_\mathsf{A}$ and $n_\mathsf{B}$. We show that, for any Gaussian measurement, if $l_\mathsf{A} + l_\mathsf{B} + n_\mathsf{A} + n_\mathsf{B} \geq 1$ then the effective total measurement is separable and unsuitable for teleportation or entanglement swapping of arbitrary input states. If this inequality is not satisfied then there exists a Gaussian measurement that remains inseparable. We extend the results and determine the set of pairs of single-mode Gaussian error channels that render all Gaussian measurements separable.

Published
2022
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2. Filter functions for the Glauber-Sudarshan $P$-function regularization

Author

Zartab, Mani, Shojaee, Ezad, and Rahimi-Keshari, Saleh

Subjects
Quantum Physics
Abstract

The phase-space quasi-probability distribution formalism for representing quantum states provides practical tools for various applications in quantum optics such as identifying the nonclassicality of quantum states. We study filter functions that are introduced to regularize the Glauber-Sudarshan $P$ function. We show that the quantum map associated with a filter function is completely positive and trace preserving and hence physically realizable if and only if the Fourier transform of this function is a probability density distribution. We also derive a lower bound on the fidelity between the input and output states of a physical quantum filtering map. Therefore, based on these results, we show that any quantum state can be approximated, to arbitrary accuracy, by a quantum state with a regular Glauber-Sudarshan $P$ function. We propose applications of our results for estimating the output state of an unknown quantum process and estimating the outcome probabilities of quantum measurements., Comment: 10 pages

Published
2022
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3. Entanglement Thresholds of Doubly-Parametric Quantum Transducers

Author

Rau, Curtis L., Kyle, Akira, Kwiatkowski, Alex, Shojaee, Ezad, Teufel, John D., Lehnert, Konrad W., and Dennis, Tasshi

Subjects
Quantum Physics
Abstract

Doubly-parametric quantum transducers, such as electro-opto-mechanical devices, are quickly approaching quantum operation as decoherence mechanisms such as thermal noise, loss, and limited cooperativities are improved. These devices show potential as the critical link between quantum information contained at frequencies as disparate as those in the optical and microwave domains, thus enabling applications such as long distance networking of superconducting quantum computers. However, the requirements on the operating parameters of the transducers necessary to achieve quantum operation have yet to be characterized. In this work we find simple, explicit expressions for the necessary and sufficient conditions under which doubly-parametric transducers in the resolved-sideband, steady-state limit are capable of entangling optical and microwave modes. Our analysis treats the transducer as a two-mode bosonic Gaussian channel capable of both beamsplitter-type and two-mode squeezing-type interactions between optical and microwave modes. For the beamsplitter-type interaction, we find parameter thresholds which distinguish regions of the channel's separability, capacity for bound entanglement, and capacity for distillable entanglement. By contrast, the two-mode squeezing-type interaction always produces distillable entanglement with no restrictions on temperature, cooperativities, or losses. Finally, we find the entanglement breaking conditions on the reduced one-mode upconversion and downconversion channels obtained by initializing the unused input with vacuum while ignoring the unused output. These differences between the entanglement thresholds of the beamsplitter-type and two-mode squeezing-type interactions are then important considerations in the construction of larger quantum networks that integrate multiple transducers., Comment: 12 pages, 5 figures

Published
2021
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4. Direct observation of deterministic macroscopic entanglement

Author

Kotler, Shlomi, Peterson, Gabriel A., Shojaee, Ezad, Lecocq, Florent, Cicak, Katarina, Kwiatkowski, Alex, Geller, Shawn, Glancy, Scott, Knill, Emanuel, Simmonds, Raymond W., Aumentado, José, and Teufel, John D.

Subjects
Quantum Physics
Abstract

Quantum entanglement of mechanical systems emerges when distinct objects move with such a high degree of correlation that they can no longer be described separately. Although quantum mechanics presumably applies to objects of all sizes, directly observing entanglement becomes challenging as masses increase, requiring measurement and control with a vanishingly small error. Here, using pulsed electromechanics, we deterministically entangle two mechanical drumheads with masses of 70 pg. Through nearly quantum-limited measurements of the position and momentum quadratures of both drums, we perform quantum state tomography and thereby directly observe entanglement. Such entangled macroscopic systems are uniquely poised to serve in fundamental tests of quantum mechanics, enable sensing beyond the standard quantum limit, and function as long-lived nodes of future quantum networks., Comment: 42 pages, 3 main figures, supplementary materials: text, 4 figures, 3 tables, 7 references

Published
2020
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5. Squeezing the angular momentum of an ensemble of complex multi-level atoms

Author

Hemmer, Daniel, Montano, Enrique, Baragiola, Ben Q., Norris, Leigh M., Shojaee, Ezad, Deutsch, Ivan H., and Jessen, Poul S.

Subjects
Quantum Physics, Physics - Atomic Physics
Abstract

Squeezing of collective atomic spins has been shown to improve the sensitivity of atomic clocks and magnetometers to levels significantly below the standard quantum limit. In most cases the requisite atom-atom entanglement has been generated by dispersive interaction with a quantized probe field, or by state dependent collisions in a quantum gas. Such experiments typically use complex multilevel atoms like Rb or Cs, with the relevant interactions designed so atoms behave like pseudo-spin-$1/2$ particles. We demonstrate the viability of spin squeezing for collective spins composed of the physical angular momenta of $\sim 10^6$ Cs atoms, each in an internal spin-4 hyperfine state. A peak metrological squeezing of $\gtrsim -5$dB was generated by quantum backaction from a dispersive quantum nondemolition (QND) measurement, implemented using a two-color optical probe that minimizes tensor light shifts without sacrificing measurement strength. Other significant developments include the successful application of composite pulse techniques for accurate dynamical control of the collective spin, enabled by broadband suppression of background magnetic fields inside a state-of-the-art magnetic shield. The absence of classical noise has allowed us to compare the observed quantum projection noise and squeezing to a theoretical model that properly accounts for both the relevant atomic physics and the spatial mode of the collective spin, finding good quantitative agreement and thereby validating its use in other contexts. Thus, our work sets the stage for experiments on quantum feedback, deterministic squeezing, closed-loop magnetometry, and new types of quantum simulation based on continuous QND measurement and feedback., Comment: 14 pages, 4 figures

Published
2018
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6. Optimal Pure-State Qubit Tomography via Sequential Weak Measurements

Author

Shojaee, Ezad, Jackson, Christopher S., Riofrio, Carlos A., Kalev, Amir, and Deutsch, Ivan H.

Subjects
Quantum Physics
Abstract

The spin-coherent-state positive-operator-valued-measure (POVM) is a fundamental measurement in quantum science, with applications including tomography, metrology, teleportation, benchmarking, and measurement of Husimi phase space probabilities. We prove that this POVM is achieved by collectively measuring the spin projection of an ensemble of qubits weakly and isotropically. We apply this in the context of optimal tomography of pure qubits. We show numerically that through a sequence of weak measurements of random directions of the collective spin component, sampled discretely or in a continuous measurement with random controls, one can approach the optimal bound., Comment: 5 pages, 2 figures

Published
2018
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10. Filter functions in quantum phase-space representations

Author

Zartab, Mani, Shojaee, Ezad, and Rahimi-Keshari, Saleh

Subjects
Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)
Abstract

Representation of quantum states in terms of phase-space quasiprobability distributions provides practical tools for identifying features such as the nonclassicality of quantum states. In this setting, filter functions are commonly used to regularize or smooth the phase-space quasiprobability distributions, in particular, the Glauber-Sudarshan $P$-function. We show that the quantum map associated with a filter function is completely positive and trace-preserving if and only if the Fourier transform of the filter function is a probability density distribution. In this case, filtering the quasiprobability distributions of a quantum state can be viewed as applying a random displacement operation on the quantum state according to the Fourier transform of the filter function. We derive a lower bound on the fidelity between the input and output states of a quantum filtering map. We illustrate several examples of filter functions corresponding to physical and nonphysical maps, in particular, a class of positive but not completely positive maps. We also discuss interesting applications of our results in estimating the output state of unknown quantum channels and estimating the outcome probabilities of quantum measurements., 7 pages

Published
2022

12. Direct observation of deterministic macroscopic entanglement

Author

Kotler, Shlomi, primary, Peterson, Gabriel A., additional, Shojaee, Ezad, additional, Lecocq, Florent, additional, Cicak, Katarina, additional, Kwiatkowski, Alex, additional, Geller, Shawn, additional, Glancy, Scott, additional, Knill, Emanuel, additional, Simmonds, Raymond W., additional, Aumentado, José, additional, and Teufel, John D., additional

Published
2021
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