Selected Publications

Notes:All posted papers are in the pdf format.
JV's pre-group publications are from 2002 and before.


Journals

2014

  1. Visible Photoluminescence from Cubic (3C) Silicon Carbide Microdisks Coupled to High Quality Whispering Gallery Modes, Marina Radulaski, Thomas M. Babinec, Kai Müller, Konstantinos G. Lagoudakis, Jingyuan Linda Zhang, Sonia Buckley, Yousif A. Kelaita, Kassem Alassaad, Gabriel Ferro, and Jelena Vuckovic, ACS Photonics (2014) (arXiv:1410.3800)
  2. Inverse design and implementation of a wavelength demultiplexing grating coupler, Alexander Y. Piggott, Jesse Lu, Thomas M. Babinec, Konstantinos G. Lagoudakis, Jan Petykiewicz, Jelena Vuckovic, Scientific Reports 4, 7210, (2014) (arXiv:1406.6185/a>)
    [
    Supplementary info]
    Featured in FastCompany, Stanford Engineering News, IFL Science, Phys.org, and Gizmodo.
  3. Multimode nanobeam cavities for nonlinear optics: high quality resonances separated by an octave, Sonia Buckley, Marina Radulaski, Jingyuan Linda Zhang, Jan Petykiewicz, Klaus Biermann, Jelena Vuckovic, Optics Express 22, 22, pp. 26498-26509 (2014) (arXiv:1408.6567)
  4. Nonlinear frequency conversion using high quality modes in GaAs nanobeam cavities, Sonia Buckley, Marina Radulaski, Jingyuan Linda Zhang, Jan Petykiewicz, Klaus Biermann, and Jelena Vuckovic, Optics Letters 39, 19 (2014) (arXiv:1407.1446)
  5. Hole-spin pumping and repumping in a p-type δ-doped InAs quantum dot, Konstantinos G. Lagoudakis, Kevin A. Fischer, Tomas Sarmiento, Kai Mueller, and Jelena Vuckovic, Physical Review B 90, 121402 (2014) (arXiv:1407.4411)
  6. Demonstration of weak optical pumping of a spin qubit in a site-controlled nanowire quantum dot, Konstantinos G. Lagoudakis, Peter L. McMahon, Shruti Puri, Kevin A. Fischer, Dan Dalacu, Philip J. Poole, Michael E. Reimer, Val Zwiller, Yoshihisa Yamamoto, and Jelena Vuckovic (arXiv:1409.4728)
  7. On-chip generation of indistinguishable photons using cavity quantum-electrodynamics, Kai Müller, Armand Rundquist, Kevin A. Fischer, Tomas Sarmiento, Konstantinos G. Lagoudakis, Yousif A. Kelaita, Carlos Sanchez Munoz, Elena del Valle, Fabrice P. Laussy, Jelena Vuckovic (arXiv:1408.5942)
  8. A carrier relaxation bottleneck probed in single InGaAs quantum dots using integrated superconducting single photon detectors, G. Reithmaier, F. Flassi, P. Hasch, S. Lichtmannecker, K. Mueller, J. Vuckovic, R. Gross, M. Kaniber, and J. J. Finley, Applied Physics Letters 105, 081107 (2014) (arXiv:1407.0593)
  9. Nonclassical higher-order photon correlations with a quantum dot strongly coupled to a photonic-crystal nanocavity, Armand Rundquist, Michal Bajcsy, Arka Majumdar, Tomas Sarmiento, Kevin Fischer, Konstantinos G. Lagoudakis, Sonia Buckley, Alexander Y. Piggott, and Jelena Vuckovic, Physical Review A 90, 023846 (2014)
  10. On-chip generation, routing and detection of quantum light, Günther Reithmaier, Michael Kaniber, Fabian Flassig, Stefan Lichtmannecker, Kai Müller, Alexander Andrejew, Jelena Vuckovic, Rudolf Gross, Jonathan Finley (arXiv:1408.2275)
  11. A Light-Matter Interface based on a Single InAs/GaAs Quantum Dot in a Nanometallic Cavity, Thomas M. Babinec, Yousif A. Kelaita, Kevin A. Fischer, Konstantinos G. Lagoudakis, Tomas Sarmiento, Armand Rundquist, Arka Majumdar, and Jelena Vuckovic (arXiv:1406.7050)
  12. Photo-oxidative tuning of individual and coupled GaAs Photonic Crystal Cavities, Alexander Y. Piggott, Konstantinos G. Lagoudakis, Tomas Sarmiento, Michal Bajcsy, and Jelena Vuckovic, Optics Express Vol. 22, 12, pp. 15017-15023 (2014)(arXiv:1401.6241)
  13. Second-Harmonic Generation in GaAs Photonic Crystal Cavities in (111)B and (001) Crystal Orientations, Sonia Buckley, Marina Radulaski, Jan Petykiewicz, Konstantinos G. Lagoudakis, Ju-Hyung Kang, Mark Brongersma, Klaus Biermann, and Jelena Vuckovic, ACS Photonics (2014) (arXiv:1402.3739)
  14. Control of two-dimensional excitonic light emission via photonic crystal, Sanfeng Wu, Sonia Buckley, Aaron M Jones, Jason S Ross, Nirmal J Ghimire, Jiaqiang Yan,, David G Mandrus, Wang Yao, Fariba Hatami, Jelena Vuckovic, Arka Majumdar, and Xiaodong Xu, 2D Materials 1, 011001 (2014) (arXiv:1311.6071)
  15. A direct measurement of the electronic structure of Si nanocrystals and its effect on optoelectronic properties, Waqas Mustafeez, Arka Majumdar, Jelena Vuckovic, and Alberto Salleo, Journal of Applied Physics 115, 103515 (2014)
  16. Quantum optics and cavity QED with quantum dots in photonic crystals, Jelena Vuckovic (arXiv:1402.2541)

2013

  1. Photonic Crystal Cavities in Cubic Polytype Silicon Carbide Films, Marina Radulaski, Thomas M. Babinec, Sonia Buckley, Armand Rundquist, J Provine, Kassem Alassaad, Gabriel Ferro, and Jelena Vuckovic, Optics Express Vol. 21, 26, pp. 32623-32629 (2013) (arXiv:1310.2222)
  2. Deterministically Charged Quantum Dots in Photonic Crystal Nanoresonators for Efficient Spin-Photon Interfaces, Konstantinos G. Lagoudakis, Kevin Fischer, Tomas Sarmiento, Arka Majumdar, Armand Rundquist, Jesse Lu, Michal Bajcsy, and Jelena Vuckovic, New Journal of Physics 15, 113056 (2013) (arXiv:1308.4463)
  3. Second Harmonic Generation in Photonic Crystal Cavities in (111)-Oriented GaAs, Sonia Buckley, Marina Radulaski, Klaus Biermann, and Jelena Vuckovic, Applied Physics Letters 103, 211117 (2013) (arXiv:1308.6051)
  4. Graphene for Tunable Nanophotonic Resonators, Arka Majumdar, Jonghwan Kim, Jelena Vuckovic, and Feng Wang, IEEE Journal of Selected Topics in Quantum Electonics Vol. 20, 1 (2013).
  5. Non-classical three-photon correlations with a quantum dot strongly coupled to a photonic-crystal nanocavity, Michal Bajcsy, Armand Rundquist, Arka Majumdar, Tomas Sarmiento, Kevin Fischer, Konstantinos G. Lagoudakis, Sonia Buckley, and Jelena Vuckovic (arXiv:1307.3601)
  6. Proposed Coupling of an Electron Spin in a Semiconductor Quantum Dot to a Nanosize Optical Cavity, Arka Majumdar, Per Kaer, Michal Bajcsy, Erik D. Kim, Konstantinos G. Lagoudakis, Armand Rundquist, and Jelena Vuckovic, Physical Review Letters 111, 027402 (2013) (arXiv:1211.5571)
  7. Strain-induced pseudoheterostructure nanowires confining carriers at room temperature with nanoscale-tunable band profiles, Donguk Nam, David S. Sukhdeo, Ju-Hyung Kang, Jan Petykiewicz, Jae Hyung Lee, Woo Shik Jung, Jelena Vuckovic, Mark L. Brongersma, and Krishna C. Saraswat, Nano Letters (2013)
  8. Nanophotonic computational design, Jesse Lu and Jelena Vuckovic, Optics Express Vol. 21, 11, pp. 13351-13367 (2013) (arXiv:1303.5823)
  9. Single-cell photonic nanocavity probes, Gary Shambat, Sri Rajasekhar Kothapalli, J Provine, Tomas Sarmiento, James Harris, Sanjiv S. Gambhir, and Jelena Vuckovic, Nano Letters 13, 11 pp 4999-5005 (2013)
    Highlights: [Video]
    Cover article, November 2013.
    Featured in Stanford Engineering News, Science Daily, Photonics.com, Compound Semiconductor, PhysOrg, Stanford Report, Popular Science, Laser Focus World, and IEEE Spectrum.
  10. Photon blockade with a four-level quantum emitter coupled to a photonic-crystal nanocavity, Michal Bajcsy, Arka Majumdar, Armand Rundquist and Jelena Vuckovic, New Journal of Physics 15, 025014 (2013) (arXiv:1209.5449)
  11. Electrical Control of Silicon Photonic Crystal Cavity by Graphene, Arka Majumdar, Jonghwan Kim, Jelena Vuckovic and Feng Wang, Nano Letters (2013) (arXiv:1210.6716)

2012

  1. Design and analysis of photonic crystal coupled cavity arrays for quantum simulation, Arka Majumdar, Armand Rundquist, Michal Bajcsy, Vaishno D. Dasika, Seth R. Bank, and Jelena Vuckovic, Physical Review B 86, 19 (2012) (arXiv:1209.3076)
  2. Engineered Quantum Dot Single Photon Sources, Sonia Buckley, Kelley Rivoire, and Jelena Vuckovic, Reports on Progress in Physics, 75, 126503 (2012) (arXiv:1210.1234)
  3. Quasiresonant Excitation of InP/InGaP Quantum Dots Using Second Harmonic Generated in a Photonic Crystal Cavity, Sonia Buckley, Kelley Rivoire, Fariba Hatami, and Jelena Vuckovic, Applied Physics Letters 101, 161116 (2012) (arXiv:1210.1247)
  4. Electrically driven photonic crystal nanocavity devices, Gary Shambat, Bryan Ellis, Jan Petykiewicz, Marie A. Mayer, Arka Majumdar, Tomas Sarmiento, James Harris, Eugene E. Haller, and Jelena Vuckovic, IEEE Journal of Selected Topics in Quantum Electronics Vol 16, pp. 1700-1710 (2012) (arXiv:1201.0964)
  5. All Optical Switching With a Single Quantum Dot Strongly Coupled to a Photonic Crystal Cavity, Arka Majumdar, Michal Bajcsy, Dirk Englund, and Jelena Vuckovic, IEEE Journal of Selected Topics in Quantum Electronics Vol 18, pp. 1812-1817 (2012)
  6. Cavity Quantum Electrodynamics with a Single Quantum Dot Coupled to a Photonic Molecule, Arka Majumdar, Armand Rundquist, Michal Bajcsy, and Jelena Vuckovic, Physical Review B 86, 045315 (2012) (arXiv:1201.6244)
  7. Objective-First Nanophotonic Design, Jesse Lu and Jelena Vuckovic, (arXiv:1207.2499)
  8. Electrical properties of GaAs photonic crystal cavity lateral p-i-n diodes, Jan Petykiewicz, Gary Shambat, Bryan Ellis, and Jelena Vuckovic, Applied Physics Letters 101, 011104 (2012).
  9. A photonic crystal cavity-optical fiber tip nanoparticle sensor for biomedical applications, Gary Shambat, Sri Rajasekhar Kothapalli, Aman Khurana, J. Provine, Tomas Sarmiento, Kai Cheng, Zhen Cheng, James Harris, Heike Daldrup-Link, Sanjiv Sam Gambhir, and Jelena Vuckovic, Applied Physics Letters 100, 213702 (2012). (arXiv:1204.0818)
  10. Loss-enabled sub-Poissonian light generation in a bimodal nanocavity, Arka Majumdar, Michal Bajcsy, Armand Rundquist, and Jelena Vuckovic, Physical Review Letters 108, 183601 (2012). (arXiv:1111.6326)
  11. Phonon-mediated coupling between quantum dots through an off-resonant microcavity, Arka Majumdar, Michal Bajcsy, Armand Rundquist, Erik Kim, and Jelena Vuckovic, Physical Review B 85, 195301 (2012). (arXiv:1111.7097)
  12. Probing the ladder of dressed states and nonclassical light generation in quantum-dot-cavity QED, Arka Majumdar, Michal Bajcsy, Jelena Vuckovic, Physical Review A 85, 041801 (2012). (arXiv:1106.1926)
  13. Objective-first design of high-efficiency, small-footprint couplers between arbitrary nanophotonic waveguide modes, Jesse Lu and Jelena Vuckovic, Optics Express 20, pp. 7221-7236 (2012).
  14. Nonlinear Temporal Dynamics of Strongly Coupled Quantum Dot-Cavity System, Arka Majumdar, Dirk Englund, Michal Bajcsy, and Jelena Vuckovic, Physical Review A 85, 033802 (2012). (arXiv:1110.4538)
  15. Ultrafast Photon-Photon Interaction in a Strongly Coupled Quantum Dot-Cavity System, Dirk Englund✝, Arka Majumdar✝, Michal Bajcsy, Andrei Faraon, Pierre Petroff, and Jelena Vuckovic, Physical Review Letters 108, 093604 (2012). (arXiv:1107.2956)
  16. Electrically driven photonic crystal cavities yield low-power optoelectronic devices, Gary Shambat, Bryan Ellis, Jan Petykiewicz and Jelena Vuckovic, SPIE Newsroom (2012).
  17. Photoluminescence from In0.5Ga0.5As/GaP quantum dots coupled to photonic crystal cavities, Kelley Rivoire, Sonia Buckley, Yuncheng Song, Minjoo Larry Lee, and Jelena Vuckovic, Physical Review B 85, 045319 (2012). (arXiv:1201.1258)
  18. Bichromatic driving of a solid-state cavity quantum electrodynamics system, Alexander Papageorge, Arka Majumdar, Erik D Kim and Jelena Vuckovic, New Journal of Physics 14, 013028 (2012). (arXiv:1104.0898)

2011

  1. Off-resonant coupling between a single quantum dot and a nanobeam photonic crystal cavity, Armand Rundquist, Arka Majumdar, and Jelena Vuckovic, Applied Physics Letters 99, 251907 (2011). (arXiv:1110:0878)
  2. Ultrafast direct modulation of a single-mode photonic crystal nanocavity light-emitting diode, Gary Shambat, Bryan Ellis, Arka Majumdar, Jan Petykiewicz, Marie A. Mayer, Tomas Sarmiento, James Harris, Eugene E. Haller and Jelena Vuckovic, Nature Communications Vol. 2, 593 (2011).
    Highlights: #6 most-emailed and #8 most-downloaded in Nature Communications in December 2011.
    Featured in Stanford Report, Stanford Engineering, Science Codex, PhysOrg, San Francisco Chronicle, Laser Focus World, Science Daily, Wired, and Forbes.
  3. Optical fiber tips functionalized with semiconductor photonic crystal cavities, Gary Shambat, J Provine, Kelley Rivoire, Tomas Sarmiento, James Harris, and Jelena Vuckovic, Applied Physics Letters 99, 191102 (2011). (arXiv:1109.4961)
    Highlights: In the top 20 most-downloaded papers in Applied Physics Letters in December 2011
  4. The effect of photo-generated carriers on the spectral diffusion of a quantum dot coupled to a photonic crystal cavity, Arka Majumdar, Erik D. Kim, and Jelena Vuckovic, Physical Review B 84, 195304 (2011). (arXiv:1107.4758)
  5. Multiply resonant photonic crystal nanocavities for nonlinear frequency conversion, Kelley Rivoire, Sonia Buckley, and Jelena Vuckovic, Optics Express 19, pp. 22198-22207 (2011).
  6. Fabrication and Analysis of Epitaxially Grown Ge _{1-x} Sn _x Microdisk Resonator With 20-nm Free-Spectral Range, Seongjae Cho, Robert Chen, Sukmo Koo, Gary Shambat, Hai Lin, Namkyoo Park, Jelena Vuckovic, Theodore I. Kamins, Byung-Gook Park, and James S. Harris, IEEE Photonics Technology Letters 23, 1535 (2011).
  7. Probing of single quantum dot dressed states via an off-resonant cavity, Arka Majumdar, Alexander Papageorge, Erik D. Kim, Michal Bajcsy, Hyochul Kim, Pierre Petrof, and Jelena Vuckovic, Physical Review B 84, 085310 (2011). (arXiv:1103.2716)
  8. Phonon mediated off-resonant quantum dot-cavity coupling under resonant excitation of the quantum dot, Arka Majumdar, Erik D. Kim, Yiyang Gong, Michal Bajcsy, and Jelena Vuckovic, Physical Review B 84, 085309 (2011). (arXiv:1012.3125).
    [Erratum], Arka Majumdar, Erik D. Kim, Yiyang Gong, Michal Bajcsy, and Jelena Vuckovic Physical Review B 87, 079907(E) (2013)
  9. Nanobeam Photonic Crystal Cavity Light-Emitting Diodes, Gary Shambat, Bryan Ellis, Jan Petykiewicz, Marie A. Mayer, Tomas Sarmiento, James Harris, Eugene E. Haller, and Jelena Vuckovic, Applied Physics Letters 99, 071105 (2011). (arXiv:1106.5803)
    Highlights: #10 downloaded article in Applied Physics Letters in August 2011.
  10. Multiply resonant high quality photonic crystal nanocavities, Kelley Rivoire, Sonia Buckley, and Jelena Vuckovic, Applied Physics Letters, 99, 013114 (2011). (arXiv:1105.6134)
  11. Integrated quantum optical networks based on quantum dots and photonic crystals, Andrei Faraon, Arka Majumdar, Dirk Englund, Erik Kim, Michal Bajcsy, and Jelena Vuckovic, New Journal of Physics, Special issue on Integrated Quantum Photonics, Vol. 13, pp. 055025 (2011)
  12. Second harmonic generation in GaP photonic crystal waveguides, Kelley Rivoire, Sonia Buckley, Fariba Hatami, and Jelena Vuckovic, Applied Physics Letters 98, 263113 (2011). (arXiv:1106.0046)
  13. Cavity-enhanced direct band electroluminescence near 1550 nm from germanium microdisk resonator diode on silicon , Szu-Lin Cheng, Gary Shambat, Jesse Lu, Hyun-Yong Yu, Krishna Saraswat, Theodore I. Kamins, Jelena Vuckovic, and Yoshio Nishi, Applied Physics Letters, 98, 211101 (2011).
  14. Inverse design of a three-dimensional nanophotonic resonator, Jesse Lu, Stephen Boyd, and Jelena Vuckovic, Optics Express, 19, pp. 10563-10570 (2011).
    Highlights: #1 downloaded article and Image of the Week on Optics Express in May 2011.
  15. Ultralow-threshold electrically pumped quantum-dot photonic-crystal nanocavity laser, Bryan Ellis, Marie Mayer, Gary Shambat, Tomas Sarmiento, Eugene Haller, James S. Harris, and Jelena Vuckovic, Nature Photonics, 5, pp. 297-300 (2011).
    Highlights: #1 downloaded article on Nature Photonics in May 2011
    Also featured in PhysOrg, Stanford Report, Stanford Daily, and Laser Focus World.
  16. Ultra-low power fiber-coupled gallium arsenide photonic crytsal cavity electro-optic modulator, Gary Shambat, Bryan Ellis, Marie Mayer, Arka Majumdar, Eugene Haller, and Jelena Vuckovic, Optics Express, 19, pp. 7530-7536 (2011).
  17. Fast quantum dot single photon source triggered at telecommunications wavelength, Kelley Rivoire, Sonia Buckley, Arka Majumdar, Hyochul Kim, Pierre Petroff, and Jelena Vuckovic, Applied Physics Letters, 98, 083105 (2011) (arXiv:1012.0300)
  18. Low Power Resonant Optical Excitation of an Optomechanical Cavity, Yiyang Gong, Armand Rundquist, Arka Majumdar, and Jelena Vuckovic, Optics Express 19, pp. 1429-1440 (2011) (arXiv:1011.3622)
  19. Strong enhancement of direct transition photoluminescene with highly tensile-strained Ge grown by molecular beam epitaxy, Yijie Huo, Hai Lin, Robert Chen, Maria Makarova, Yiwen Rong, Mingyang Li, Theodore I. Kamins, Jelena Vuckovic, and James S. Harris, Applied Physics Letters 98, 011111 (2011).

2010

  1. Direct band Ge photoluminescence near 1.6 um coupled to Ge-on-Si microdisk resonators, Gary Shambat, Szu-Lin Cheng, Jesse Lu, Yoshio Nishi, and Jelena Vuckovic Applied Physics Letters 97, 241102 (2010).
  2. Deterministic coupling of a single nitrogen vacancy center to a photonic crystal cavity, Dirk Englund, Brendan Shields, Kelley Rivoire, Fariba Hatami, Jelena Vuckovic, Hongkun Park, and Mikhail D. Lukin, Nano Letters , 10, pp. 3922-3926 (2010) (arXiv:1005.2204)
  3. Differential reflection spectrocopy of a single quantum dot strongly coupled to a photonic crystal cavity , Erik Kim, Arka Majumdar, Hyochul Kim, Pierre Petroff, and Jelena Vuckovic Applied Physics Letters 97, 053111 (2010).
  4. Proposal for high-speed and high-fidelity electron-spin initialization in a negatively charged quantum dot coupled to a microcavity in a weak external magnetic field, Arka Majumdar, Ziliang Lin, Andrei Faraon, and Jelena Vuckovic, Phys. Rev. A, 82, 022301 (2010). (arXiv:0907.3187)
  5. Sum-frequency generation in doubly resonant GaP photonic crystal nanocavities , Kelley Rivoire, Ziliang Lin, Fariba Hatami, and Jelena Vuckovic, Applied Physics Letters, 97, 043103 (2010).
  6. Analysis of the Purcell effect in photonic and plasmonic crystals with losses, Hideo Iwase, Dirk Englund, and Jelena Vuckovic, Optics Express, 18, pp. 16546-16560 (2010).
  7. Linewidth broadening of a quantum dot coupled to an off-resonant cavity, Arka Majumdar, Andrei Faraon, Erik Kim, Dirk Englund, Hyochul Kim, Pierre Petroff, and Jelena Vuckovic, PRB, 82, 045306 (arXiv:1003.2350)
  8. Photoluminescence from silicon dioxide photonic crystal cavities with embedded silicon nanocrystals, Yiyang Gong, Satoshi Ishikawa, Szu-Lin Cheng, Marika Gunji, Yoshio Nishi, and Jelena Vuckovic, Physical Review B , Vol. 81, 235317 (2010).
    Highlights: Featured as an editor's choice article
    Also spotlighted by the APS
  9. Observation of transparency of erbium-doped silicon nitride in photonic crystal nanobeam cavities, Yiyang Gong, Maria Makarova, Selcuk Yerci, Rui Li, Martin J. Stevens, Burm Baek, Sae Woo Nam, Luca Del Negro, and Jelena Vuckovic, Optics Express, Vol 18, pp. 13863-13873 (2010).
  10. Tunable-wavelength second harmonic generation from GaP photonic crystal cavities coupled to fiber tapers, Gary Shambat, Kelley Rivoire, Jesse Lu, Fariba Hatami, and Jelena Vuckovic, Optics Express, Vol 18, pp. 12176-12184 (2010).
  11. Electrically pumped photonic crystal nanocavity light sources using a laterally doped p-i-n junction, Bryan Ellis, Tomas Sarmiento, Marie Mayer, Bingyang Zhang, James Harris, Eugene Haller, and Jelena Vuckovic, Applied Physics Letters, Vol 96, 181103 (2010).
    Highlights: One of the most downloaded articles in Applied Physics Letters in May 2010
  12. Nanobeam photonic crystal cavity quantum dot laser, Yiyang Gong, Bryan Ellis, Gary Shambat, Tomas Sarmiento, James S. Harris, and Jelena Vuckovic, Optics Express , Vol 18, pp. 8781-8789 (2010).
  13. Generation of nonclassical states of light via photon blockade in optical nanocavities, Andrei Faraon, Arka Majumdar, and Jelena Vuckovic, Phys. Rev. A, Vol 81, 033838 (2010). (arXiv:0908.4303)
  14. Coupled fiber taper extraction of 1.53 um photoluminescence from erbium doped silicon nitride photonic crystal cavities, Gary Shambat, Yiyang Gong, Jesse Lu, Selcuk Yerci, Rui Li, Luca Dal Negro, and Jelena Vuckovic, Optics Express, Vol 18, pp. 5964-5973 (2010) (arXiv:1001.0430)
  15. Resonant excitation of a quantum dot strongly coupled to a photonic crystal nanocavity, Dirk Englund, Arka Majumdar, Andrei Faraon, Mitsuru Toishi, Nick Stoltz, Pierre Petroff, and Jelena Vuckovic, Physical Review Letters , Vol 104, 073904 (2010)
  16. Theory of Electro-optic Modulation via a Quantum Dot Coupled to a Nano-resonator, Arka Majumdar, Nicolas Manquest, Andrei Faraon, Jelena Vuckovic, Optics Express, Vol 18, pp. 3974-3984 (2010) (arXiv:0911.5207)
  17. Photonic Crystal and Plasmonic Silicon-Based Light Sources, Maria Makarova, Yiyang Gong, Szu-Lin Cheng, Yoshio Nishi, Selcuk Yerci, Rui Li, Luca dal Negro, Jelena Vuckovic, IEEE Journal of Selected Topics in Quantum Electronics, Vol 16, pp. 132-140 (2010)
  18. Inverse design of nanophotonic structures using complementary convex optimization, Jesse Lu, Jelena Vuckovic, Optics Express, Vol 18, pp. 3793-3804 (2010) (arXiv:0912.4425)
  19. Photonic crystal cavities in silicon dioxide, Yiyang Gong, Jelena Vuckovic, Applied Physics Letters, Vol 96, 031107 (2010)
    Highlights: One of the most downloaded articles in Applied Physics Letters in January 2010
  20. Linewidth narrowing and Purcell enhancement in photonic crystal cavities on an Er-doped silicon nitride platform, Yiyang Gong, Maria Makarova, Selcuk Yerci, Rui Li, Martin J. Stevens, Burm Baek, Sae Woo Nam, Robert H. Hadfield, Sander N. Dorenbos, Val Zwiller, Jelena Vuckovic, Luca dal Negro, Optics Express, Vol 18, pp. 2601-2612 (2010)
  21. Enhanced two-photon processes in single quantum dots inside photonic crystal nanocavities, Ziliang Lin, Jelena Vuckovic, Physical Review B, Vol 81, 035301 (2010) (arXiv:0905.4945)
  22. Fast Electrical Control of a Quantum Dot Strongly Coupled to a Photonic Crystal Cavity, Andrei Faraon, Arka Majumdar, Hyochul Kim, Pierre Petroff, Jelena Vuckovic, Physical Review Letters, Vol 104, 047402 (2010) (arXiv:0906.0751)
    Highlights: Featured in Laser focus world

2009

  1. Photonic Quantum Technologies, Jeremy O'Brien, Akira Furusawa, Jelena Vuckovic, Nature Photonics, Vol 3, 687-695 (2009)
  2. Second harmonic generation in gallium phosphide photonic crystal nanocavities with ultralow continuous wave pump power, Kelley Rivoire, Ziliang Lin, Fariba Hatami, W. Ted Masselink, Jelena Vuckovic, Optics Express, Vol 17, pp 22609-22615 (2009) (arXiv:0910.4757)
  3. Enhanced Light Emission from Erbium Doped Silicon Nitride in Plasmonic Metal-Insulator-Metal Structures, Yiyang Gong, Selcuk Yerci, Rui Li, Luca Dal Negro, Jelena Vuckovic, Optics Express, Vol 17, pp 18651-18658 (2009) (arXiv:0908.3901)
  4. An optical modulator based on a single strongly coupled quantum dot - cavity system in a p-i-n junction, Dirk Englund, Andrei Faraon, Arka Majumdar, Nick Stoltz, Pierre Petroff, Jelena Vuckovic, Optics Express, Vol 17, pp 18651-18658 (2009)
  5. Lithographic Positioning of Fluorescent Molecules on High-Q Photonic Crystal Cavities, Kelley Rivoire, Anika Kinkhabwala, Fariba Hatami, W. Ted Masselink, Yuri Avlasevich, Klaus Muellen, W.E. Moerner, Jelena Vuckovic, Applied Physics Letters, Vol 95, 123113 (2009)
  6. Electrically controlled modulation in a photonic crystal nanocavity, Dirk Englund, Bryan Ellis, Elizabeth Edwards, Tomas Sarmiento, James S. Harris, David A.B. Miller, Jelena Vuckovic, Optics Express, Vol 17, pp 15409-15419 (2009), (arXiv:0905.1376)
  7. High-brightness single photon source from a quantum dot in a directional-emission nanocavity, Mitsuru Toishi, Dirk Englund, Andrei Faraon, Jelena Vuckovic, Optics Express, Vol 17, pp 14618-14626 (2009), (arXiv:0904.1262)
  8. Local temperature control of photonic crystal devices via micron-scale electrical heaters, Andrei Faraon, Jelena Vuckovic, Applied Physics Letters, Vol 95, 043102 (2009), (arXiv:0904.4224)
  9. Room temperature 1.6 um electroluminescence from Ge light emitting diode on Si substrate, Szu-Lin Cheng, Jesse Lu, Gary Shambat, Hyun-Yong Yu, Krishna Saraswat, Jelena Vuckovic, Yoshio Nishi, Optics Express, Vol 17, pp 10019-10024 (2009)
    Highlights: Featured on Slashdot, in Stanford School of Engineering press release, and by Laser Focus World
  10. Single photon nonlinear optics on photonic crystal chips, Dirk Englund, Andrei Faraon, Ilya Fushman, Jelena Vuckovic, SPIE Newsroom (2009)
  11. Time-resolved lasing action from single and coupled photonic crystal nanocavity array lasers emitting in the telecom-band, Dirk Englund, Hatice, Altug, Jelena Vuckovic, Journal of Applied Physics, Vol 105, 093110 (2009), (arXiv:0810.2287)
  12. Coherent excitation of a strongly coupled quantum dot-cavity system, Dirk Englund, Arka Majumdar, Andrei Faraon, Mitsuru Toishi, Nick Stoltz, Pierre Petroff, Jelena Vuckovic, (arXiv:0902.2428)
  13. Quantum dots in photonic crystals: From quantum information processing to single photon nonlinear optics, Dirk Englund, Ilya Fushman, Andrei Faraon, Jelena Vuckovic, Photonics and Nanostructures - Fundamentals and Applications, Volume 7, Issue 1 (2009)
  14. Plasmonic Enhancement of Emission from Si-nanocrystals, Yiyang Gong, Jesse Lu, Szu-Lin Cheng, Yoshio Nishi, Jelena Vuckovic, Applied Physics Letters, Vol 94, article 013106 (2009) (arXiv:0810.4747)

2008

  1. Dipole induced transparency in waveguide coupled photonic crystal cavities, Andrei Faraon, Ilya Fushman, Dirk Englund, Nick Stoltz, Pierre Petroff, Jelena Vuckovic, Optics Express, Vol 16, pp 12154-12162 (2008)
  2. Gallium Phosphide Photonic Crystal Nanocavities in the Visible, Kelley Rivoire, Andrei Faraon, Jelena Vuckovic, Applied Physics Letters, Vol 93, article 063103 (2008) (arXiv:0807.2623)
  3. Ultrafast photonic crystal lasers, Dirk Englund, Hatice Altug, Bryan Ellis, and Jelena Vuckovic, Laser and Photonics Reviews, Volume 2, No. 4, pp 264-274 (2008)
  4. Probing the interaction between a single quantum dot and a photonic crystal cavity, Ilya Fushman, Dirk Englund, Andrei Faraon, Jelena Vuckovic, Physica Status Solidi c , Vol 5, No. 9, pp 2808-2815 (2008)
  5. Controlled Phase Shifts with a Single Quantum Dot, Ilya Fushman, Dirk Englund, Andrei Faraon, Nick Stoltz, Pierre Petroff, Jelena Vuckovic, Science, vol. 320, number 5877, pp. 769-772 (2008)
    Highlights: See also articles by Stanford Report, CompoundSemi News, Technology Research News, photonics.com, Semiconductor International, physorg.com,
  6. Quantum information processing on photonic crystal chips, Dirk Englund, Andrei Faraon, Ilya Fushman, Jelena Vuckovic, SPIE Newsroom (2008)
  7. Enhanced light emission in photonic crystal nanocavities with Erbium-doped silicon nanocrystals, Maria Makarova, Vanessa Sih, Joe Warga, Rui Li, Luca dal Negro, Jelena Vuckovic, Applied Physics Letters, Vol. 92, article 161107 (2008), Erratum
  8. Coherent generation of nonclassical light on a chip via photon-induced tunneling and blockade, Andrei Faraon, Ilya Fushman, Dirk Englund, Nick Stoltz, Pierre Petroff, Jelena Vuckovic, Nature Physics, Vol. 4, pp. 859-863 (2008) (arXiv:0804.2740)
  9. Local Tuning of Photonic Crystal Cavities Using Chalcogenide Glasses Andrei Faraon, Dirk Englund, Douglas Bulla, Barry Luther-Davies, Benjamin J. Eggleton, Nick Stoltz, Pierre Petroff, Jelena Vuckovic, Applied Physics Letters, Vol 92, article 043123 (2008) (arXiv:0711.0772)
  10. Spontaneous Emission Control in High-Extraction Efficiency Plasmonic Crystals, Hideo Iwase, Dirk Englund, Jelena Vuckovic, Optics Express, Vol 16, pp 426-434 (2008) (arXiv:0711.4879)

2007

  1. Controlling Cavity Reflectivity With a Single Quantum Dot, Dirk Englund, Andrei Faraon, Ilya Fushman, Nick Stoltz, Pierre Petroff, Jelena Vuckovic, Nature, vol. 450, number 7171, pp. 857-861 (2007)
    Highlights: See also stories by Stanford Report, optics.org
  2. Efficient Terahertz Room-Temperature Photonic Crystal Nanocavity Laser, Dirk Englund, Hatice Altug, Ilya Fushman, and Jelena Vuckovic, Applied Physics Letters, Vol 91, article 071126 (2007) (arXiv:0705.0537v1)
    Highlights: Featured in Laser Focus World October 2007 issue.
  3. Genetic Optimization of Photonic Bandgap Structures, Joel Goh, Ilya Fushman, Dirk Englund, Jelena Vuckovic, Optics Express, Vol 15, pp. 8218-8230 (2007) (arXiv:0704.0181v1)
  4. Local Quantum Dot Tuning on Photonic Crystal Chips, Andrei Faraon, Dirk Englund, Ilya Fushman, Nick Stoltz, Pierre Petroff, Jelena Vuckovic, Applied Physics Letters, Vol 90, article 213110 (2007) (arXiv:quant-ph/0703265)
    Highlights: Highlighted by Science Magazine, Vol. 316, p1395, June 8, 2007
  5. Low-Threshold Surface-Passivated Photonic Crystal Nanocavity Laser, Dirk Englund, Jelena Vuckovic, and Hatice Altug, Applied Physics Letters, Vol 91, article 071124 (2007) (arXiv:quant-ph/0703198)
  6. Analysis of a Quantum Nondemolition Measurement Scheme Based on Kerr Nonlinearity in Photonic Crystal Waveguides, Ilya Fushman and Jelena Vuckovic, Optics Express, Vol. 15, pp. 5559-5571 (2007) (arXiv:quant-ph/0603150)
  7. Dynamics of Quantum Dot Photonic Crystal Lasers, Bryan Ellis, Ilya Fushman, Dirk Englund, Bingyang Zhang, Yoshihisa Yamamoto, and Jelena Vuckovic, Applied Physics Letters, vol 90, article 151102 (2007) (arXiv:quant-ph/0703067)
    Highlights:One of the most downloaded research article from Applied Physics Letters in April 2007.
  8. Ultra Fast Nonlinear Optical Tuning of Photonic Crystal Cavities, Ilya Fushman, Edo Waks, Dirk Englund, Nick Stoltz, Pierre Petroff, and Jelena Vuckovic, Applied Physics Letters, vol. 90, article 091118 (2007) (arXiv:physics/0611303)
    Highlights: highlighted in Nature Photonics, April 2007, pp. 203
  9. Design of plasmon cavities for solid-state cavity quantum electrodynamics applications, Yiyang Gong and Jelena Vuckovic, Applied Physics Letters , vol. 90, article 033113 (2007) (arXiv:quant-ph/0609169)
  10. Efficient photonic crystal cavity-waveguide couplers , Andrei Faraon, Dirk Englund, Ilya Fushman, Jelena Vuckovic, Edo Waks,Applied Physics Letters, vol. 90, article 073102 (2007) (arXiv:physics/0610105)
    Highlights: One of the most downloaded articles from Applied Physics Letters in February 2007.
  11. Generation and Transfer of Single Photons on a Photonic Crystal Chip, Dirk Englund, Andrei Faraon, Bingyang Zhang, Yoshihisa Yamamoto, and Jelena Vuckovic, Optics Express, Vol. 15, pp. 5550-5558 (2007) (arXiv:quant-ph/0609053)

2006

  1. Silicon based photonic crystal nanocavity light emitters, Maria Makarova, Jelena Vuckovic, Hiroyuki Sanda, Yoshio Nishi, Applied Physics Letters, vol. 89, article 221101 (2006) (arXiv:physics/0609060)
    Highlights:The most downloaded research article from Applied Physics Letters in December 2006. Featured in Laser Focus World October 2007 issue.
  2. Patterned femtosecond laser excitation of terahertz leaky modes in GaAs photonic crystals, Nathan Jukam, Ilya Fushman, Cristo Yee, Jelena Vuckovic, and Mark S. Sherwin, Applied Physics Letters, vol. 89, 241112 (2006)
  3. Ultra-fast Photonic Crystal Nanolasers, Hatice Altug, Dirk Englund, and Jelena Vuckovic, Nature Physics , vol. 2, pp. 484-488 (July 2006)
    Highlights: Also featured as the cover story in this issue of Nature Physics and highlighted in Nature Photonics and Laser Focus World December 2006 issue, and again in Laser Focus World October 2007 issue.
  4. Dipole Induced Transparency in drop filter cavity-waveguide systems, Edo Waks and Jelena Vuckovic, Physical Review Letters,vol. 96, article 153601 (2006) (arXiv:quant-ph/0510228), Erratum
  5. A direct analysis of photonic nanostructures, Dirk Englund and Jelena Vuckovic, Optics Express, vol. 14, pp. 3472-3483 (2006)
  6. Dispersive properties and giant Kerr non-linearities in Dipole Induced Transparency, Edo Waks and Jelena Vuckovic,Physical Review A, vol. 73, article 041803(R) (2006)arXiv:quant-ph/0511205
  7. Two-Dimensional Porous Silicon Photonic Crystal Light Emitters, Maria Makarova, Jelena Vuckovic, Hiroyuki Sanda, Yoshio Nishi (arXiv:physics/0509178)
  8. Generation and manipulation of nonclassical light using photonic crystals, Jelena Vuckovic, Dirk Englund, David Fattal, Edo Waks, and Yoshihisa Yamamoto, Physica E, vol. 31, No. 2 (2006) (arXiv:quant-ph/0507273)
  9. Photonic Crystal Nanocavity Arrays, Hatice Altug and Jelena Vuckovic, Invited article for IEEE LEOS Newsletter, vol. 20, No. 2, pp. 4-11, April 2006
    Highlights: Also featured as the cover story of this IEEE LEOS Newsletter

2005

  1. Photonic crystal nanocavity array laser, Hatice Altug and Jelena Vuckovic, Optics Express, vol. 13, No. 22, pp. 8819-8828 (2005)
    Highlights: See also the Stanford Report story,Laser Focus World article, and Photonics Spectra article.
  2. Coupling of Pb quantum dots to photonic crystal cavities at room temperature, Ilya Fushman, Dirk Englund, and Jelena Vuckovic, Applied Physics Letters vol. 87, article 241102 (2005) (arXiv:physics/0505098)
  3. General recipe for designing photonic crystal cavities, Dirk Englund, Ilya Fushman, and Jelena Vuckovic, Optics Express, Vol. 13, No. 16, pp. 5961 - 5975 (2005) (arXiv:physics/0507156)
    Highlights: See also the optics research highlight in Nature and the review of this article by Henri Benisty: Photonic crystals: New designs to confine light, Nature Physics, vol. 1, pp. 9, Oct. 2005
  4. Controlling the Spontaneous Emission Rate of Single Quantum Dots in a 2D Photonic Crystal, Dirk Englund, David Fattal, Edo Waks, Glenn Solomon, Bingyang Zhang, Toshihiro Nakaoka, Yasuhiko Arakawa, Yoshihisa Yamamoto, and Jelena Vuckovic, Physical Review Letters vol. 95, article 013904 (2005) (arXiv:quant-ph/0501091)
  5. Coupled mode theory for photonic crystal cavity-waveguide interaction, E. Waks and J. Vuckovic, Optics Express, ol.13, No. 13, pp. 5064 - 5073 (2005)(arXiv:physics/0504077)
  6. Polarization control and sensing with two-dimensional coupled photonic crystal microcavity arrays, Hatice Altug and Jelena Vuckovic, Optics Letters vol. 30, No. 9, pp. 982-984 (2005) (arXiv:physics/0407103)
  7. Experimental demonstration of the slow group velocity of light in two-dimensional coupled photonic crystal microcavity arrays, Hatice Altug and Jelena Vuckovic, Applied Physics Letters, vol. 86, article 111102 (2005). (arXiv:physics/0406109)
    Highlights: See also the Physics Web News Story
  8. Fabrication of InAs quantum dots in AlAs/GaAs DBR pillar microcavities for single photon sources, B. Zhang, G. S. Solomon, M. Pelton, J. Plant, C. Santori, J. Vuckovic, and Y. Yamamoto, Journal Of Applied Physics vol. 97, article 073507 (2005)
  9. Single photons on demand, Barry Sanders, Jelena Vuckovic and Philippe Grangier, Europhysics News, vol. 36, No. 2, pp. 56-58, March/April 2005 (review article)
  10. Single photons for quantum information systems, Y. Yamamoto, C. Santori, G. Solomon, J. Vuckovic, D. Fattal, E. Waks, E. Diamanti, Progress in Informatics No.1, pp. 5-37 (2005) (review article)

2004

  1. Two dimensional coupled photonic crystal resonator arrays, H. Altug and J. Vuckovic, Applied Physics Letters, vol. 84, pp. 161-163, January 2004.
    Highlights: See also the cover of Applied Physics Letters dedicated to this article. (arXiv:physics/0406110)
  2. Entanglement formation and violation of Bell's inequality with a semiconductor single photon source, D. Fattal, K. Inoue, J. Vuckovic, C. Santori, G. Solomon, and Y. Yamamoto, Physical Review Letters, vol. 92, article 037903, 2004. (arXiv:quant-ph/0305048)
  3. Sub-microsecond correlations in photoluminescence from InAs quantum dots, C. Santori, D. Fattal, J. Vuckovic, G. Solomon, E. Waks, and Y. Yamamoto, Physical Review B, vol. 69, article 205324 2004. (arXiv:cond-mat/0308323)
  4. Planar photonic crystal nanolasers (I): Porous cavity lasers, M. Loncar, T. Yoshie, K. Okamoto, Y. Qiu, J. Vuckovic, and A. Scherer, IEICE Transactions on Electronics, Vol. E87-C, No. 3, pp. 291-299, 2004.
  5. Single-photon generation with InAs quantum dots, C. Santori, D. Fattal, J. Vuckovic, G. Solomon, and Y, Yamamoto, New Journal of Physics, focus issue on Single photons on demand, vol. 6, 2004.
    Highlights: See also this whole focus issue on Single photons on demand, of the New Journal of Physics.
  6. Photonic technologies for quantum information processing, P. Kumar, P. Kwiat, A. Migdall, S. W. Nam, J. Vuckovic, and F. N. C. Wong, Journal of Quantum Information Processing, Special issue on experimental aspects of quantum computing, vol. 3, No. 1-5, Oct. 2004.
  7. Sub-micron all-optical digital memory and integration of nano-scale photonic devices without isolators, M. F. Yanik, H. Altug, J. Vuckovic and S. Fan, Journal of Lightwave Technology, vol. 22, No. 10, pp. 2316-2322, 2004.
  8. Generation of single photons and correlated photon pairs using InAs quantum dots, C. Santori, D. Fattal, J. Vuckovic, G. S. Solomon, and Y. Yamamoto, Fortschritte der Physik-Progress Of Physics, vol. 52, No. 11-12, pp. 1180-1188 (Nov-Dec 2004).

2003

  1. Enhanced single photon emission from a quantum dot in a micropost microcavity, J. Vuckovic, D. Fattal, C. Santori, G. Solomon, and Y. Yamamoto, Applied Physics Letters, vol. 82, pp. 3596-3598, May 2003. (arXiv:quant-ph/0307025)
  2. Photonic crystal microcavities for cavity quantum electrodynamics with a single quantum dot, J. Vuckovic and Y. Yamamoto, Applied Physics Letters, vol. 82, pp. 2374-2376, April 2003.
  3. An efficient source of single photons: a single quantum dot in a micropost microcavity , M. Pelton, J. Vuckovic, G. Solomon, C. Santori, B. Zhang, J. Plant, and Y. Yamamoto, Physica E - Low dimensional systems and nanostructures, vol. 17, pp. 564-567, 2003.
  4. Indistinguishable single photons from a quantum dot, D. Fattal, C. Santori, J. Vuckovic, G. Solomon, Y. Yamamoto, Physica Status Solidi b, vol. 238, pp. 305-308, 2003.

2002

  1. Secure communication: Quantum cryptography with a photon turnstile, E. Waks, K. Inoue, C. Santori, D. Fattal, J. Vuckovic, G. Solomon, and Y. Yamamoto,Nature, vol. 420, pp. 762, December 2002.
    Check also the supplementary information on this article on the Nature website
  2. An efficient source of single photons: a single quantum dot in a micropost microcavity, M. Pelton, C. Santori, J. Vuckovic, B. Zhang, G. S. Solomon, J. Plant, and Y. Yamamoto, Physical Review Letters, vol. 89, article 233602, November 2002. (arXiv:quant-ph/0208054)
    Highlights: See also the cover of Phys. Rev. Letters dedicated to this article.
  3. Indistinguishable photons from a single-photon device, C. Santori, D. Fattal, J. Vuckovic, G. S. Solomon, and Y. Yamamoto, Nature, vol. 419, pp. 594-597, Oct. 2002.
    Highlights:See also the review of this article by Philippe Grangier: Single photons stick together Nature, vol. 419, pp. 577, Oct. 2002, and the news featured in the Science and Nature magazines (the latter requires a free registration for "Nature physics portal").
  4. Optimization of three-dimensional micropost microcavities for cavity quantum electrodynamics, J. Vuckovic, M. Pelton, A. Scherer, and Y. Yamamoto, Physical Review A, vol. 66, article 023808, August 2002. (arXiv:quant-ph/0208134)
  5. Optimization of Q-factor in photonic crystal microcavities, J. Vuckovic, M. Loncar, H. Mabuchi, and A. Scherer, IEEE Journal of Quantum Electronics, vol. 38, No. 7, pp. 850-856, July 2002.
  6. Photonic crystals for confining, guiding, and emitting light, A. Scherer, O. Painter, J. Vuckovic, M. Loncar, and T. Yoshie, IEEE Transactions on Nanotechnology, vol.1, pp. 4 -11, 2002.
  7. Experimental and theoretical confirmation of Bloch-mode light propagation in planar photonic crystal waveguides, M. Loncar, D. Nedeljkovic, T. P. Pearsall, J. Vuckovic, A. Scherer, S. Kuchinsky, and D. C. Allan, Applied Physics Letters, vol. 80, No. 10, pp. 1689-1691, 2002.
  8. Three dimensionally confined modes in micropost microcavities: quality factors and Purcell factors, M. Pelton, J. Vuckovic, G. S. Solomon, A. Scherer, and Y. Yamamoto, IEEE Journal of Quantum Electronics, vol. 38, No. 2, pp. 170-177, February 2002.
  9. Design of photonic crystal microcavities for cavity QED, J. Vuckovic, M. Loncar, H. Mabuchi, and A. Scherer, Physical Review E, vol. 65, article # 016608, January 2002. (arXiv:quant-ph/0208101)

2001

  1. High quality two-dimensional photonic crystal slab cavities, T. Yoshie, J. Vuckovic, A. Scherer, H. Chen, and D. Deppe, Applied Physics Letters, vol. 79, pp. 4289-4291, December 2001.
  2. Quantum networks based on cavity QED, H. Mabuchi, M. Armen, B. Lev, M. Loncar, J. Vuckovic, H.J. Kimble, J. Preskill, M. Roukes, and A. Scherer, Quantum Information and Computation, vol. 1, special issue on Implementation of Quantum Computation, pp. 7-12, 2001.
  3. Low Complexity Soft Decision Decoding Algorithms for Reed Solomon Codes , B. Vucetic, V. Ponnampalam, and J. Vuckovic, IEICE Transactions on Communications (Special Issue on Innovative Mobile Communication Technologies at the Dawn of the 21st Century), Vol. E84-B, No. 3, pp. 392-399, March 2001.
  4. Methods for controlling positions of guided modes in photonic crystal waveguides, M. Loncar, J. Vuckovic, and A. Scherer, Journal of the Optical Society of America B, vol. 18, Issue 9 pp. 1362-1368, September 2001.

2000

  1. Surface plasmon enhanced light-emitting diode, J. Vuckovic, M. Loncar, and A. Scherer, IEEE Journal of Quantum Elecronics, vol. 36, No. 10, pp. 1131-1144, October 2000.
  2. Low energy electron beam focusing in self-organized porous alumina vacuum windows, T. Doll, J. Vuckovic, M. Hochberg, and A. Scherer, Applied Physics Letters, vol. 76, No. 24, pp. 3635-3637, 2000.
  3. Design and fabrication of silicon photonic crystal optical waveguides, M. Loncar, T. Doll, J. Vuckovic, and A. Scherer, Journal of Lightwave Technology, vol. 18, No. 10, pp. 1402-1411, October 2000.
  4. Waveguiding in planar photonic crystals, M. Loncar, D. Nedeljkovic, T. Doll, J. Vuckovic, A. Scherer, and T. P. Pearsall, Applied Physics Letters, vol. 77, No. 13, pp. 1937-1939, September 25, 2000.

1999

  1. Finite-Difference Time-Domain Calculation of the Spontaneous Emission Coupling Factor in Optical Microcavities , J. Vuckovic, O. Painter, Y. Xu, A. Yariv, and A. Scherer, IEEE Journal of Quantum Electronics, vol. 35, No. 8, pp. 1168-1174, August 1999.
  2. Defect modes of a two-dimensional photonic crystal in an optically thin dielectric slab, O. Painter, J. Vuckovic, and A. Scherer, Journal of the Optical Society of America B, vol. 16, No. 2, pp. 275-285, February 1999.
  3. Finite-difference time-domain calculation of spontaneous emission lifetime in a microcavity, Y. Xu, J. S. Vuckovic, R. K. Lee, O. J. Painter, A. Scherer, and A Yariv, Journal of the Optical Society of America B, vol. 16, No., pp. 465-474, March 1999.

Theses

  1. Sonia Buckley, Engineering photonic crystal cavities in III-V semiconductors for 𝜒(2) frequency conversion, Ph.D. Dissertation, July 2014
  2. Jesse Lu, Nanophotonic Computational Design, Ph.D. Dissertation, June 2013.
  3. Gary Shambat, From solid state to soft matter: Photonic nanocavities as advanced optoelectronic devices and single-cell biomedical probes, Ph.D. dissertation, May 2012.
  4. Arka Majumdar, Solid state cavity quantum electrodynamics with quantum dots coupled to photonic crystal cavities, Ph.D. dissertation, August 2012.
  5. Kelley Rivoire, Nonlinear frequency conversion in III-V semiconductor photonic crystals, Ph.D. dissertation, March 2012.
  6. Bryan Ellis, Ultralow threshold electrically pumped photonic crystal lasers, Ph.D. dissertation, February 2012.
  7. Yiyang Gong, Silicon-based photonic, plasmonic, and optomechanic devices, Ph.D. dissertation, December 2010.
  8. Maria Makarova, Silicon Based Photonic Crystal Light Sources, Ph.D. dissertation, March 2010.
  9. Andrei Faraon, Locally Controlled Photonic Crystal Devices With Coupled Quantum Dots: Physics and Applications, Ph.D. dissertation, August 2009.
  10. Ilya Fushman, Quantum Dots in Photonic Crystals: From Quantum Information Processing to Single Photon Nonlinear Optics, Ph.D. dissertation, December 2008.
  11. Dirk Englund, Photonic Crystals for Quantum and Classical Information Processing, Ph.D. dissertation, July 2008.
  12. Hatice Altug, Physics and Applications of Photonic Crystal Nanocavities, Ph.D. dissertation, December 2006.
  13. Joel Goh, Design of Photonic Crystal Cavities by Genetic Algorithms and Numerical Optimization Techniques, Senior thesis, 2006.
  14. Benedikt Stein,Stimulated Raman Scattering in Silicon Coupled Photonic Crystal Microcavity Arrays, 2006.

Book chapters

  1. Inverse design of nanophotonic structures, J. Lu and J. Vuckovic, Invited book chapter in Numerical optimization techniques for metamaterial design, edited by K. Diest, Springer Topics in Applied Physics, vol. 127 (2013)
  2. Photonic crystal cavity lasers, Y. Gong, B. Ellis, J. Vuckovic, Invited book chapter in Quantum Dot Devices, edited by Z. M. Wang, Lecture Notes in Nanoscale Science and Technology, Springer-Verlag (2012)
  3. Quantum optics with single quantum dots in photonic crystal cavities, A. Majumdar, M. Bajcsy, K. Rivoire, S. Buckley, A. Faraon, E. Kim, D. Englund, and J. Vuckovic, Invited book chapter in Quantum optics with semiconductor nanostructures, edited by Frank Jahnke, Woodhead Publishing (2012)
  4. Quantum dots in photonic crystal cavities, A. Faraon and J. Vuckovic, Invited book chapter in Quantum Dots: optics, electron transport and future applications, edited by A. Tartakovskii, Cambridge University Press (2012)
  5. Spontaneous emission control in a plasmonic structure, H. Iwase, Y. Gong, D. Englund, and J. Vuckovic, Invited book chapter in Nanoscale Photonics and Optoelectronics, edited by Z. M. Wang and A. Neogi, Lecture notes in Nanoscale Science and Technology, vol. 9, Springer-Verlag (2010).
  6. Photonic crystal microcavity light sources, H. Altug, D. Englund, and J. Vuckovic, Invited book chapter in Comprehensive Semiconductor Science and Technology, edited by P. Bhattacharya, Elsevier (2010)
  7. Physics and applications of quantum dots in photonic crystals, D. Englund, A. Faraon, I. Fushman, B. Ellis, and J. Vuckovic, Invited book chapter in Single Semiconductor Quantum Dots, edited by Peter Michler, Springer Book series on NanoScience and Technology, Springer (2008)
  8. Quantum Information Processing With Quantum Dots in Photonic Crystals, J. Vuckovic, D. Englund, A. Faraon, I. Fushman, and E Waks, Invited book chapter in Semiconductor Quantum Bits, edited by Oliver Benson and Fritz Henneberger, Pan Stanford Publishing (2008)
  9. Pillar microcavities, C. Santori, D. Fattal, J. Vuckovic, M. Pelton, G. Solomon, E. Waks, D. Press, Y. Yamamoto, Invited book chapter in Practical applications of microresonators in optics and photonics, edited by A. Matsko, CRC (2009)
  10. Photonic Technologies for Quantum Information Processing,P. Kumar, P. Kwiat, A. Migdall, S.W. Nam, J. Vuckovic, and F.N.C. Wong, Invited book chapter in Experimental Aspects of Quantum Computing, edited by Henry Everitt, Springer (2005)
  11. Cavity Enhanced Single Photons From a Quantum Dot, J. Vuckovic, C. Santori, D. Fattal, M. Pelton, G. Solomon, and Y. Yamamoto, Invited book chapter in Optical Microcavities, Ed: Kerry Vahala (World Scientific, 2004).
  12. Regulated Single Photons and Entangled Photons From a Quantum Dot Microcavity, Y. Yamamoto, M. Pelton, C. Santori, G. S. Solomon, O. Benson, J. Vuckovic, and A. Scherer, Invited book chapter in Semiconductor Spintronics and Quantum Computation, Eds: D. D. Awshalom, D. Loss, and N. Samarth, pp. 277-305 (Springer-Verlag, Berlin, Heidelberg, 2002).

Patents

  1. US Patent No.8,829,638: "An ultrafast photonic crystal cavity single-mode light-emitting diode," Gary Shambat, Bryan Ellis, Jelena Vuckovic, issued Sept. 9, 2014
  2. US Patent No.8,471,352: "A practical electrically pumped photonic crystal nanocavity," Bryan Ellis, Ilya Fushman, Jelena Vuckovic, issued Jun. 25, 2013
  3. US Patent No.8,355,606: "Ultrafast, ultralow threshold single emitter optical switch", D. Englund, I. Fushman, A. Faraon, and J. Vuckovic, issued Feb. 2013.
  4. US Patent No.7,994,467: "Optical Cavity Emitter Arrangements With Spectral Alignment And Methods Therefor", A. Faraon, I. Fushman, D. Englund, and J. Vuckovic, issued Aug. 9, 2011.
  5. US Patent No.7,848,603: "Optical switching based on dipole induced transparency", E. Waks and J. Vuckovic, issued Dec. 7 2010.
  6. US patent No.7,630,604: "Dipole induced transparency in photonic crystal cavity-waveguide system", E. Waks and J. Vuckovic, issued Dec. 2009.
  7. US patent No.7,292,613: "Half-Wavelength Micropost Microcavity with Electric Field Maximum in the High-Refractive Index Region", J. Vuckovic and Y. Yamamoto, issued on Nov. 6, 2007.
  8. US patent No.7,206,488: "Coupled photonic crystal resonator array arrangements and applications", H. Altug and J. Vuckovic, issued on April 17, 2007.
  9. US patent No.6,466,709:"Photonic crystal microcavities for strong coupling between an atom and the cavity field", A. Scherer, J. Vuckovic, M. Loncar and H. Mabuchi.
  10. US patent No.6,515,292: "High resolution electron projection", A. Scherer and J. Vuckovic.
  11. US patent No.6,534,798: "Surface plasmon enhanced LED and the method of operation of the same", A. Scherer, J. Vuckovic and M. Loncar.
  12. US patent No. 6,944,384: "Methods for controlling positions of guided modes of the photonic crystal waveguides", M. Loncar, J. Vuckovic and A. Scherer.

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