1 Daniel Wasserman University of Texas Austin Dept. of Electrical and Computer Engineering Microelectronics Research Center Austin, TX 78758 (512) 471-9818 [email protected]EDUCATION Princeton University, Princeton, NJ Ph.D. in Electrical Engineering M.A. in Electrical Engineering 2004 2000 Dissertation: “Quantum Dots: Mid-Infrared Luminescence, (110) Growth, Single-Dot Luminescence and Cleaved Edge Overgrowth” Brown University, Providence, RI Sc.B. Honors in Engineering/Physics 1998 Areas of Concentration: Engineering/Physics, History Honors: Magna Cum Laude , Phi Beta Kappa-1997, top 3% of graduating class, Sigma Xi, with Honors EMPLOYMENT University of Texas Austin Associate Professor, Department of Electrical and Computer Engineering 8/2016- University of Illinois Urbana Champaign, Urbana, IL Associate Professor, Department of Electrical and Computer Engineering 7/2015-8/2016 Assistant Professor, Department of Electrical and Computer Engineering 7/2011-7/2015 University of Massachusetts Lowell, Lowell, MA Assistant Professor, Associate-Director of Photonics Center 2007–2011 Princeton University, Princeton, NJ Post-Doctoral Research Fellow 2004–2007 FELLOWSHIPS AND AWARDS Fellow, Optical Society of America 2018 Mr. N. Doug Williams Memorial Centennial Fellowship in Engineering 2018 IEEE Photonics Society Distinguished Lecturer 2017-2018 UIUC Distinguished Promotion Award NSF CAREER Award AFOSR Young Investigator Award UIUC College of Engineering Outstanding Advisor Award UIUC Instructors ranked as Excellent (ECE329 F’12, ECE198 S’13, F’14, ECE574 S’15, S’16) UML Department of Physics Excellence in Teaching Award Council on Science and Technology Postdoctoral Teaching Fellowship, Princeton University National Science Foundation Graduate Fellowship Francis Upton Graduate Fellowship, Princeton University 2015 2011 2010 2012/2013 2012-2015 2010 2004–2007 1998–2002 1998–2002 TEACHING University of Texas at Austin, Austin, TX Instructor – EE383V, Quantum Electro-Optics F’18 Instructor- EE302, Introduction to Electrical Engineering F’17 Instructor- EE325, Engineering Electromagnetics with Mathematica S’17,’18,’19 Instructor – Senior Design F’16, S’17 Course Development –EE325, Engineering Electromagnetics with Mathematica F’16 University of Illinois Urbana Champaign, Urbana, IL Course Development –ECE329P, Fields and Waves with Mathematica F’15
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“Investigating coherent filtering of mid-IR light”, Sandia National Labs, PI, 32.5K 2019
DARPA Nascent Light-Matter Interactions: “Harnessing the ultimate limits of light-matter interactions with polaritonic metamaterials” co-PI, Phase I 46K
Senior Member of IEEE, Fellow of OSA. IEEE EDS Optoelectronic Devices Technical Committee (2015-2019)
INVITED TALKS
EDSSC, Taiwan October, 2017
Conference on Lasers and Electro-Optics (CLEO), San Jose, CA June, 2017
AVS Symposium, Nashville, TN November, 2016
NG Next, Integrated Photonics Workshop Huntington Beach, CA October, 2016
North American Molecular Beam Epitaxy Conference (NAMBE), Saratoga Springs, NY
September, 2016
Conference on Lasers and Electro-Optics (CLEO), San Jose, CA June, 2016
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MRS Fall Meeting, Boston, MA November, 2015
MRS Spring Meeting, San Francisco, CA April, 2015
IEEE Summer Topicals, Montreal, CA July, 2014 Device Research Conference, Santa Barbara, CA June, 2014 NSF EPMD CAREER Workshop May, 2014 SPIE Optics and Photonics, San Diego, CA, “Engineered Metals for Mid-IR
Plasmonics” August 2013
SPIE Optics and Photonics, San Diego, CA, “Selective Thermal Emission from thin-film metasurfaces”
August 2013
National Science Foundation Workshop, Prague, CZ , “Mid-IR Photonics” April 2013
Physics of Quantum Electronics 2013, Snowbird, UT, “Designer Mid-IR Metals” January 2013
Abdus Salam International Centre for Theoretical Physics "Workshop on Nanophotonics", Trieste, IT: “Mid-IR Plasmonics”
December 2012
SPIE Photonics Asia, Beijing, China: “Making the mid-infrared nano with plasmonics and metamaterials”
November 2012
Center for Nanoscale Science and Technology (CNST), University of Illinois: “Making the mid-infrared nano with plasmonics and metamaterials”
“Build Your Own Optical Communication System”, Austin Urban Scholars March 2019
“Heat Check Yourself: Real time thermal imaging”, UT Girl Day Feb. 2018, 2019
“Build Your Own Optical Communication System”, Principal Scholars Program Dec. 2015
“Jell-O Optics”, Campus Middle School for Girls Dec. 2015
“Hands-On Nanotechnology Activity”, Principal Scholars Program. Dec. 2014
“Build Your Own Optical Communication System”, Campus Middle School for Girls Dec. 2014
“Build Your Own Hard Drive” activity day, Principal Scholars Program. November 2013
Planned, developed, and ran Physics Activity Days at UML Photonics Center for Lowell High Students: science activity, a facilities tour, and LN2 ice cream.
2008, -10, -11
Gear Up Science Activity: Build Your Own Hard Drive October, 2007
Taught Lowell High Physics Class “Physics of the Curveball” November, 2007
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Princeton University: Developed, organized, and ran Engineering Activity Days
(2006, 2007) for Lawrence, Trenton high students, tables for Science and
Engineering Expo (2004-2006).
2004–2007
STUDENTS
Post-Doc
Researchers
Prof. Stephanie Law, 2011-2014, currently Asst. Prof. at University of Delaware
Dr. Yujun Zhong, 2014-2016
Shaohua Wang, Visiting Scholar, 2016-2017
Current Sukrith Dev (5 th year, PhD)
Leland Nordin (4 th year, PhD)
Zuoming Dong (4 th year, PhD)
Kun Li (4 th year, PhD)
Abhilasha Kamboj (4 th year, PhD)
Priyanka Petluru (3rd year, PhD)
Yinan Wang (3rd year, PhD)
David Silva (2nd yr PhD)
Former Narae Yoon, Ph.D., 2019, Intel, Austin TX
William Streyer, Ph.D. 2016, IGB UIUC
Runyu Liu, Ph.D. 2016, Apple
Lan Yu, Ph.D. 2016, IBM
Daniel Zuo, Ph.D. 2015, Night Vision Labs
Aaron Rosenberg, MS 2014 Nova Research Inc.
Andrew Taylor, MS 2013, Lockheed Martin
Troy Ribaudo Ph.D 2011, Currently at Lam Research
David Adams Ph.D 2012, Instructor of Medicine, Harvard Medical School
UML Press Releases and Publications: 2008 UML Research Magazine, UML Shuttle April 2008, UML
Alumni Magazine Summer 2010.
PEER REVIEWED PUBLICATIONS
1. “Electrical modulation of degenerate semiconductor plasmonic interfaces“, Z. Dong, R.K. Vinnakota, A.F. Briggs, L. Nordin, S.R. Bank, D.A. Genov, and D. Wasserman, J. Appl. Phys., 126, 043101 (2019).
2. Invited Tutorial: “Probing Polaritons in the Mid - to Far-Infrared”, T. Folland, L. Nordin, D. Wasserman, and J. Caldwell, J. Appl. Phys., 125, 191102 (2019).
Nordin, Junchi Lu, Kaijun Feng, Daniel Wasserman, and Anthony J. Hoffman, Adv. Opt. Mater. 1800826 (2019).
4. “Measurement of Carrier Lifetime in Micron-Scaled Materials using Resonant Microwave Circuits”, S. Dev, Y. Wang, K. Kim, M. Zamiri, C. Kadlec, M. Goldflam, S. Hawkins, E. Shaner, J. Kim, S. Krishna, M. Allen, J. Allen, E. Tutuc, and D. Wasserman, Nat. Commun., 10, 1625 (2019).
5. “Design and growth of multi-functional InAsP metamorphic buffers for mid-infrared quantum well lasers on InP”, D. Jung, L. Yu, S. Dev, D. Wasserman, M.L. Lee, J. Appl. Phys., 125 082537 (2019)
6. “Measuring molecular transport through polymer films with dual-band plasmonic antennas”, H. Chen, F. Neubrech, R. Liu, J.S. Katz, S. Matteucci, S.G. Arturo, D. Wasserman, H. Giessen, and P.V. Braun, Submitted
7. “Metal germanides for practical on-chip plasmonics in the mid infrared“, E.M. Smith, W.H. Streyer, N. Nader, S. Vangala, G. Grzybowski, R. Soref, D. Wasserman, and J.W. Cleary, Opt. Mater. Express, 8, 968 (2018)
8. “Ultra-thin enhanced-absorption long-wave infrared detectors”, S. Wang, N. Yoon, A. Kambo j, P. Petluru, W. Zheng, and D. Wasserman, Applied Physics Letters, 112 091104 (2018).
9. “Optical Mapping of RF Field Profiles in Resonant Microwave Circuits”, Sukrith Dev, Runyu Liu, Jeffery W. Allen, Monica S. Allen, Brett R. Wenner and Daniel Wasserman, IEEE Photon. Technol. Lett., 30, 331 (2018).
10. “Next generation mid-infrared sources”, D. Jung, S. Bank, M.L. Lee, and D. Wasserman, J. Opt., 19 123001 (2017).
11. “Damage-Free Smooth-Sidewall InGaAs Nanopillar Array by Metal -Assisted Chemical Etching“, L. Kong, Y. Song, J.D. Kim, L. Yu, D. Wasserman, W. K. Chim, S.Y. Chiam, and X. Li, ACS Nano, 11(10), 10193 (2017).
12. “Mid-infrared epsilon-near-zero modes in ultra-thin phononic films“, L. Nordin, O. Dominguez, C. M. Roberts, W. Streyer, K. Feng, Z. Fang, V. A. Podolskiy, A. J. Hoffman, and D. Wasserman, Appl. Phys. Lett. 111, 091105 (2017).
13. “Modified electron beam induced current technique for in(Ga)As/InAsSb superlattice infrared detectors“, N. Yoon, C. J. Reyner, G. Ariyawansa, J. M. Duran, J. E. Scheihing, J. Mabon, and D. Wasserman, J. Appl. Phys., 122, 074503 (2017).
14. "Palladium Germanides for Mid- and Long-Wave Infrared Plasmonics", E. M. Smith, W. H. Streyer, N. Nader, S. Vangala, R. Soref, D. Wasserman, and J.W. Cleary, MRS Advances , pp. 1 -6 (2017).
15. “Mid-wave infrared narrow bandwidth guided mode resonance notch filter“, Y. Zhong, Z. Goldenfeld, K. Li, W. Streyer, L. Yu, L. Nordin, N. Murphy, and D. Wasserman, Opt. Lett. 42(2), 223 -226 (2017).
16. “Engineering carrier lifetimes in type-II In(Ga)Sb/InAs mid-IR emitters“, Lan Yu, Yujun Zhong, Sukrith Dev and Daniel Wasserman, Journal of Vacuum Science and Technology B, 35, 02B101 (2017).
17. “Enhanced responsivity resonant RF photodetectors“, R. Liu, S. Dev, Y. Zhong, R. Lu, W. Streyer, J.W. Allen, M.S. Allen, B. R. Wenner, S. Gong, and D. Wasserman, Optics Express, 24, 26044 -26054 (2016).
18. “Room-temperature mid-infrared quantum well lasers on multi -functional metamorphic buffers“, D. Jung, L. Yu, S. Dev, D. Wasserman and M.L. Lee, Applied Physics Letters, 109, 211101 (2016).
19. “Epsilon Near Zero Photonic Wires”, R. Liu, C. M. Roberts, Y. Zhong, V.A. Podolskiy, and D. Wasserman, ACS Photonics, 3(6), 1045-1052 (2016).
20. “Multiplexed infrared photodetection using resonant radio -frequency circuits” R. Liu, R. Lu, C. Roberts, S. Gong, J. W. Allen, M. S. Allen, B. R. Wenner, and D. Wasserman, Appl. Ph ys. Lett., 108, 061101 (2016).
21. Invited: “Engineering the Reststrahlen Band with Hybrid Plasmon/Phonon Excitations”, W. Streyer, K. Feng, Y. Zhong, A.J. Hoffman, and D. Wasserman, MRS Communications, 6, 1-8 (2016).
22. “Buried Extraordinary Optical Transmission Gratings”, R. Liu, X. Zhao, C. Roberts, X. Li, V. Podolskiy, and D. Wasserman, Advanced Materials, 28, 1441 (2016).
23. “Mid-infrared electroluminescence from InAs type-I quantum wells grown on InAsP/InP metamorphic buffers”, D. Jung, L. Yu, D. Wasserman, M. L. Lee, J. Appl. Phys., 118, 183101 (2015).
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24. Invited Review: “Photonic Materials, Structures and Devices for Reststrahlen Band Optics”, K. Feng, W. Streyer, Y. Zhong, A.J. Hoffman, and D. Wasserman, Optics Express , 23, A1418 (2015).
25. "Selective absorbers and thermal emitters for far-infrared wavelengths ", W. Streyer, K. Feng, Y. Zhong, A.J. Hoffman, and D. Wasserman, Appl. Phys. Lett., 107, 081105 (2015)
26. "Localized surface phonon polariton resonances in polar gallium nitride" , K. Feng, W. Streyer, S.M. Islam, J. Verma, D. Jena, D. Wasserman and A.J. Hoffman, Appl. Phys. Lett., 107, 081108 (2015)
27. “Direct Minority Carrier Transport Characterization of InAs/InAsSb Superlattice nBn Photodetectors”, D. Zuo, R. Liu, D. Wasserman, J. Mabon, Z.-Y. He, S. Liu, Y.-H. Zhang, E.A. Kadlec, and E.A. Shaner, Appl. Phys. Lett., 106, 071107 (2015).
28. “Platinum germanides for mid- and long-wave infrared plasmonics”, J.W. Cleary, W.H. Streyer, N. Nader, S. Vangala, I. Avrutsky, B. Claflin, J. Hendrickson, D. Wasserman, R.E. Peale , W. Buchwald, R. Soref, Optics Express, 23, 3316-3326 (2015).
29. Invited Review: “Mid-Infrared Plasmonic Materials”, Y. Zhong, S. Malagari, T. Hamilton, and D. Wasserman, J. Nanophotonics, 9(1), 093791 (2015).
30. “Mid-infrared emission from In(Ga)Sb layers on InAs(Sb)”, R. Liu, Y. Zhong, L. Yu, H. Kim, S. Law, J.-M. Zuo, and D. Wasserman, Optics Express, 22, 24466 (2014).
31. “Controlling quantum dot energies using submonolayer bandstructure engineering”, L. Yu, D. Jung, S. Law, J. Shen, J.J. Cha, M.L. Lee, D. Wasserman, Appl. Phys. Lett., 105, 081103 (2014).
32. “Design, Fabrication, and Characterization of Near-IR Gold Bowtie Nanoantenna Arrays”, H. Chen, A.M. Bhuiya, R. Liu, D. Wasserman, and K.C. Touissant, Jr., J. Phys. Chem. C, 118, 20553 (2014).
33. “Editorial: Special issue on mid-infrared and THz photonics”, D. Wasserman, R. Singh, and T. Akalin, Invited Editorial, J. Opt., 16, 090201 (2014)
34. “Doped semiconductors with Band-Edge Plasma Frequencies”, S. Law, R. Liu, D. Wasserman, J. Vac. Sci. Technol. B, 32, 05260 1-7 (2014).
35. Invited: “Flat mid-infrared composite plasmonic materials using lateral doping -patterned semiconductors”, A. Rosenberg, J. Surya, R. Liu, W. Streyer, S. Law, L.S. Leslie, R. Bhargava, and D. Wasserman, J. Opt., 16, 094012 (2014).
36. "Engineering absorption and blackbody radiation in the far-infrared with surface phonon polaritons on gallium phosphide", W. Streyer, S. Law, A. Rosenberg, C. Roberts, V.A. Podolskiy, A.J. Hoffman, and D. Wasserman, Appl. Phys. Lett., 104, 131105 (2014).
37. "ENZ-Enhanced Light Transmission through a Subwavelength Slit", S. Inampudi, D. C. Adams, T. Ribaudo, D. Slocum, S. Vangala, W.D. Goodhue, D. Wasserman, and V. A. Podolskiy, Phys. Rev. B, 89, 125119 (2014).
38. “All-Semiconductor Plasmonic Perfect Absorbers”, S. Law, T. Kilpatrick, L. Yu, T. Ribaudo, C. Roberts, V.A. Podolskiy, E.A. Shaner, and D. Wasserman, Phys. Rev. Lett., 112, 017401 (2014).
39. "All-Semiconductor Plasmonic Nanoantennas for Infrared Sensing", S. Law, L. Yu, A. Rosenberg, and D. Wasserman, Nano Lett., 13, 4560 (2013).
40. "Degenerately doped InGaBi:As as a highly conductive and transparent contact material in the infrared range", Y. Zhong, P.B. Dongmo, L. Gong, S. Law, B. Chase, D. Wasserman, and J.M.O. Zide, Optics Materials Express, 3, 1197 (2013).
41. "Wafer-Scale Production of Uniform InAsyP1-y Nanowire Array on Silicon for Heterogeneous Integration", J.C. Shin, A. Lee, P.K. Mohseni, D.Y. Kim, L. Yu, J.H. Kim, H.J. Kim, W.J. Choi, D. Wasserman, K.J. Choi, X. Li, ACS Nano (2013)
42. "Direct observation of minority carrier lifetime improvement in InAs/GaSb type-II superlattice photodiodes via interfacial layer control", D. Zuo, P. Xiao, D. Wasserman, and S.L. Chuang, Appl. Phys. Lett., 102, 141107 (2013)
43. "Strong absorption and selective emission from engineered metals with thin dielectric films", W. Streyer, S. Law, T. Jacobs, G. Rooney, and D. Wasserman, Optics Express, 21, 9113 (2013).
44. “Near-field infrared absorption of plasmonic semiconductor microparticles studied using atomic force microscope infrared spectroscopy”, J. Felts, S. Law, C.M. Roberts, V.A. Podolskiy, D. Wasserman, and W.P. King, Appl. Phys. Lett., 102, 152110 (2013).
45. "Epitaxial growth of engineered metals for mid-infrared plasmonics", S. Law, L. Yu, D. Wasserman, J. Vac. Sci. Technol. B, 31, 03C121 (2013).
46. Invited Review: “Towards nano-scale photonics with micro-scale photons: The opportunities and challenges of mid-infrared plasmonics”, S. Law, V. Podolskiy, and D. Wasserman, Nanophotonics, 2, 104 (2013)
47. “2.8µm emission from type-I quantum wells grown on InAsxP1-x/InP metamorphic graded buffers”, D. Jung, Y. Song, L. Yu, D. Wasserman, and M.L. Lee, Appl. Phys. Lett., 101, 251107 (2012)
48. “Electroluminescence from quantum dots fabricated with nanosphere lithography”, L. Yu, S. Law, and D. Wasserman, Appl. Phys. Lett., 101, 103105 (2012).
49. “Mid-infrared designer metals”, S. Law, D.C. Adams, A.M. Taylor, and D. Wasserman, Optics Express, 20, 12155 (2012).
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50. “Strong coupling of molecular and mid-infrared perfect absorber resonances”, J.A. Mason, G. Allen, V. Podolskiy, and D. Wasserman, IEEE Photonics Technology Letters, 24, 31 (2012).
51. “Enhanced Light Funneling Through Subwavelength Apertures Using Epsilon Near Zero Metamaterials”, D.C. Adams, N. Inampudi, T. Ribaudo, D. Slocum, N. Kuhta, S. Vangala, W. Goodhue, V.A. Podolskiy, and D. Wasserman, Phys. Rev. Lett., 107, 133901 (2011).
52. “Voltage-controlled active mid-infrared plasmonic devices”, K. Anglin, T. Ribaudo, D.C. Adams, X. Qian, W.D. Goodhue, S. Dooley, E.A. Shaner and D. Wasserman, Journal of Applied Physics, 109, 123103 (2011).
53. “Strong absorption and selective thermal emission from midinfrared metamaterials”, J.A. Mason, S. Smith, and D. Wasserman, Applied Physics Letters, 98, 241105 (2011).
54. “Multiscale beam evolution and shaping in corrugated plasmonic structures”, S. Thongrattanasiri, D.C. Adams, D. Wasserman and V. Podolskiy,Optics Express, 19, 9269 (2011).
55. “Observation of Rabi-Splitting from Surface Plasmon Coupled Conduction-State Transitions in Electrically-Excited InAs Quantum Dots”, B.S. Passmore, D.C. Adams, T. Ribaudo, P. Davids, W.W. Chow, S.A. Lyon, D. Wasserman, and E.A. Shaner, Nano-Letters, 11, 338 (2011).
56. “Selective Thermal Emission from Patterned Steel Substrates”, J. Mason, D.C. Adams, Z. Johnson, S. Smith, A.W. Davis, and D. Wasserman, Opt. Express, 18, 25912 (2010).
57. “Plasmonic mid-infrared beam steering”, D.C. Adams, S. Thongrattanasiri, T. Ribaudo, V. Podolskiy, and D. Wasserman, Appl. Phys. Lett., 96, 201112 (2010).
58. "High-optical-quality nanosphere lithographically formed InGaAs quantum dots using molecular beam epitaxy assisted GaAs mass transport and overgrowth", X. Qian, S. Vangala, D. Wasserman, and W.D. Goodhue., J. Vac. Sci. Technol. B, 28(3), C3C9 (2010).
59. “Mid-infrared doping tunable transmission through subwavelength metal hole arrays on InSb”, B.S Passmore, D.G. Allen, S. R. Vangala, W.D. Goodhue, D. Wasserman, and E.A. Shaner, Optics Express, 17 10223 (2009).
60. “Active Control and Spatial Mapping of Midinfrared Propagating Surface Plasmons”, T. Ribaudo, S.S. Howard, C. Gmachl, X. Wang, F.-S. Choa, and D. Wasserman, Opt. Express, 17, 7019 (2009).
61. “Spectral and spatial investigation of mid-infrared surface waves on a plasmonic grating”, T. Ribaudo, D.C. Adams, B. Passmore, E.A. Shaner and D. Wasserman, Appl. Phys. Lett. 94, 201109 (2009).
62. “Room temperature electroluminescence from InAs quantum dots”, D. Wasserman, T. Ribaudo, S.A. Lyon, S.K. Lyo, and E.A. Shaner, Appl. Phys. Lett., 94, 061101 (2009).
63. “Loss mechanisms in mid-infrared extraordinary optical transmission gratings”, T. Ribaudo, K. Freitas, E.A. Shaner, J.G. Cederberg, D. Wasserman, Opt. Express 17 666 (2009).
64. High k-space lasing in a dual-wavelength quantum cascade laser”, K.J. Franz, S. Menzel, A.J. Hoffman, D. Wasserman, J.W. Cockburn and C. Gmachl, Nature Photonics, 3, 50 (2009).
65. “Uniform InGaAs quantum dot arrays fabricated using nanosphere lithography”, X. Qian, J. Li, D. Wasserman, W.D. Goodhue, Appl. Phys. Lett. 93 231907 (2008).
66. “High-performance quantum cascade lasers. Optimized design through waveguide and thermal modeling”, S.S. Howard, Z. Liu, D. Wasserman, A.J Hoffman, T.S. Ko, C.F. Gmachl, IEEE J. Sel. Top. in Quant. Elect., 13, 1054 (2007).
67. “Current-tunable mid-infrared extraordinary transmission gratings”, E.A. Shaner, J. Cederberg, D. Wasserman, Appl. Phys. Lett., 91, 181110 (2007).
68. “Mid-Infrared doping tunable extraordinary transmission from sub-wavelength gratings”, D. Wasserman, E.A. Shaner, and J.G. Cederberg, Appl. Phys. Lett., 90, 191102 (2007).
69. “Negative Refraction in Semiconductor Metamaterials” A.J. Hoffman, L. Alekseyev, S.S. Howard, K.J. Franz, D. Wasserman, V.A. Podolskiy, E.E. Narimanov, D.L. Sivco, and C. Gmachl, Nature Materials, 6, 946 (2007)
70. “Narrow width, low-ridge configuration for high-power quantum cascade lasers”, A. Lyahk, P. Zory, D. Wasserman, G. Shu, C. Gmachl, D. Bour Appl. Phys. Lett., 90, 141107 (2007)
71. “Evidence of cascaded emission in a dual-wavelength quantum cascade laser”, K.J. Franz, D. Wasserman, A.J. Hoffman, D.C. Jangraw, K.-T, Shiu, S.R. Forrest, and C. Gmachl, Appl. Phys. Lett., 90, 091104 (2007).
72. “Multiple wavelength polarized mid-infrared emission from InAs quantum dots”, D. Wasserman, C. Gmachl, S.A. Lyon, and E.A. Shaner, Appl. Phys. Lett., 88, 191118 (2006).
73. “Room Temperature Continuous-wave Quantum Cascade Lasers Grown by MOCVD without Lateral Regrowth”, Z. Liu, D. Wasserman, S.S. Howard, A.J. Hoffman, C. Gmachl, X. Wang, T. Tanbun-Ek, L. Cheng, and Fow-Sen Choa, IEEE Photonics Technology Letters, 18, 1347 (2006).
74. “Anomalous spin polarization of GaAs two-dimensional hole systems”, R. Winkler, E. Tutuc, S.J. Papadakis, S. Melinte, M. Shayegan, D. Wasserman, and S.A. Lyon, Phys. Rev. B, 72, 195321 (2005).
75. “Stimulated electronic Anti-Stokes Raman emission in Quantum Cascade lasers”, A. A Gomez-Iglesias, D. Wasserman, C. Gmachl, A. Belyanin, and D.L. Sivco, Appl. Phys. Lett., 87, 261113 (2005).
76. “6 nm half-pitch lines and 0.04μm2 static random access memory patterns by nanoimprint lithography”, M.D. Austin, W. Zhang, H.X. Ge. D. Wasserman, S.A. Lyon, and S.Y. Chou, Nanotech., 8, 1058 (2005).
77. “Cleaved-edge overgrowth of aligned quantum dots on strained layers of InGaAs”, D. Wasserman and S. A. Lyon, Appl. Phys.Lett., 85, 5352 (2004).
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78. “Scanning near-field photoluminescence mapping of (110) InAs-GaAs self-assembled quantum dots”, M. Hadjipanayi, A.C. Maciel, J.F. Ryan, D. Wasserman, and S.A. Lyon, Appl. Phys. Lett., 85, 2535 (2004).
79. “Fabrication of 5nm linewidth and 14 nm pitch features by nanoimprint lithography”, Michael D. Austin, Haixiong Ge, Wei Wu, Mingtao Li, Zhaoning Yu, D. Wasserman, S.A. Lyon, and Stephen Y. Chou, Appl. Phys. Lett., 84, 5299 (2004).
80. “Formation of self-assembled quantum dots on (110) GaAs Substrates”, D. Wasserman, S.A. Lyon, M. Hadjipanayi, A. Maciel, and J .F. Ryan, Appl. Phys. Lett.. 83, 5050 (2003).
81. “Negative differential Rashba effect in two-dimensional hole systems”, B. Habib, E. Tutuc, S. Melinte, M. Shayegan, D. Wasserman, S.A. Lyon, and R. Winkler, Appl. Phys. Lett., 85, 3151 (2004).
82. “Characterization of GaAs grown by molecular beam epitaxy on vicinal Ge(100) substrates”, A. Wan, V. Menon, S.R. Forrest, D. Wasserman, S. A. Lyon, and A. Kahn, J. Vac. Sci. Technol. B, 22, 1893 (2004).
83. “Spin splitting in GaAs (100) two-dimensional holes”, B. Habib, E. Tutuc, S. Melinte, M. Shayegan, D. Wasserman, S. A. Lyon, and R. Winkler, Phys. Rev. B, 69, 113311 (2004).
84. “Mid-infrared luminescence from InAs quantum dots in unipolar devices”, D. Wasserman and S.A. Lyon, Appl. Phys. Lett., 81, 2848 (2002).
85. Mid-infrared electroluminescence from InAs quantum dots in p-n junctions and unipolar tunneling structures” D. Wasserman and S.A. Lyon, Physica Status Solidi B, 224, 585 (2001).
86. “Probing dopant incorporation in InAs/GaAs QDIPs by polarization-dependent Fourier transform infrared spectroscopy”, Z. Zhao, C. Yi, A.D. Stiff-Roberts, A.J. Hoffman, D. Wasserman, C. Gmachl, Infrared Physics & Technology, 51 131 (2007).
87. “DX-like centers in InAs/GaAs QDIPs observed by polarization-dependent Fourier transform infrared spectroscopy”, Z. Zhao, C. Yi, A.D. Stiff-Roberts, A.J. Hoffman, D. Wasserman, C. Gmachl, J. Vac. Sci. & Technol. B, 25 1108 (2007).
CONFERENCE PROCEEDINGS
1. “Extending the Operating Wavelength of Type-I InAs Quantum Well Lasers on InP”, M.L. Lee, D. Jung, L. Yu, S. Dev, D. Wasserman, Advanced Photonics Congress, Novel Optical Materials and Applications, Paper# NoW3C.4 (2017).
2. “Exciting Localized Modes in Polar Epsilon-Near-Zero Materials”, O. Dominguez, L.J. Nordin, K. Feng, J. Lu, D. Wasserman, A.J. Hoffman, CLEO: Applications and Technology, Paper# JTh2A.113 (2017).
3. “Temperature Dependent Diffusion Characterization of In(Ga)As/InAsSb Type-II Superlattice Infrared Detectors”, N. Yoon, C.J. Reyner, G. Ariyawansa, J.E. Scheihing, J. Mabon, D. Wasserman, CLEO: Science and Innovations, Paper# STh3I.6 (2017)
4. “New Sources and Sensors for Mid- to Far-IR Optical Sensing”, L. Yu, D. Jung, S. Dev, N. Yoon, L. Nordin, A.J. Hoffman, M.L. Lee, D. Wasserman, CLEO: Applications and Technology, Paper# AM2B.1 (2017).
5. “Growth and characterization of In1-xGaxAs/InAs0.65Sb0.35 strained layer superlattice infrared detectors”, G. Ariyawansa, J. M. Duran, C. J. Reyner, E. H. Steenbergen, N. Yoon, D. Wasserman, J. E. Scheihing, Proc. SPIE 10177, Infrared Technology and Applications XLIII, 1017712
6. (May 16, 2017); “Buried Extraordinary Optical Transmission”, C. Roberts, R. Liu, X. Zhao, L. Yu, P. Mohseni, X. Liu, D. Wasserman, V.A. Podolskiy, CLEO: Fundamental Science, JTh2A.111 (2016).
7. “Epsilon-Near-Zero Photonic Wires”, R. Liu, C. Roberts, Y. Zhong, V.A. Podolskiy, and D. Wasserman, CLEO: QELS: Fundamental Science, FTh3D.1 (2016).
8. “Diffusion Characterization Using Electron Beam Induced Current and Time-Resolved Photoluminescence of InAs/InAsSb Type-II Superlattices”, D. Zuo, R. Liu, D. Wasserman, J. Mabon, Z. He, S. Liu, Y.-H. Zhang, E. Kadlec, B. Olson, E.A. Shaner, CLEO: Science and Innovations, SM2G.4 (2015)
9. “Localized Surface Phonon Polariton Resonators in GaN”, K. Feng, W. Streyer, S.M. Islam, J. Verma, D. Jena, D. Wasserman, A. Hoffman, QELS Fundamental Science, FTu2E.7, (2015).
10. “Platiinum germanides for long-wavelength infrared plasmonics”, N. Nader, W. Streyer, S. Vangala, D. Wasserman, J.R. Hendrickson, and J.W. Cleary, FiOS, FTu1E5, (2014)
11. “All-Semiconductor Plasmonic Nano-Antennas” S. Law, L. Yu, A. Rosenberg, and D. Wasserman, CLEO: QELS Fundamental Science, FM2K.1 2014
12. “All-Semiconductor Negative Plasmonic Absorbers” C. Roberts, S. Law, T. Kilpatrick, L. Yu, T. Ribaudo, E.A. Shaner, D. Wasserman, and V.A. Podolskiy, CLEO: QELS Fundamental Science, FM1C.3 2014
13. “Controlling Quantum Dot Energies Using Submonolayer Bandstructure Engineering” L. Yu, S. Law, D. Jung, M.L. Lee, and D. Wasserman, CLEO: Science and Innovation, Stu3H.6 2014
14. “Mid-IR Plasmonics with Engineered Semiconductor Metals”, S. Law, C. Roberts, S. Inampudi, A. Rosenberg, V. Podolskiy, and D. Wasserman, Workshop on Optical Materials, OW1D.3 (2014).
15. “All-Semiconductor Plasmonic Perfect Absorber”, S. Law, C. Roberts, T. Kilpatrick, L. Yu, T. Ribaudo, E.A. Shaner, V.A. Podolskiy, and D. Wasserman, CLEO: Science and Innovation, CM2F.6 (2013).
16. “Selective thermal emission from thin-film metasurfaces", W Streyer, S Law, J Mason, DC Adams, T Jacobs, G Rooney, D Wasserman, SPIE NanoScience+ Engineering, Proc. SPIE 8808, p. 88080V-88080V-12, 2013
17. “Making the mid-infrared nano with designer plasmonic materials”, S. Law, J. Felts, C. Roberts, V. Podolskiy, W.P. King, D. Wasserman, Proc. SPIE 8555-1 (2012).
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18. "CO2 sensing with a 2005 nm thulium holmium co-doped fiber laser", R. Zhou, S. McKeown, B. Griffin, B. Amnueypornsakul, H. Huang, S. Eckhoff, D. Wasserman, and L. Goddard, in Optical Sensors, OSA Technical Digest (online) (Optical Society of America, 2012), paper STh2B.4.
19. "Selective Thermal Emission from Patterned Steel Surfaces", J. Mason, D. Adams, S. Smith, Z. Johnson, A. Davis, and D. Wasserman, in CLEO:2011 - Laser Applications to Photonic Applications, OSA Technical Digest (CD) (Optical Society of America, 2011), paper JTuI42.
20. "ENZ-enhanced transmission through subwavelength slits", S. Inampudi, D. Slocum, D. Adams, S. Vangala, W. Goodhue, D. Wasserman, and V. Podolskiy, in CLEO:2011 - Laser Applications to Photonic Applications, OSA Technical Digest (CD) (Optical Society of America, 2011), paper JTuI56.
21. "Toothed Mid-Infrared Metal-Insulator-Metal Waveguides", K. Anglin, D. Adams, T. Ribaudo, and D. Wasserman, in CLEO:2011 - Laser Applications to Photonic Applications, OSA Technical Digest (CD) (Optical Society of America, 2011), paper CTuS4.
22. "Funneling Light Through a Subwavelength Aperture Using Epsilon-Near-Zero Materials", D. Slocum, D. Adams, S. Inampudi, S. Vangala, W. Goodhue, V. Podolskiy, and D. Wasserman, in Quantum Electronics and Laser Science Conference, OSA Technical Digest (CD) (Optical Society of America, 2011), paper QThA3.
23. “Active Mid-Infrared Plasmonic Beam Steering Devices”, D.C. Adams, T. Ribaudo, S. Thongrattanasiri, E.A. Shaner, V. Podolskiy, and D. Wasserman, Proc. SPIE, 7756-41 (2010).
24. "Beam Steering of Mid-Infrared Light with Active Plasmonic Structures", D. Adams, S. Thongrattanasiri, V. Podolskiy, and D. Wasserman, in Conference on Lasers and Electro-Optics, OSA Technical Digest (CD) (Optical Society of America, 2010), paper CFB7.
25. "Evolution of Beaming Pattern in Corrugated Mid-IR Plasmonic Structures", S. Thongrattanasiri, D. Adams, D. Wasserman, and V. Podolskiy, in Quantum Electronics and Laser Science Conference, OSA Technical Digest (CD) (Optical Society of America, 2010), paper QMF5.
26. "Active Control and Spatial Mapping of Mid-Infrared Propagating Surface Plasmons", T. Ribaudo, E. Shaner, S. Howard, C. Gmachl, X. Wang, F. Choa, and D. Wasserman, in Conference on Lasers and Electro Optics/International Quantum Electronics Conference, OSA Technical Digest (CD) (Optical Society of America, 2009), paper IMB1
27. “Mid-Infrared Emitters Utilizing Intersublevel Transitions in Self-Assembled InAs Quantum Dots”, T. Ribaudo, B.S. Passmore, D.C. Adams, X. Qian, S. Vangala, W.D. Goodhue, E.A. Shaner, S.A. Lyon, and D. Wasserman, Proc. SPIE 7616, 7616A1-1, (2010).
28. “Active Mid-Infrared Plasmonic Beam Steering Devices”, D.C. Adams, T. Ribaudo, S. Thongrattanasiri, E.A. Shaner, V. Podolskiy, and D. Wasserman, Proc. SPIE, 7756-41 (2010).
29. “Active Control of Propagating Waves on Plasmonic Surfaces”, T. Ribaudo, E.A. Shaner, S.S. Howard, C. Gmachl, X.J. Wang, F.-S. Choa, and D. Wasserman, Proc. SPIE 7221-24, 2 (2009).
30. “Mid-Infrared Emitters Utilizing Intersublevel Transitions in Self-Assembled InAs Quantum Dots”, T. Ribaudo, B.S. Passmore, D.C. Adams, X. Qian, S. Vangala, W.D. Goodhue, E.A. Shaner, S.A. Lyon, and D. Wasserman, Proc. SPIE 7616, 7616A1-1, (2010).
31. "Laser Action at High k-Space Values in Anti-Correlated Multi-Wavelength Quantum Cascade Lasers", S. Menzel, K. Franz, D. Wasserman, A. Hoffman, J. Cockburn, and C. Gmachl, in Conference on Lasers and Electro-Optics/Quantum Electronics and Laser Science Conference and Photonic Applications Systems Technologies, OSA Technical Digest (CD) (Optical Society of America, 2008), paper CTuP1.
32. "Mid-Infrared Beam Propagation and Modulation in Extraordinary Transmission Gratings", E. Shaner, B. Passmore, A. Grine, and D. Wasserman, in Plasmonics and Metamaterials, OSA Technical Digest (CD)(Optical Society of America, 2008), paper MMD6
33. Loss Mechanisms in Extraordinary Optical Transmission Gratings", T. Ribaudo, K. Freitas, D. Wasserman, E. Shaner, and J. Cederberg, " in Plasmonics and Metamaterials, OSA Technical Digest (CD) (Optical Society of America, 2008), paper MWB2.
34. "Electrically Tunable Mid-Infrared Extraordinary Optical Transmission Gratings", D. Wasserman, E. Shaner, and J. Cederberg, in Conference on Lasers and Electro-Optics/Quantum Electronics and Laser Science Conference and Photonic Applications Systems Technologies, OSA Technical Digest (CD) (Optical Society of America, 2008), paper CThBB3.
35. “Doping Tunable Enhanced Extraordinary Optical Transmission Gratings”, D. Wasserman, J. Cederberg, and E.A. Shaner, Proc. SPIE 6760, 67600A (2007).
36. "Cascaded Emission from a Dual-Wavelength Quantum Cascade Laser", K. Franz, D. Wasserman, A. Hoffman, C. Gmachl, K. Shiu, and S. Forrest, in Conference on Lasers and Electro-Optics/Quantum Electronics and Laser Science Conference and Photonic Applications Systems Technologies, OSA Technical Digest Series (CD) (Optical Society of America, 2007), paper CTuE3.
37. "Narrow STRIPE-Width, Low-Ridge Configuration for High Power Quantum Cascade Lasers", A. Lyakh, P. Zory, D. Wasserman, G. Shu, C. Gmachl, M. D'Souza, D. Botez, and D. Bour, in Conference on Lasers and Electro-Optics/Quantum Electronics and Laser Science Conference and Photonic Applications Systems Technologies, OSA Technical Digest Series (CD) (Optical Society of America, 2007), paper CTuO1.
38. "Nonlinear Quantum Cascade Lasers: Toward Broad Tunability and Short-Wavelength Operation", F. Xie, D. Smith, V. Chaganti, A. Belyanin, D. Wasserman, C. Gmachl, J. Kono, M. Belkin, and F. Capasso, in Conference
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on Lasers and Electro-Optics/Quantum Electronics and Laser Science Conference and Photonic Applications Systems Technologies, OSA Technical Digest Series (CD) (Optical Society of America, 2007), paper CTuO6.
39. "Difference Frequency Generation from Integrated Nonlinearities in Two-Wavelength Quantum Cascade Lasers", D. Wasserman, S. Howard, C. Gmachl, A. Belyanin, and D. Sivco, in Conference on Lasers and Electro Optics/Quantum Electronics and Laser Science Conference and Photonic Applications Systems Technologies, OSA Technical Digest Series (CD) (Optical Society of America, 2007), paper JWA138.
40. “MOCVD growth and regrowth of quantum cascade lasers”, F.-S. Choa, L. Cheng, X. Ji, Z. Liu, D. Wasserman, S.S. Howard, C.F. Gmachl, X. Wang, J. Fan, and J. Khurgin, Proc. SPIE 6485, 64850N (2007).
41. “Mid-infrared electroluminescence from InAs quantum dots”, D. Wasserman, S.A. Lyon, C. Gmachl, J. Cederberg, and E.A. Shaner, Proc. SPIE Vol. Vol.6386, p.63860E (2006).
42. "Approaches to Compact Quantum Cascade Laser Modules with Integrated Coolers", J. Chen, Z. Liu, D. Wasserman, C. Gmachl, D. Sivco, and A. Cho, in Conference on Lasers and Electro-Optics/Quantum Electronics and Laser Science and Photonic Applications Systems Technologies, Technical Digest (CD) (Optical Society of America, 2005), paper JTuC85.
43. “110 InAs Quantum Dots: Growth, Single-Dot Luminescence and Cleaved Edge Alignment”, D. Wasserman, E.A. Shaner, S.A. Lyon, M. Hadjipanayi, A.C. Maciel, and J.F. Ryan, MRS Fall 2004 Meeting Proc. “Progress in Compound Semiconductor Materials IV--Electronic and Optoelectronic Applications”, Vol. 829, (2005).
BOOK CHAPTERS
1. “Electroluminescence from III-V self-assembled quantum dots”, D. Wasserman and S.A. Lyon, Book Chapter for "The Handbook of Electroluminescent Materials", edited by Prof. D.R. Vij, Department of Physics, Kurukshetra University, India, Institute of Physics Publishing, Bristol, U.K (2004).
REVIEWS
1. “Nanosecond modulation of thermal emission“, Daniel Wasserman , Light: Science & Applications, 8, 68 (2019).
3. “Tunable Resonant Devices on Active Substrates”, D. Wasserman, M. Allen, J. Allen, B. Wenner, Patent Pending, Application #: 62/396,580
4. “Optoelectronic device including a buried metal grating for extraordinary optical transmission”, X. Li, D. Wasserman, X. Zhao, Patent Pending, Application #: 62/187,353
5. “Uncooled, high sensitivity spectral selective infrared detector”, S. Gong, D. Wasserman, Patent Granted, Application
#: 62/310,334
6. “Mid-Infrared Detector Using a Heavily doped Backplane to the Detector Structure” Provisional Patent