Scientific Publications
Displaying 1 - 26 of 26
2022
Performance analysis of quantum repeaters enabled by deterministically generated photonic graph states
Zhan Y., P. Hilaire, E. Barnes, S. Economou, and S. Sun, Arxiv:2209.11430 (2022).
Noise Spectroscopy Without Dynamical Decoupling Pulses
Vezvaee A., N. Shitara, S. Sun, and A. Montoya-Castillo, Arxiv:2210.00386 (2022).
2021
Development of Quantum Interconnects (QuICs) for Next-Generation Information Technologies
Awschalom D., K. Berggren, H. Bernien, S. Bhave, L. Carr, P. Davids, S.E. Economou, D. Englund, A. Faraon, M.M. Fejer, and S. Guha, Prx Quantum 2, 017002 (2021).
Optimal two-photon excitation of bound states in non-Markovian waveguide QED
Trivedi R., D. Malz, S. Sun, S. Fan, and J. Vučković, Physical Review A 104, 013705 (2021).
2020
Deterministic Generation of Loss-Tolerant Photonic Cluster States with a Single Quantum Emitter
Zhan Y., and S. Sun, Physical Review Letters 125, 223601 (2020).
4H-silicon-carbide-on-insulator for integrated quantum and nonlinear photonics
Lukin D., C. Dory, M. Guidry, K. Yang, S. Mishra, R. Trivedi, M. Radulaski, S. Sun, D. Vercruysse, G. Ahn, and J. Vučković, Nature Photonics 14, 330-334 (2020).
Generation of Tin-Vacancy Centers in Diamond via Shallow Ion Implantation and Subsequent Diamond Overgrowth
Rugar A., H. Lu, C. Dory, S. Sun, P. McQuade, Z.-X. Shen, N. Melosh, and J. Vučković, Nano Letters 20, 1614-1619 (2020).
Single-photon nonlinear optics with a semiconductor quantum dot
Sun S., and K. Müller, in Semiconductors And Semimetals (Elsevier, 2020), pp. 387-416.
Spectrally reconfigurable quantum emitters enabled by optimized fast modulation
Lukin D.M., A.D. White, R. Trivedi, M.A. Guidry, N. Morioka, C. Babin, Ö.O. Soykal, J. Ul-Hassan, N.T. Son, T. Ohshima, and P.K. Vasireddy, Npj Quantum Information 6, 80 (2020).
Narrow-Linewidth Tin-Vacancy Centers in a Diamond Waveguide
Rugar A.E., C. Dory, S. Aghaeimeibodi, H. Lu, S. Sun, S.D. Mishra, Z.-X. Shen, N.A. Melosh, and J. Vučković, Acs Photonics 7, 2356-2361 (2020).
2019
Nanodiamond Integration with Photonic Devices
Radulaski M., J. Zhang, Y.-K. Tzeng, K. Lagoudakis, H. Ishiwata, C. Dory, K. Fischer, Y. Kelaita, S. Sun, P. Maurer, and K. Alassaad, Laser & Photonics Reviews 13, 1800316 (2019).
Characterization of optical and spin properties of single tin-vacancy centers in diamond nanopillars
Rugar A., C. Dory, S. Sun, and J. Vučković, Physical Review B 99, 205417 (2019).
Inverse-designed diamond photonics
Dory C., D. Vercruysse, K. Yang, N. Sapra, A. Rugar, S. Sun, D. Lukin, A. Piggott, J. Zhang, M. Radulaski, and K. Lagoudakis, Nature Communications 10, 3309 (2019).
A Spin–Photon Interface Using Charge-Tunable Quantum Dots Strongly Coupled to a Cavity
Luo Z., S. Sun, A. Karasahin, A.S. Bracker, S. Carter, M. Yakes, D. Gammon, and E. Waks, Nano Letters 19, 7072-7077 (2019).
2018
A single-photon switch and transistor enabled by a solid-state quantum memory
Sun S., H. Kim, Z. Luo, G. Solomon, and E. Waks, Science 361, 57-60 (2018).
Quantum dot single-photon sources with ultra-low multi-photon probability
Hanschke L., K. Fischer, S. Appel, D. Lukin, J. Wierzbowski, S. Sun, R. Trivedi, J. Vučković, J. Finley, and K. Müller, Npj Quantum Information 4, (2018).
Cavity-Enhanced Raman Emission from a Single Color Center in a Solid
Sun S., J. Zhang, K. Fischer, M. Burek, C. Dory, K. Lagoudakis, Y.-K. Tzeng, M. Radulaski, Y. Kelaita, A. Safavi-Naeini, and Z.-X. Shen, Physical Review Letters 121, (2018).
Pulsed coherent drive in the Jaynes-Cummings model
Fischer K., S. Sun, D. Lukin, Y. Kelaita, R. Trivedi, and J. Vučković, Physical Review A 98, (2018).
Cavity-Enhanced Optical Readout of a Single Solid-State Spin
Sun S., H. Kim, G. Solomon, and E. Waks, Physical Review Applied 9, (2018).
Strongly Cavity-Enhanced Spontaneous Emission from Silicon-Vacancy Centers in Diamond
Zhang J., S. Sun, M. Burek, C. Dory, Y.-K. Tzeng, K. Fischer, Y. Kelaita, K. Lagoudakis, M. Radulaski, Z.-X. Shen, and N. Melosh, Nano Letters 18, 1360-1365 (2018).
2017
Interfacing Single Quantum Dot Spins with Photons Using a Nanophotonic Cavity
Sun S., and E. Waks, in Quantum Dots For Quantum Information Technologies (Springer Link, 2017).
Complete coherent control of silicon vacancies in diamond nanopillars containing single defect centers
Zhang J., K. Lagoudakis, Y.-K. Tzeng, C. Dory, M. Radulaski, Y. Kelaita, K. Fischer, S. Sun, Z.-X. Shen, N. Melosh, and S. Chu, Optica 4, 1317 (2017).
2016
Single-shot optical readout of a quantum bit using cavity quantum electrodynamics
Sun S., and E. Waks, Physical Review A 94, (2016).
A quantum phase switch between a single solid-state spin and a photon
Sun S., H. Kim, G. Solomon, and E. Waks, Nature Nanotechnology 11, 539-544 (2016).
2014
Deterministic generation of entanglement between a quantum-dot spin and a photon
Sun S., and E. Waks, Physical Review A 90, (2014).
2013
Strain tuning of a quantum dot strongly coupled to a photonic crystal cavity
Sun S., H. Kim, G. Solomon, and E. Waks, Applied Physics Letters 103, 151102 (2013).