{"id":14,"date":"2023-09-01T16:30:30","date_gmt":"2023-09-01T16:30:30","guid":{"rendered":"https:\/\/live-optics-wp.pantheonsite.io\/danielsoh\/?page_id=14"},"modified":"2026-06-18T18:32:42","modified_gmt":"2026-06-18T18:32:42","slug":"publications","status":"publish","type":"page","link":"https:\/\/wp.optics.arizona.edu\/danielsoh\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"\r\n<h3>Journal Articles<\/h3>\r\n<ol>\r\n<li>Soh, Daniel. &#8220;Computational Superiority of Non-Markovian Kerr Feedback in Continuous-Variable Quantum Reservoir Computing.&#8221; <i>arXiv preprint arXiv:2606.06689<\/i> (2026) (<a href=\"https:\/\/arxiv.org\/abs\/2606.06689\">https:\/\/arxiv.org\/abs\/2606.06689)<\/a>.<\/li>\r\n<li>Zhu, C., Wang, T., McMahon, P. L., &amp; Soh, D. (2025). Quantum optical neural networks using atom-cavity interactions to provide all-optical nonlinearity. <i>arXiv preprint arXiv:2511.06167 <\/i><a href=\"https:\/\/arxiv.org\/pdf\/2511.06167\">(https:\/\/arxiv.org\/pdf\/2511.06167)<\/a>.<\/li>\r\n<li>Zhu, Chuanzhou, Peter J. Ehlers, Hendra I. Nurdin, and Daniel Soh. &#8220;Minimalistic and scalable quantum reservoir computing enhanced with feedback.&#8221; <i>npj Quantum Information<\/i> (2025) (<a href=\"https:\/\/www.nature.com\/articles\/s41534-025-01144-4)\">https:\/\/www.nature.com\/articles\/s41534-025-01144-4)<\/a>.<\/li>\r\n<li>Chatterjee, E., Soh, D., &amp; Eichenfield, M. (2025). Acoustoelectric Amplification in a Piezoelectric-2DEG Heterostructure. <i>arXiv preprint arXiv:2510.09248 <\/i>(<a href=\"https:\/\/arxiv.org\/abs\/2510.09248\">https:\/\/arxiv.org\/abs\/2510.09248<\/a>).<\/li>\r\n<li>Chatterjee, Eric, Daniel Soh, and Matt Eichenfield. &#8220;Quantum-limited acoustoelectric amplification in a piezoelectric-2DEG heterostructure.&#8221; <i>Physical Review Research<\/i> 8.2 (2026): 023185. (<a href=\"https:\/\/journals.aps.org\/prresearch\/pdf\/10.1103\/9zjg-gx79\">https:\/\/journals.aps.org\/prresearch\/pdf\/10.1103\/9zjg-gx79<\/a>).<\/li>\r\n<li>Kaushik, Ishwar S., Peter J. Ehlers, and Daniel Soh. &#8220;All-optical echo state network reservoir computing.&#8221; <i>Physical Review Research<\/i> 8.1 (2026): 013041.(<a href=\"https:\/\/journals.aps.org\/prresearch\/abstract\/10.1103\/3b3z-29f4\">https:\/\/journals.aps.org\/prresearch\/abstract\/10.1103\/3b3z-29f4<\/a>).<\/li>\r\n<li>P.J. Ehlers, H.I. Nurdin, D. Soh, &#8220;Stochastic reservoir computers,&#8221; <em>Nature Communications<\/em> 16, 3070 (2025) (<a href=\"https:\/\/doi.org\/10.1038\/s41467-025-58349-6\">https:\/\/doi.org\/10.1038\/s41467-025-58349-6<\/a>) &#8211; <em><strong>Editor&#8217;s Highlights<\/strong><\/em>.<\/li>\r\n<li>Ehlers, P. J., Nurdin, H. I., &amp; Soh, D. (2025). Improving the performance of echo state networks through state feedback.\u00a0<em>Neural Networks<\/em>,\u00a0<em>184<\/em>, 107101 (<a href=\"https:\/\/doi.org\/10.1016\/j.neunet.2024.107101\">https:\/\/doi.org\/10.1016\/j.neunet.2024.107101<\/a>).<\/li>\r\n<li>Young, S. M., &amp; Soh, D. (2025). Fundamental limits to the generation of highly displaced bright squeezed light using linear optics and parametric amplifiers.\u00a0<em>Physical Review Research<\/em>,\u00a0<em>7<\/em>(1), 013130 (<a href=\"https:\/\/doi.org\/10.1103\/PhysRevResearch.7.013130\">https:\/\/doi.org\/10.1103\/PhysRevResearch.7.013130<\/a>).<\/li>\r\n<li>Zhu, C., Ehlers, P. J., Nurdin, H. I., &amp; Soh, D. (2025). Practical few-atom quantum reservoir computing. <i>Physical Review Research<\/i>, <i>7<\/i>(2), 023290. (<a href=\"https:\/\/doi.org\/10.1103\/wsyq-jyxd\">https:\/\/doi.org\/10.1103\/wsyq-jyxd<\/a>)<\/li>\r\n<li>Zhu, C., Ehlers, P. J., Nurdin, H. I., &amp; Soh, D. (2025). Minimalistic and Scalable Quantum Reservoir Computing Enhanced with Feedback. <em>npj Quantum Information 195. (<a href=\"https:\/\/doi.org\/10.1038\/s41534-025-01144-4\">https:\/\/doi.org\/10.1038\/s41534-025-01144-4<\/a>)<\/em>.<\/li>\r\n<li>Pizzimenti, A. J., &amp; Soh, D. (2024). Optical Gottesman-Kitaev-Preskill qubit generation via approximate squeezed coherent state superposition breeding.\u00a0<em>Physical Review A<\/em>,\u00a0<em>110<\/em>(6), 062619 (<a href=\"https:\/\/doi.org\/10.1103\/PhysRevA.110.062619\">https:\/\/doi.org\/10.1103\/PhysRevA.110.062619<\/a>).<\/li>\r\n<li>P. Chrostoski, S. Bisson, D. Farley, F. Naducci, D. Soh, &#8220;Error analysis in large area multi-Raman pulse atom interferometry due to undesired spontaneous decay,&#8221;\u00a0<em>arXiv preprint \u00a0<\/em>arXiv:2403.08913 (2024).<\/li>\r\n<li>Chatterjee, Eric, Alexander Wendt, Daniel Soh, and Matt Eichenfield. &#8220;Ab-Initio Calculations of Nonlinear Susceptibility and Multi-Phonon Mixing Processes in a 2DEG-Piezoelectric Heterostructure,&#8221; Physical Review Research 6 (2), 023288 (2024) (<a href=\"https:\/\/doi.org\/10.1103\/PhysRevResearch.6.023288\">https:\/\/doi.org\/10.1103\/PhysRevResearch.6.023288<\/a>).<\/li>\r\n<li>Cuozzo, J.J., Yu, W., Davids, P., Nenoff, T.M., Soh, D.B., Pan, W. and Rossi, E., &#8220;Leggett Modes in Dirac Semimetals,&#8221;, Nature Physics, pp.1-6 (2024) (<a href=\"https:\/\/doi.org\/10.1038\/s41567-024-02412-4\">https:\/\/doi.org\/10.1038\/s41567-024-02412-4<\/a>).<\/li>\r\n<li>D. Soh and E. Chatterjee, \u201cLabel-free quantum super-resolution imaging using entangled multi-mode squeezed light,\u201d New Journal of Physics 25 (9), 093001 (2023) (<a href=\"https:\/\/iopscience.iop.org\/article\/10.1088\/1367-2630\/acf2ba\/meta\">https:\/\/iopscience.iop.org\/article\/10.1088\/1367-2630\/acf2ba\/meta<\/a>).<\/li>\r\n<li>Chatterjee, Eric, Wei Pan, and Daniel Soh. &#8220;Ultra-high-precision detection of single microwave photons based on a hybrid system between a Majorana zero mode and a quantum dot.&#8221; <i>Physical Review Research<\/i> 5.1 013034 (2023).<\/li>\r\n<li>J.C. Taylor, E. Chatterjee, W.F. Kindel, D. Soh, M. Eichenfield, \u201cReconfigurable quantum phononic circuits via piezo-acoustomechanical interactions,\u201d npj Quantum Information 8(1), pp.1-12 (2022).<\/li>\r\n<li>E. Chatterjee, D. Soh, M. Eichenfield, \u201cOptimal quantum transfer from input flying qubit to lossy quantum memory,\u201d Jour. Phys. A: Math. Theor. (2022)<\/li>\r\n<li>D. Soh, E. Chatterjee, M. Eichenfield, \u201cHigh-fidelity state transfer between leaky quantum memories,\u201d Phys. Rev. Research 3(3), 033027 (2021).<\/li>\r\n<li>W. Pan, D. Soh, W. Yu, P. Davids, T.M. Nenoff, \u201cMicrowave response in a topological superconducting quantum interference device,\u201d Scientific Reports 11(1), pp. 1-5 (2021).<\/li>\r\n<li>E. Chatterjee, W. Pan, D. Soh, \u201cMicrowave photon number resolving detector using the topological surface state of superconducting cadmium arsenide,\u201d Phys. Rev. Research 3 (2), 023046 (2021).<\/li>\r\n<li>E. Chatterjee, D. Soh, C. Rogers, D. Gray, H. Mabuchi, \u201cLow-temperature annihilation rate for quasilocalized excitons in monolayer MoS2,\u201d Phys. Rev. B 100(15), 155405 (2019).<\/li>\r\n<li>D. Soh, C. Rogers, D.J. Gray, E. Chatterjee, H. Mabuchi, \u201cOptical nonlinearities of excitons in monolayer MoS2,\u201d Phys. Rev. B 97 (16), 165111 (2018).<\/li>\r\n<li>D. Soh, R. Hamerly, H. Mabuchi, \u201cComprehensive analysis of the optical Kerr coefficient of graphene,\u201d Phys. Rev. A 94, 023845 (2016)<\/li>\r\n<li>M. Sarovar, D. Soh, J. Cox, C. Brif, C. T. DeRose, R. Camacho, P. Davids, \u201cSilicon nanophotonics for scalable quantum coherent feedback networks,\u201d EPJ quantum technology 3(1), 14 (2016)<\/li>\r\n<li>D. Soh, C. Brif, P. J. Coles, N. Lutkenhaus, R. M. Camacho, J. Urayama, M. Sarovar, \u201cSelf-referenced continuous-variable quantum key distribution,\u201d Phys. Rev. X 5(4), 041010 (2015)<\/li>\r\n<li>O. Crisafulli, N. Tezak, D. Soh, M. A. Armen, H. Mabuchi, \u201cSqueezed light in an optical parametric oscillator network with coherent feedback quantum control,\u201d Optics Express 21(15), 18371-18386 (2013).<\/li>\r\n<li>S. W. Moore, D. Soh, S. E. Bisson, B. D. Patterson, \u201cA 400 \u00b5J 79 ns all-fiber Q-switched laser using an Yb<sup>3+<\/sup>-doped fiber saturable absorber,\u201d Optics Express 20(21), 23778-23789 (2012)<\/li>\r\n<li>D. Soh, S. E. Bisson, B. D. Patterson, and S. W. Moore, \u201cHigh-power all-fiber passively Q-switched laser using a doped fiber as a saturable absorber: numerical simulations,\u201d Optics Letters 36(13), pp. 2536-2538 (2011).<\/li>\r\n<li>D. Soh and J. P. Kplow, \u201cAnalysis of spectral broadening of incoherent light in optical fibers with nonzero dispersion,\u201d Optical Engineering 50(11), 111602 (2011).<\/li>\r\n<li>D. Soh, J. P. Koplow, S. W. Moore, K. L. Schroder, and W. L. Hsu, \u201cThe effect of dispersion on spectral broadening of incoherent continuous-wave light in optical fibers,\u201d Optics Express 18(21), pp. 22393-22405 (2010).<\/li>\r\n<li>J. Kim, D. Soh, J. Nilsson, D. J. Richardson, and J. K. Sahu, \u201cFiber design for high-power low-cost Yb:Al-doped fiber laser operating at 980nm,\u201d IEEE Journal of Selected Topics in Quantum Electronics, vol.13(3) pp.588-597 (2007).<\/li>\r\n<li>J. Kim, P. Dupriez, D. Soh, J. Nilsson, J. K. Sahu, \u201cCore area scaling of Nd:Al-doped silica depressed clad hollow optical fiber and Q-switched laser operation at 0.9 microns,\u201d Optics Letters, vol.31(19) pp.2833-2835 (2006).<\/li>\r\n<li>D. Soh, J. Nilsson, and A. B. Grudinin, \u201cEfficient femtosecond laser generation using parabolic amplification combined with a pulse compressor: I. Stimulated Raman scattering effect,\u201d Journal of Optical Society of America B, vol. 23(1), pp. 1-9 (2006).<\/li>\r\n<li>D. Soh, J. Nilsson, and A. B. Grudinin, \u201cEfficient femtosecond laser generation using parabolic amplification combined with a pulse compressor: II. Finite gain-bandwidth effect,\u201d Journal of Optical Society of America B, vol. 23(1), pp. 10-19 (2006).<\/li>\r\n<li>Y. Jeong, J. Nilsson, J. K. Sahu, D. Soh, P. Dupriez, C. A. Codemard, S. Baek, D. N. Payne, R. Horley, J. A. Alvarez-Chavez, and P. W. Turner, \u201cSingle-mode plane-polarized ytterbium-doped large-core fiber laser with 633 W continuous-wave output power,\u201d Optics Letters, vol. 30(9) pp.955-957 (2005).<\/li>\r\n<li>Y. Jeong, J. Nilsson, J. K. Sahu, D. Soh, C. Alegria, P. Dupriez, C. A. Codemard, D. N. Payne, R. Horley, L. M. B. Hickey, L. Wanzcyk, J. Chryssou, J. A. Alvarez-Chavez, and P. W. Turner, \u201cSingle-frequency single-mode plane-polarized ytterbium-doped fiber master-oscillator power amplifier source with 264W output power,\u201d Optics Letters, vol. 30(5) pp. 459-461 (2005).<\/li>\r\n<li>S. Yoo, D. Soh, J. Kim, Y. Jung, J. Nilsson, J. K. Sahu, J. W. Lee, and K. Oh, \u201cAnalysis of W-type waveguide for Nd-doped fiber laser operating near 940nm,\u201d Optics Communications, vol. 247(1-3), pp. 153-162 (2005).<\/li>\r\n<li>Y. Jeong, J. K. Sahu, D. Soh, C. A. Codemard, and J. Nilsson, \u201cHigh-power tunable single-frequency single-mode erbium:ytterbium co-doped large-core fiber master-oscillator power amplifier source,\u201d Optics Letters, vol.30(22), pp.2997-2999 (2005).<\/li>\r\n<li>D. Soh, S. Yoo, J. Nilsson, J. K. Sahu, K. Oh, S. Baek, Y. Jeong, C. A. Codemard, P. Dupriez, J. Kim, and V. Philippov, \u201cNeodymium-doped cladding pumped aluminosilicate fiber laser tunable in the 0.9 micron wavelength range,\u201d IEEE Journal of Quantum Electronics, vol. 40(9), pp.1275-1282 (2004).<\/li>\r\n<li>D. Soh, J. Nilsson, S. Baek, C. Codemard, Y. Jeong, and V. Philippov, \u201cModal power decomposition of beam intensity profiles into LP modes of multimode optical fibers,\u201d Journal of the Optical Society of America A, vol. 21(7), pp.1241-1250 (2004).<\/li>\r\n<li>S. Baek, D. Soh, Y. Jeong, J. K. Sahu, J. Nilsson, B. Lee, \u201cA cladding-pumped fiber laser with pump-reflecting inner-cladding Bragg grating,\u201d IEEE Photonics Technology Letters, vol. 16(2), pp.407-409 (2004).<\/li>\r\n<li>D. Soh, C. Codemard, S. Wang, J. Nilsson, J. K. Sahu, F. Laurell, V. Philippov, Y. Jeong, C. Alegria, and S. Baek, \u201cA 980 nm Yb-doped fiber MOPA source and its frequency doubling,\u201d IEEE Photonics Technology Letters, vol. 16(4), pp.1032-1034 (2004).<\/li>\r\n<li>Y. Jeong, J. K. Sahu, S. Baek, C. Alegria, D. Soh, C. Codemard, and J. Nilsson, \u201cCladding-pumped ytterbium-doped large-core fiber laser with 610 W of output power,\u201d Optics Communications, vol. 234(01-Jun) pp.315-319 (2004).<\/li>\r\n<li>D. Soh, J. Nilsson, J. K. Sahu, and L. J. Cooper, \u201cGeometrical factor modification of helical-core fiber radiation loss formula,\u201d Optics Communications, vol. 222, pp.235-242 (2003).<\/li>\r\n<\/ol>\r\n<hr \/>\r\n<h3>Conference Talks<\/h3>\r\n<ol>\r\n<li>Ehlers, Peter J., and Daniel Soh. &#8220;Diagrammatic Expansion for Solving the Lindblad Master Equation.&#8221; <i>APS Global Physics Summit 2026<\/i>. 2026.<\/li>\r\n<li>Chatterjee, Eric, Daniel Soh, and Matt Eichenfield. &#8220;An Ultra-Scalable Quantum Squeezer Through Acoustic Parametric Amplification in a Piezoelectric-2DEG Heterostructure.&#8221; <i>APS Global Physics Summit 2026<\/i>. 2026.<\/li>\r\n<li>Zhu, Chuanzhou, Tianyu Wang, Peter L. McMahon, and Daniel Soh. &#8220;Quantum Atomic Optical Neural Network.&#8221; In <i>APS Global Physics Summit 2026<\/i>. 2026.<\/li>\r\n<li>Pizzimenti, Andrew J., and Daniel Soh. &#8220;All-Optical Gottesman-Kitaev-Preskill Qubit Generation via Approximate Squeezed Coherent State Superposition Breeding.&#8221; <i>Quantum 2.0<\/i>. Optica Publishing Group, 2025.<\/li>\r\n<li>Soh, Daniel, Peter Ehlers, and Hendra Nurdin. &#8220;Reservoir Computing with Feedback for Quantum State Identification.&#8221; <i>Bulletin of the American Physical Society <\/i>(APS March Meeting) (2024).<\/li>\r\n<li>Chrostoski, Philip, Scott Bisson, and Daniel Soh. &#8220;Limitations of a large momentum atom interferometer acceleration sensor due to spontaneous emission.&#8221; <i>Bulletin of the American Physical Society<\/i> (APS March Meeting) (2024).<\/li>\r\n<li>Chatterjee, Eric, Daniel Soh, and Matt Eichenfield. &#8220;Ab-Initio Calculations of Nonlinear Susceptibility and Multi-Phonon Mixing Processes in a 2D Electron Gas Coupled to a Piezoelectric Material.&#8221; <i>Bulletin of the American Physical Society<\/i> (APS March Meeting) (2024).<\/li>\r\n<li>Soh, Daniel, and Steve Young. &#8220;Fundamental limits to the highly-displaced bright squeezed light generation based on linear optics and parametric processes.&#8221; <i>Bulletin of the American Physical Society<\/i> (APS March Meeting) (2024).<\/li>\r\n<li>E. Chatterjee, D. Soh, M. Eichenfield, \u201cBuilding a quantum repeater using optomechanical oscilaltors as on-demand entanglement sources,\u201d APS March Meeting 2023.<\/li>\r\n<li>P. Chrostoski, S. Bisson, D. Soh, \u201cLimitations of a multi-Raman-pulse atom interferometry acceleration sensor,\u201d APS March Meeting 2023.<\/li>\r\n<li>D. Soh, \u201cSuper-resolution quantum imaging using massively entangled multimode squeezed light,\u201d APS March Meeting 2022, Invited focus session talk.<\/li>\r\n<li>D. Soh, M. Eichenfield, \u201cBright squeezed light from dissipative optomechanical light squeezer,\u201d APS March Meeting 2022.<\/li>\r\n<li>E. Chatterjee, D. Soh, R. Lewis, W. Kindel, L. Hackett, J. Taylor, M. Eichenfield, \u201cLong-distance end-to-end quantujm state transfer in a transmon qubit network connected via optical photons,\u201d APS March Meeting 2022.<\/li>\r\n<li>J. Cuozzo, W. Yu, P. Davids, T. Nenoff, D. Soh, E. Rossi, W. Pan, \u201cLeggett modes in Dirac semimetals,\u201d APS March Meeting 2022.<\/li>\r\n<li>E. Chatterjee, D. Soh, M. Eichenfield, \u201cOptimal quantum transfer from input flying qubit to lossy memory,\u201d APS March Meeting 2022.<\/li>\r\n<li>E. Chatterjee, D. Soh, M. Eichenfield, \u201cArtificial atom on a chip based on coupling between 2DEG and piezo resonator,\u201d APS March Meeting, Invited focus session talk.<\/li>\r\n<li>E. Chatterjee, W. Pan, D. Soh, \u201cAn RF photon-number-resolving detector using Majorana zero mode,\u201d APS March Meeting 2022, Invited focus session talk.<\/li>\r\n<li>E. Chatterjee, D. Soh, M. Eichenfield, \u201cHigh-fidelity qubit transfer between leaky memory blocks,\u201d APS March Meeting.\u00a0<\/li>\r\n<li>D. Soh, E. Chatterjee, C. Rogers, D. Gray, H. Mabuchi, \u201cOptical selection rules and optical nonlinearities of excitonic states in monolayer MoS2,\u201d APS 2019, C12. 003<\/li>\r\n<li>D. Soh, B. D. Patterson, S. E. Bisson, \u201cAn all-fiber high-energy cladding-pumped 93 nanosecond Q-switched fiber laser using a fiber saturable absorber,\u201d Photonics West 2014 LASE.<\/li>\r\n<li>S. W. Moore, D. Soh, S. E. Bisson, B. D. Patterson, W. L. Hsu, \u201cA high-energy cladding-pumped 80 nanosecond Q-switched fiber laser using a tapered fiber saturable absorber,\u201d Photonics West 2013 LASE.<\/li>\r\n<li>J. P. Koplow and D. Soh, \u201cThe 4FAD: a high-extinction-ratio,achromatic, temperature-insensitive, high-damage-threshold, all-fiber, power-selective filter,\u201d CLEO 2011, Baltimore, May 1-6, 2011, paper CMZ5.<\/li>\r\n<li>S. Moore, D. Soh, K. Schroder, and W. Hsu, \u201cSpectral beam compression and combination using fiber laser sources,\u201d Directed Energy Professional Society \u2013 24<sup>th<\/sup> Solid State and Diode Laser Technology Review (SSDLTR), Santa Fe, June 6-9, 2011.<\/li>\r\n<li>J. Kim, P. Dupriez, D. Soh, C. Codemard, S. Yoo, Y. Jeong, J. Nilsson, and J. K. Sahu, \u201cDepressed clad hollow optical fiber with the fundamental LP<sub>01<\/sub> mode cut-off,\u201d Photonics West 2006 San Jose 21-26 Jan 2006 6102-16.<\/li>\r\n<li>Y. Jeong, J. Nilsson, D. Soh, C. A. Codemard, P. Dupriez, C. Farrell, J. K.Sahu, J. Kim, S. Yoo, D. J. Richardson, and D. N. Payne, \u201cHigh power single-frequency Yb-doped fiber amplifiers,\u201d OFC 2006 Anaheim 5-10 Mar 2006 OThJ7 (Invited).<\/li>\r\n<li>\u00a0J. Nilsson, Y. Jeong, D. Soh, C. A. Codemard, P. Dupriez, C.Farell, J. K. Sahu, J. Kim, S. Yoo, and D. N. Payne, \u201cHigh-power fiber lasers: progress and opportunities,\u201d Proc. 14th International Laser Physics Workshop 2005 (LPHYS 2005) Kyoto 4-8 Jul 2005 PS5 (Plenary) .<\/li>\r\n<li>P. Dupriez, J. Nilsson, Y. Jeong, J. K. Sahu, C.Codemard, D. Soh, C. Farrell, J. Kim, A.Piper, A. Malinowski, D. J. Richardson, \u201cCurrent progress in high-power fiber lasers and amplifiers,\u201d Optical Amplifiers and their Applications (OAA) Budapest 7-10 Aug 2005 (Invited).<\/li>\r\n<li>J. Kim, D. Soh, C.Codemard, S. Yoo, Y. Jeong, J. Nilsson, J. K. Sahu, \u201cYb:Al-doped depressed clad hollow optical fiber laser operating at 980nm,\u201d CLEO\/IQEC Pacific Rim Tokyo 11-15 Jul 2005 CTuI4-5.<\/li>\r\n<li>D. Soh, A.B.Grudinin, J. Nilsson, Y. Jeong, S. Yoo, J. Kim, C.Codemard, P. Dupriez, \u201cStimulated Raman scattering effect on femtosecond pulse generation using a parabolic amplification and a pulse compressor,\u201d ONERA Scientific Day Paris 27-28 Jun 2005.<\/li>\r\n<li>Y. Jeong, J. Nilsson, J. K. Sahu, P. Dupriez, C. A. Codemard, D. Soh, C. Farrell, J. Kim, D. J. Richardson, D. N. Payne, \u201cHigh power fiber lasers,\u201d CLEO\/IQEC-Pacific Rim Tokyo 11-15 Jul 2005 CWI4-1-INV (Invited).<\/li>\r\n<li>Y. Jeong, J. K. Sahu, D. Soh, C.Codemard, J. Nilsson, \u201cTunable single-frequency ytterbium-sensitized erbium-doped fiber MOPA source with 150W (51.8 dBm) of output power at 1563 nm,\u201d OFC 2005 Anaheim 6-11 Mar 2005 PDP1 (Postdeadline).<\/li>\r\n<li>Y. Jeong, J. Nilsson, J. K. Sahu, D. Soh, P. Dupriez, C. A. Codemard, C. Farrell, J. Kim, D. J. Richardson, D. N. Payne, \u201cBeyond 1 kW, the rising power of fibre lasers,\u201d OECC Seoul 4-8 Jul 2005 8D1-1 (Invited).<\/li>\r\n<li>Y. Jeong, D. Soh, C. A. Codemard, P. Dupriez, C. Farrell, V.Philippov, J. K. Sahu, D.J.Richardson, J. Nilsson, D. N. Payne, \u201cState of the art of cw fibre lasers,\u201d CLEO\/Europe Munich 12-17 Jun 2005 TFII1-1-WED (Invited).<\/li>\r\n<li>J. Nilsson, J. K. Sahu, Y. Jeong, V. N. Philippov, D. Soh, C.Codemard, P. Dupriez, J. Kim, D. J. Richardson, A. Malinowski, A. N. Piper, J. H. V. Price, K. Furusawa, W. A. Clarkson, D. N. Payne, \u201cHigh power fiber lasers,\u201d OFC 2005 Anaheim 6-11 Mar 2005 OTuF1 (Invited).<\/li>\r\n<li>J. Kim, P. Dupriez, D. Soh, J. K. Sahu, J. Nilsson, D. N. Payne, \u201cNd:Al-doped depressed clad hollow fiber laser at 930 nm,\u201d ASSP 2005 Vienna 6-9 Feb 2005.<\/li>\r\n<li>D. Soh, J. Clowes, I. Godfrey, A. B. Grudinin, \u201cCompact 85 fs frequency doubled 810 nm fiber system with 60 mW of average power,\u201d Photonics West 2005 San Jose 22-27 Jan 2005.<\/li>\r\n<li>Y. Jeong, J. Nilsson, J. K. Sahu, D. Soh, C.Alegria, P. Dupriez, C. A. Codemard, D. N. Payne, R. Horley, L. M. B. Hickey, L. Wanzcyk, C. E. Chryssou, J. A. Alvarez-Chavez, P. W. Turner, \u201cSingle-frequency polarized ytterbium-doped fiber MOPA source with 264W output power,\u201d CLEO\/IQEC 2004 San Francisco 16-21 May 2004 CPDD1 (Postdeadline).<\/li>\r\n<li>C. Alegria, Y. Jeong, C. Codemard, J. K. Sahu, L. Fu, M. R. Mokhtar, M. Ibsen, S. Baek, D. Soh, V. Philippov, J. Nilsson, \u201cWideband tunable high power narrow linewidth erbium-ytterbium doped fiber laser using compression-tunable fiber Bragg grating,\u201d Photonics West San Jose 24-29 Jan 2004 SPIE Proc. 5335-43 pp.229.<\/li>\r\n<li>C. A. Codemard, L. M. B. Hickey, K. Yelen, D. Soh, R. Wixey, M. Coker, M. N. Zervas, J. Nilsson, \u201c400 mW 1060nm ytterbium doped fiber DFB laser,\u201d Photonics West 2004 San Jose 24-29 Jan 2004 SPIE Proc. 5335-11 pp.224.<\/li>\r\n<li>J. K. Sahu, Y. Jeong, C. Alegria, C. Codemard, D. Soh, S. Baek, V. Philippov, L. J. Cooper, J. Nilsson, R. B. Williams, M. Ibsen, W. A. Clarkson, D. J. Richardson, D. N. Payne, \u201cRecent advances in high power fiber lasers,\u201d ASSP 2004 New Mexico 1-4 Feb 2004 (Invited).<\/li>\r\n<li>Y. Jeong, J. K. Sahu, S. Baek, C. Alegria, D. Soh, C. Codemard, V. Philippov, D. J. Richardson, D. N. Payne, J. Nilsson, \u201cYtterbium-doped double-clad large-core fiber lasers with kW-level continuous-wave output power,\u201d CLEO\/IQEC 2004 San Francisco 16-21 May 2004 CMS.<\/li>\r\n<li>D. Soh, S. W. Yoo, J. Nilsson, J. K. Sahu, S. Baek, Y. Jeong, L. J. Cooper, C. Codemard, P. Dupriez, C. Alegria, V. Philippov, K. Oh, \u201cCladding pumped Nd-doped fiber laser tunable from 908 to 938 nm,\u201d CLEO\/IQEC 2004 San Francisco 16-21 May 2004 CMK.<\/li>\r\n<li>D. Soh, S. W. Yoo, J. K. Sahu, L. J. Cooper, S. Baek, K. Oh,\u201d A cladding pumped neodymium-doped fiber laser tunable from 932 nm to 953 nm,\u201d ASSP 2004 New Mexico 1-4 Feb 2004 MD9.<\/li>\r\n<li>D. Soh, C. Codemard, J. K. Sahu, J. Nilsson, V. Philippov, C. Alegria, Y. Jeong, \u201cA 4.3W 977 nm ytterbium-doped jacketed-air-clad fiber amplifier,\u201d ASSP 2004 New Mexico 1-4 Feb 2004 MA3.<\/li>\r\n<li>D. Soh, C. Codemard, J. K. Sahu, J. Nilsson, S. Baek, S. Wang, F. Laurell, \u201cAn 18 mW 488.7 nm cw frequency doubled fibre MOPA source,\u201d Photonics West 2004 San Jose 24-29 Jan 2004 SPIE Proc. 5335-10 pp.223.<\/li>\r\n<li>K. H. Yla-Jarkko, S. -U. Alam, P. W. Turner, J. Moore, J. Nilsson, R. Selvas, D. Soh, C. Codemard, J. K. Sahu, \u201cCladding pumping technology for next generation of fiber amplifiers and lasers,\u201d OAA 2003 Otaru 6-9 Jul 2003 TuC1 (Invited).<\/li>\r\n<li>V. Philippov, J. Nilsson, Y. Jeong, C. Alegria, D. Soh, C. Codemard, S. Baek, J. K. Sahu, W. A. Clarkson, D. N. Payne, \u201cVersatile and functional high power fiber sources,\u201d 2nd International Symposium on High-Power Fiber Lasers and Their Applications St Petersburg 1-3 Jul 2003 HPFL-2.4 (Invited).<\/li>\r\n<li>D. N. Payne, J. Nilsson, Y. Jeong, C. Alegria, V. Philippov, D. Soh, C. Codemard, S. Baek, J. K. Sahu, D. J. Richardson, W. A. Clarkson, \u201cThe revolution in high-power fiber lasers,\u201d 2nd International Symposium on High-Power Fiber Lasers and Their Applications St Petersburg 1-3 Jul 2003 HPFL-1.2 (Invited).<\/li>\r\n<li>Y. Jeong, J. K. Sahu, S. Baek, C.Alegria, C. A. Codemard, D. Soh, V. Philippov, R. B. Williams, K. Furusawa, D. J. Richardson, D. N. Payne, J. Nilsson, \u201cThe rising power of fibre lasers,\u201d IEEE\/LEOS 2003 Arizona 26-30 Oct 2003 ThD1 (Invited).<\/li>\r\n<li>J. Nilsson, Y. Jeong, C. Alegria, V. Philippov, D. Soh, C. Codemard, S. Baek, J. K. Sahu, D. J. Richardson, W. A. Clarkson, D. N. Payne, \u201cFiber lasers: flexible and functional solutions for today and the future,\u201d Third International Symposium on Laser and Nonlinear Optical Materials (ISLNOM) Colorado 20-24 Jul 2003 (Invited).<\/li>\r\n<li>K. H. Yla-Jarkko, R. Selvas, D. Soh, J. K. Sahu, C. A. Codemard, J. Nilsson, S. -U. Alam, A. B. Grudinin, \u201cA 3.5 W 977 nm cladding-pumped jacketed air-clad ytterbium-doped fiber laser,\u201d OSA TOPS: Proc ASSP 2003 83 pp.103-7 John J Zayhowski, ed. (Postdeadline).<\/li>\r\n<li>C. Codemard, D. Soh, K. Yla-Jarkko, J. K. Sahu, M. Laroche, J. Nilsson, \u201cCladding-pumped L-band phosphosilicate erbium-ytterbium co-doped fiber amplifier,\u201d OAA 2003 Otaru Japan 6-9 Jul 2003 TuC2.<\/li>\r\n<\/ol>\r\n<p>&nbsp;<\/p>\r\n<hr \/>\r\n<h3>Books<\/h3>\r\n<ol>\r\n<li>Daniel Soh, <em>Photonic Quantum Information Processing<\/em>, CRC Press (Taylor &amp; Francis Group), London, 2026 (in press).\u00a0<\/li>\r\n<\/ol>\r\n<hr \/>\r\n<h3>Patents<\/h3>\r\n<ol>\r\n<li>US Patent 12038285, Hybrid inertial navigation system and method, J. Lee, D. Soh (Sandia National Labs)<\/li>\r\n<li>US Patent 12029141, Systems and methods for resolving a number of incident RF-range photons, D. Soh, W. Pan, E. Chatterjee (Sandia National Labs)<\/li>\r\n<li>US Patent 11343088, Systems and methods for quantum optical device authentication, D. Soh, S. E. Bisson (Sandia National Labs)<\/li>\r\n<li>US Patent 11226502, Photonic integrated circuits for generating high-brightness squeezed light, D. Soh, M. Eichenfield, C. Long (Sandia National Labs)<\/li>\r\n<li>US Patent 11177890, Remote quantum state transfer for qubits with different frequencies, D. Soh, M. Eichenfield (Sandia National Labs)<\/li>\r\n<li>US Patent 10341015, Secure fiber optic seals enabled by quantum optical communication concepts, M. Sarovar, D. Farley, D. Soh, R. Camacho, C. Brif (Sandia National Labs)<\/li>\r\n<li>US Patent 9964431, Narrow bandwidth detection of vibration signature using fiber lasers, S. Moore and D. Soh (Sandia National Labs)<\/li>\r\n<li>US Patent 9906311, Transceivers and receivers for quantum key distribution and methods pertaining thereto, C. DeRose, M. Sarovar, D. Soh, A. Lentine, P. Davids, R. Camacho (Sandia National Labs)<\/li>\r\n<li>US Patent 9553677, Self-referenced continuous-variable quantum key distribution, D. Soh, M. Sarovar, R. Camacho (Sandia National Labs)<\/li>\r\n<li>US Patent 9500930, On-chip entangled photon source, D. Soh and S. Bisson (Sandia National Labs)<\/li>\r\n<li>US Patent 9465274, High yield entangled photons, D. Soh and S. Bisson (Sandia National Labs)<\/li>\r\n<li>US Patent 9031098, All Fiber Passively Q-switched Laser, D. Soh and S. Bisson (Sandia National Labs).<\/li>\r\n<li>US Patent 8730568, Generating Laser Pulses Based on Chirped Pulse Amplification, S. Tong, J. Prawiharjo, H. Cong, D. Soh, L. West, and A. H. Lin (Calmar Laser Inc.)<\/li>\r\n<li>US Patent 7991022, Optical Pulse Amplification based on Stimulated Raman Scattering, D. Soh and T. H. Lin (Calmar Laser Inc.)<\/li>\r\n<li>US Patent 7573918, Dispersion Compensated Mode-Locked Pulsed Lasers and Optical Amplifiers, D. Soh and T. H. Lin (Calmar Laser Inc.)<\/li>\r\n<\/ol>\r\n<hr \/>\r\n<h3>\u00a0<\/h3>\r\n<p>&nbsp;<\/p>\r\n","protected":false},"excerpt":{"rendered":"","protected":false},"author":91,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"categories":[],"tags":[],"class_list":["post-14","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/wp.optics.arizona.edu\/danielsoh\/wp-json\/wp\/v2\/pages\/14","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/wp.optics.arizona.edu\/danielsoh\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/wp.optics.arizona.edu\/danielsoh\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/wp.optics.arizona.edu\/danielsoh\/wp-json\/wp\/v2\/users\/91"}],"replies":[{"embeddable":true,"href":"https:\/\/wp.optics.arizona.edu\/danielsoh\/wp-json\/wp\/v2\/comments?post=14"}],"version-history":[{"count":32,"href":"https:\/\/wp.optics.arizona.edu\/danielsoh\/wp-json\/wp\/v2\/pages\/14\/revisions"}],"predecessor-version":[{"id":280,"href":"https:\/\/wp.optics.arizona.edu\/danielsoh\/wp-json\/wp\/v2\/pages\/14\/revisions\/280"}],"wp:attachment":[{"href":"https:\/\/wp.optics.arizona.edu\/danielsoh\/wp-json\/wp\/v2\/media?parent=14"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/wp.optics.arizona.edu\/danielsoh\/wp-json\/wp\/v2\/categories?post=14"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/wp.optics.arizona.edu\/danielsoh\/wp-json\/wp\/v2\/tags?post=14"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}