Daniel Poitras

Rôles et responsabilités

Agent de recherche, centre de recherche en électronique et photonique avancée, équipe de photonique.

Recherche et / ou projets en cours

  • Revêtements optiques pour la telecommunication par satellites (avec l'université McMaster, program HTSN)
  • Revêtements optiques de fibres optiques pour des dispositifs à mémoire quantique (projet interne au CNRC)
  • Design, fabrication et mesures de mirroirs à faibles bruits thermiques pour des applications de détection d'ondes gravitationelles (avec Shincron Co. Japan, CNRS France et MIT USA)
  • Revêtements optiques pour un instrument de mesure d'aérosols, pour des applications en métrologie (projet interne au CNRC)
  • Revêtements optiques de guides optiques dans l'infrarouge pour différentes applications de telecommunication et détection (projets internes au CNRC; projets avec clients).
  • Revêtements optiques pour des applications d'imagerie infrarouge (projets interne au CNRC et avec clients).

Études

Ph.D. Génie physique, École Polytechnique de Montréal, 2000.

Inventions et brevets

  • PCT/CA2009/001764, Grating-based evanescent field molecular sensor using a thin silicon waveguide layer, Grant: US, W, CA
  • US7991023B2 (no PCT), Multi-band multiwavelength quantum dot mode-locked lasers, Grant: US, CA
  • PCT/CA2004/001553, High performance organic light emitting devices, Grant: US, CA, W
  • US7769062B2 (no PCT), Quantum-dot-based semiconductor waveguide devices, Grant: US
  • Form1, divulgation de l’invention: A composition for disinfection and a method of preparing a disinfectant, 2022.
  • Form1, divulgation de l’invention: Semiconductor laser with optimized facet coatings, 2021.
  • Form1, divulgation de l’invention: Dispersion-controlled semiconductor laser cavity based on facet coatings with compensating dispersion, 2013.

Principales publications

  1. Daniel Poitras, Penghui Ma, Michael Jacobson, Catherine Cooksey, Luke Sandilands, Stacey Lee, "2022 Topical Meeting on Optical Interference Coatings: Manufacturing Problem Contest [Invited]," Applied Optics 62 (7) 2023. https://doi.org/10.1364/AO.477250

  2. D Poitras, L Flannigan, CQ Xu, "Optical Coatings for mid-IR DFG-based Next Generation Transceivers for Optical SATCOM," Optical Interference Coatings Conference, WA. 3,2022.

  3. Khan Zeb, Zhenguo Lu, Jiaren Liu, Youxin Mao, Guocheng Liu, Philip J Poole, Mohamed Rahim, Grzegorz Pakulski, Pedro Barrios, Martin Vachon, Daniel Poitras, Weihong Jiang, John Weber, Xiupu Zhang, Jianping Yao, "Photonic Millimeter-Wave-over-Fiber MIMO Wireless System Based on a QDash Laser," 2022 Photonics North (PN), 1-1.

  4. Khan Zeb, Zhenguo Lu, Jiaren Liu, Youxin Mao, Guocheng Liu, Philip J Poole, Mohamed Rahim, Grzegorz Pakulski, Pedro Barrios, Martin Vachon, Daniel Poitras, Weihong Jiang, John Weber, Xiupu Zhang, Jianping Yao, "Broadband Optical Heterodyne Millimeter-Wave-over-Fiber Wireless Links Based on a Quantum Dash Dual-Wavelength DFB Laser," Journal of Lightwave Technology 40 (12), 3698-3708, 2022.

  5. Zhenguo Lu, Jiaren Liu, Youxin Mao, Khan Zeb, Guocheng Liu, Philip J Poole, John Weber, Mohamed Rahim, Grzegorz Pakulski, Chunying Song, Martin Vachon, Pedro Barrios, Daniel Poitras, Shurui Wang, Weihong Jiang, "Quantum dash multi-wavelength lasers for Tbit/s coherent communications and 5G wireless networks,"  Journal of the European Optical Society-Rapid Publications 17 (1), 1-7, 2021.

  6. Khan Zeb, Zhenguo Lu, Jiaren Liu, Youxin Mao, Mohamed Rahim, Philip J Poole, Pedro Barrios, Guocheng Liu, Grzegorz Pakulski, Weihong Jiang, Martin Vachon, Daniel Poitras, Xiupu Zhang, "A quantum-dash dual-wavelength DFB laser for optical millimeter-wave radio-over-fiber systems,"  Optical Fiber Communication Conference, W1J. 5, 2021.

  7. Zhenguo Lu, Jiaren Liu, Youxin Mao, Guocheng Liu, Philip J Poole, Pedro Barrios, Mohamed Rahim, Grzegorz Pakulski, Weihong Jiang, Daniel Poitras, Chunying Song, Martin Vachon, John Weber, Shurui Wang, Ping Zhao, Craig Storey, Khan Zeb, Xiupu Zhang, Jianping Yao, Ke Wu, "Quantum-Dot Multi-Wavelength Lasers for Millimeter Wave Generation and Transmission," Photonics North (PN), 1-1, 2021.

  8. Zhenguo Lu, Khan Zeb, Jiaren Liu, Eric Liu, Linda Mao, Philip J Poole, Mohamed Rahim, Grzegorz Pakulski, Pedro Barrios, Weihong Jiang, Daniel Poitras, "Quantum dot semiconductor lasers for 5G and beyond wireless networks," Smart Photonic and Optoelectronic Integrated Circuits XXIII 11690, 68-75, 2021.

  9. Zhenguo Lu, Jiaren Liu, Linda Mao, Philip J Poole, Eric Liu, John Weber, Chunying Song, Pedro Barrios, Martin Vachon, Shurui Wang, Daniel Poitras, "InAs/InP quantum dot coherent comb lasers and their applications in data centre and coherent communication systems," Novel In-Plane Semiconductor Lasers XX 11705, 1170503, 2021.

  10. K Zeb, ZG Lu, JR Liu, YX Mao, GC Liu, PJ Poole, M Rahim, G Pakulski, P Barrios, WH Jiang, D Poitras, X Zhang, "Ultra-low intensity and phase noise quantum-dash dual-wavelength dfb laser for 5G millimeter-wave signals," Laser Applications Conference, JTu5A. 13, 2021.

  11. Guocheng Liu, Shurui Wang, Zhenguo Lu, Jiaren Liu, Daniel Poitras, Mohamed Rahim, Pedro Barrios, Weihong Jiang, Grzegorz Pakulski, Philip J Poole, "Gain Characteristics of InAs/InP Quantum Dash Semiconductor Optical Amplifiers between S-and C-bands," Integrated Photonics Research, Silicon and Nanophotonics, ITu2A. 4, 2020.

  12. Guocheng Liu, Shurui Wang, Zhenguo Lu, Jiaren Liu, Daniel Poitras, Mohamed Rahim, Pedro Barrios, Weihong Jiang, Grzegorz Pakulski, Philip J Poole, "Temperature-dependent Gain Characteristics of InAs/InP Quantum Dash Semiconductor Optical Amplifiers," Photonics North (PN), 1-1, 2020.

  13. Seyed Ghasem Razavipour, James A Gupta, Graeme Sabiston, Nicaulas Sabourin, Andrew Bezinger, Jean Lapointe, Daniel Poitras, "Pressure-dependent sensitivity of battery based methane detection system using tunable diode laser at 3270 nm," Quantum Sensing and Nano Electronics and Photonics XVII 11288, 283-290, 2020.

  14. D Poitras, L Li, MR Jacobson, CC Cooksey, "2019 Topical Meeting on Optical Interference Coatings: Manufacturing Problem Contest [invited]," Applied Optics 59, A31-A39 (2020).

  15. Boris Lamontagne, Norman R. Fong, In-Hyouk Song, Penghui Ma, Pedro Barrios, and Daniel Poitras, “Review of microshutters for switchable glass,” J. Micro/Nanolith. MEMS MOEMS, vol. 18 (4) 040901 (2019).
  16. Seyed Ghasem Razavipour, James A. Gupta, Graeme Sabiston, Nicaulas Sabourin, Andrew Bezinger, Jean Lapointe, and Daniel Poitras, "Pressure-dependent sensitivity of a single-pass methane detection system using a continuous-wave distributed feedback laser at 3270  nm," Appl. Opt. 58, 6906-6911 (2019)
  17. D. Poitras, "Facet Coating Design Robustness," in Optical Interference Coatings Conference (OIC) 2019, OSA Technical Digest (Optical Society of America, 2019), paper TC.4.
  18. D. Poitras, L. Li, M. Jacobson, and C. Cooksey, "OIC 2019 Manufacturing Problem Contest," in Optical Interference Coatings Conference (OIC) 2019, OSA Technical Digest (Optical Society of America, 2019), paper WC.1.
  19. J. Liu, Z. Lu, P. J. Poole, P. J. Barrios and D. Poitras, "Automatic Cross Carrier-Envelope Phase Locking Within a Dual-Peak Mode-Locked Quantum-Dot Diode Laser," in IEEE Journal of Selected Topics in Quantum Electronics, vol. 25, no. 6, pp. 1-4, Nov.-Dec. 2019.
  20. Zhenguo Lu, Jiaren Liu, Linda Mao, Chun-Ying Song, John Weber, Daniel Poitras, Philip Poole, "2.24 Tbit/s PAM-4 transmission by an InAs/InP quantum dot mode-locked laser," Proc. SPIE 10946, Metro and Data Center Optical Networks and Short-Reach Links II, 109460A (1 February 2019).
  21. Jean-Michel Guay, Jaspreet Walia, Guillaume Côté, Daniel Poitras, Fabio Variola, Pierre Berini, and Arnaud Weck, "Effect of ps-laser repetition rate on colour rendition, nanoparticle morphology and surface chemistry on silver [Invited]," Opt. Mater. Express 9, 457-468 (2019). [Google Scholar: 1 citation]
  22. Jiaren Liu, Zhenguo Lu, Linda Mao, Philip Poole, Chunying Song, John Weber, Pedro Barrios, Daniel Poitras, Siegfried Janz, "InAs/InP Quantum Dot Lasers and Applications," 2018 IEEE International Semiconductor Laser Conference (ISLC), Santa Fe, NM, 2018, pp. 1-3.
  23. Sofiane Haffouz, Katharina D. Zeuner, Dan Dalacu, Philip J. Poole, Jean Lapointe, Daniel Poitras, Khaled Mnaymneh, Xiaohua Wu, Martin Couillard, Marek Korkusinski, Eva Schöll, Klaus D. Jöns, Valery Zwiller, and Robin L. Williams, “Bright Single InAsP Quantum Dots at Telecom Wavelengths in Position-Controlled InP Nanowires: The Role of the Photonic Waveguide,” Nano Letters 18 (5), 3047-3052 (2018). [Google Scholar: 20 citations]
  24. ZG Lu, JR Liu, CY Song, J Weber, Y Mao, SD Chang, HP Ding, PJ Poole, P Barrios, D Poitras, S Janz, M O'Sullivan, “An InAs/InP quantum dot C-band coherent comb laser,” 2018 Optical Fiber Communications Conference and Exposition (OFC), San Diego, CA, 2018, pp. 1-3.
  25. Z.G. Lu, J R. Liu, C.Y. Song, J. Weber, Y. Mao, S.D. Chang, H.P. Ding, P.J. Poole, P.J. Barrios, D. Poitras, S. Janz, and M. O’Sullivan, "High performance InAs/InP quantum dot 34.462-GHz C-band coherent comb laser module," Opt. Express 26, 2160-2167 (2018). [Google Scholar: 12 citations]
  26. Jean-Michel Guay, Antonino Calà Lesina, Guillaume Côté, Martin Charron, Daniel Poitras, Lora Ramunno, Pierre Berini, and Arnaud Weck, “Laser-induced plasmonic colours on metals,” Nature Communications, 8, 16095.1-12 (2017). [Google Scholar: 67 citations]
  27. Daniel Poitras, Li Li, Michael Jacobson, and Catherine Cooksey, "Manufacturing problem contest [invited]," Appl. Opt. 56, C1-C10 (2017). [Google Scholar: 2 citations]
  28. James A. Gupta, Andrew Bezinger, Jean Lapointe, Daniel Poitras, Geof C. Aers, "GaSb-based single-mode distributed feedback lasers for sensing (Conference Presentation)," Proc. SPIE 10107, Smart Photonic and Optoelectronic Integrated Circuits XIX, 101070M (28 April 2017)
  29. Liu, J. R., Z. G. Lu, P. J. Poole, C. Y. Song, J. Weber, L. Mao, P. J. Barrios, D. Poitras, and S. Janz. "Phase noise analysis of InAs/InP quantum-dot mode-locked semiconductor lasers." In Proceedings of the 8th International Conference and Exhibition on Lasers, Optics & Photonics. 2017. [Google Scholar: 3 citations]
  30. Lu, Z. G., J. R. Liu, P. J. Poole, P. J. Barrios, D. Poitras, C. Y. Song, S. D. Chang et al. "Coherence comb laser sources: quantum dots, packaging and active control." In Invited paper), The 18th European Conference on Integrated Optics. 2016. [Google Scholar: 7 citations]
  31. Zhenguo Lu, Jiaren Liu, Philip J. Poole, Chun-Ying Song, John Webber, Linda Mao, Shoude Chang, Heping Ding, Pedro J. Barrios, Daniel Poitras, Siegfried Janz, "Integrated InAs/InP quantum-dot coherence comb lasers (Conference Presentation)," Proc. SPIE 10107, Smart Photonic and Optoelectronic Integrated Circuits XIX, 101070I (28 April 2017) [Google Scholar: 9 citations]
  32. D. Poitras and P. G. Verly, "Asymmetry in Waveguide Facet Coating," in Optical Interference Coatings 2016, OSA Technical Digest (online) (Optical Society of America, 2016), paper TC.6.
  33. D. Poitras, P. Ma, P. G. Verly, Z. Lu, J. Liu, P. Barrios, J. Caballero, and P. J. Poole, "Metal-Dielectric Waveguide Facet Coatings," in Optical Interference Coatings 2016, OSA Technical Digest (online) (Optical Society of America, 2016), paper TC.5.
  34. ZG Lu, JR Liu, D Poitras, P Poole, P Barrios, CY Song, SD Chang, C Flueraru, HP Ding and S Janz. “High Performance InAs/InP C-Band Quantum Dot Coherence Frequency Comb Lasers,” Conference on Lasers and Electro-Optics (CLEO) 2013, OSA Technical Digest, paper CTh4G2, Optical Society of America, 2013. [1 citation]
  35. A. Gamouras, M. Britton, M.M. Khairy, R. Mathew, D. Dalacu, P. Poole, D. Poitras, R.L. Williams and K.C. Hall. “Energy-selective optical excitation and detection in InAs/InP quantum dot ensembles using a one-dimensional optical microcavity,” Applied Physics Letters 103(25), 253109-1—253109-4 (2013). [Google Scholar: 5 citations]
  36. S. Fairchild, M. Cahay, P.T. Murray, L. Grazulis, X. Wu, D. Poitras and D.J. Lockwood. “Grain size, texture and crystallinity in lanthanum monosulfide thin films grown by pulsed laser deposition,” Thin Solid Films 524, 166-172 (2012). [citation]
  37. Z.J. Jiao, Z.G. Lu, J.R. Liu, P.J. Poole, P.J. Barrios, D. Poitras, G. Pakulsi, J. Caballero and X.P. Zhang. “Linewidth enhancement factor in InAs/InP quantum dot lasers around 1.5 um,” Optics Communication 285(21), 4372-4375 (2012). [11 citations]
  38. S. Haffouz, P.J. Barrios, D. Poitras, and R. Normandin. “Near-Infrared ultrawide bandwith LEDs using InAs quantom dots of equally tuned heights,” IEEE Photonics Technology Letters 24(19), 1677-1679 (2012). [1 citation]
  39. J. Liu, Z.G. Lu, P.J. Poole, P.J. Barrios, D. Poitras, Z. Jiao and X.P. Zhang. “THz optical pulses from a coupled-cavity quantum-dot laser, “ Optics Communication 285(6), 1323-1325 (2012). [2 citations]
  40. Z. Jiao, J. Liu, Z. Lu, X. Zhang, P.J. Poole, P.J. Barrios, D. Poitras and J. Caballero. “Tunable terahertz beat signal generation from an InAs/InP quantum-dot mode-locked laser combined with external-cavity,” IEEE Photonics Technology Letters 24(6), 518-520 (2012). [6 citations]
  41. S. Haffouz, P.J. Barrios, R. Normandin, D. Poitras and Z. Lu. “Ultrawide-bandwidth, superluminescent light-emitting diodes using InAs quantum dots of tuned height,” Optics Letters 37(6), 1103-1105 (2012). [31 citations]
  42. J.A. Gupta, A. Bezinger, P.J. Barrios, J. Lapointe, D. Poitras and P. Waldron. “High-resolution methane spectroscopy using InGaAsSb/AlInGaAsSb laterally-coupled index-grating distributed feedback laser diode at 3.23um,” Electronics Letters 48(7), 396-397 (2012). [10 citations]
  43. Z. Jiao, J. Liu, Z. Lu, X. Zhang, P.J. Poole, P.J. Barrios, D. Poitras and J. Caballero. “Semiconductor and organic lasers and amplifiers-tunable terahertz beat signal generation from an InAs/InP quantum-dot mode-locked laser combined with external-cavity,” IEEE Photonics Technology Letters 24(5), 518 (2012).
  44. M. Cahay, P. Boolchand, S.B. Fairchild, L. Grazulis, P.T. Murray, T.C. Back, V. Semet, V.T. Binh, X. Wu, D. Poitras, D.J. Lockwood, F. Yu and V. Kuppa, “Review article: Rare-earth monosulfides as durable and efficient cold cathodes,” Journal of Vacuum Science and Technology B 29(6),  06F602 (2011). [5 citations]
  45. PJ Poole, ZG Lu, JR Liu, P Barrios, ZJ Jiao, D Poitras, AJ SpringThorpe, G Pakulski, D Goodchild, B Rioux. “Narrow linewidth 1.52 µm InAs/InP quantum dot DFB lasers,” Compound Semiconductor Week (CSW/IPRM) and International conference on Indium Phosphide and related materials (IPRM), Berlin, May 2011. [1 citation]
  46. ZG Lu, PJ Poole, JR Liu, PJ Barrios, D Poitras, ZJ Jiao, G Pakulski, JA Caballero, D Goodchild, B Rioux, AJ SpringThorpe. “InAs/InP quantum dot laser devices around 1550 nm for fiber communications,” ICO International Conference on Information Photonics (IP), IEEE, Ottawa, May 2011.
  47. JA Gupta, PJ Barrios, A Bezinger, P Waldron, BF Ventrudo, J Lapointe, D Poitras, C Storey. “Single-mode mid-infrared lasers for gas sensing in the 2–4um range,” ICO International Conference on Information Photonics (IP), IEEE, Ottawa, May 2011. [2 citations]
  48. ZG Lu, P Poole, P Barrios, ZJ Jiao, JR Liu, G Pakulski, D Goodchild, B Rioux, AJ SpringThorpe, D Poitras. “Single-mode 1.52 µm InAs/InP quantum dot DFB lasers,” Optical Fiber Communication Conference and Exposition (OFC/NFOEC), 2011 and the National Fiber Optic Engineers Conference, IEEE, Los Angeles, March 2011. [1 citation]
  49. Zhejing Jiao, Jiaren Liu, Zhenguo Lu, Philip Poole, Pedro Barrios, Daniel Poitras, and X.P. Zhang.  “437 GHz optical pulse train generation from a C-Band InAs/InP quantum dot laser,” in Optical Fiber Communication Conference/National Fiber Optic Engineers Conference 2011, OSA Technical Digest (CD) (Optical Society of America, 2011), paper OThY7. [3 citations]
  50. Z.G. Lu, P.J. Poole, J.R. Liu, P.J. Barrios, Z.J. Jiao, G. Pakulski, D. Poitras, D. Goodchild, B. Rioux and A.J. SpringThorpe. “High-performance 1.52um InAs/InP quantum dot distributed feedback laser,” Electronics Letters 47(14), 818-819 (2011). [10 citations]
  51. Z.J. Jiao, J.R. Liu, Z.G. Lu, X.P. Zhang, P.J. Poole, P.J. Barrios and D. Poitras. ”A C-band InAs/InP quantum dot semiconductor mode-locking laser emitting 403-GHz repetition rate pulses,” IEEE Photonics Technology Letters 23(9), 543-545 (2011). [24 citations]
  52. Z.G. Lu, J.R. Liu, P.J. Poole, Z.J. Jiao, P.J. Barrios, D. Poitras, J. Caballero and X.P. Zhang. “Ultra-high repetition rate InAs/InP quantum dot mode-locked lasers,” Optics Communication 284(9), 2323-2326 (2011). [22 citations]
  53. Y. Guo, J.A. Dobrowolski, L. Li, D. Poitras and T. Tiwald. “Implementation of long-wavelength cut-off filters based on critical angle,” Applied Optics 50(9), C396-C402 (2011). [2 citations]
  54. WY Li, ZG Lu, DX Xu, JR Liu, P Poole, P Barrios, D Poitras, R Ma, J Lapointe, M Vachon, S Janz. « Quantum dot multiwavelength comb lasers with Si ring resonator, » Photonics North 2010, Proc. SPIE 7750, paper 77501U, Niagara Falls, June 2010.
  55. Z. Haffouz, M. Rodermans, P.J. Barrios, J. Lapointe, S. Raymond, Z. Lu and D. Poitras. “Broadband superluminescent diodes with height-engineering InAs-GaAs quantum dots,” Electronics Letters 46(16), 1144-1146 (2010). [16 citations]
  56. Jens H Schmid, Przemek J Bock, Pavel Cheben, William Sinclair, Jaime García, Siegfried Janz, Jean Lapointe, Geoffrey C Aers, Daniel Poitras, Yunhui Li, Gregory Lopinski, André Delâge, Adam Densmore, Boris Lamontagne, Rubin Ma, Dan-Xia Xu. “Applications of subwavelength grating structures in silicon-on-insulator waveguides,” OPTO and Silicon Photonics V, Proc. SPIE 7606, paper 76060F, San Francisco, February 2010. [5 citations]
  57. Yanen Guo, JA Dobrowolski, Li Li, Daniel Poitras, Tom Tiwald. « Measured Properties of Long-Wavelength Cut-Off Filters Based on Critical Angle, “ Optical Interference Coatings (OIC), OSA Technical Digest, paper TuB5, 2010.
  58. J. H. Schmid, W. Sinclair, J. Garci­a, S. Janz, J. Lapointe, D. Poitras, Y. Li, T. Mischki, G. Lopinski, P. Cheben, A. Delage, A. Densmore, P. Waldron, and D.-X. Xu,"Silicon-on-insulator guided mode resonant grating for evanescent field molecular sensing", Optics Express 17, 18371-18380, 2009. [54 citations]
  59. Z.G. Lu, J.R. Liu, P.J. Poole, S. Raymond, P.J. Barrios, D. Poitras, G. Pakulski, P. Grant, and D. Roy-Guay, "An L-band monolithic InAs/InP quantum dot mode-locked laser with femtosecond pulses", Optics Express, Vol. 17, No. 16, pp.13609-13614 (August, 2009). [36 citations]
  60. S. Haffouz, S. Raymond, Z.G. Lu, P.J. Barrios, D. Roy-Guay, X. Wu, J.R. Liu, D. Poitras and Z. Wasilewski "Growth and fabrication of quantum dots superluminescent diodes using indium flush technique: a new approach in controlling the bandwidth", Journal of Crystal Growth, V.311, p.1803-1806 (2009). [14 citations]
  61. Jiaren Liu, Zhenguo Lu, S Raymond, PJ Poole, PJ Barrios, D Poitras, P Grant. “Passively mode-locked quantum dot diode lasers,” Conference on Lasers and Electro-Optics/Pacific Rim, OSA Technical Digest, paper WG4_3, 2009.
  62. J.H. Schmid, W. Sinclair, S. Janz, J. Lapointe, D. Poitras, T. Mischki, G. Lopinski, P. Waldron, P. Cheben, A. Delage, A. Densmore, D. Xu, "Silicon photonic guided mode resonance filter for evanescent field molecular sensing," Integrated Photonics and Nanophotonics Research and Applications, OSA Technical Digest (CD) paper IWB3, Optical Society of America , 2009.  [3 citations]
  63. Z.G. Lu, J.R. Liu, P.J. Poole, S. Raymond, P.J. Barrios, D. Poitras, G. Pakulski, X.P. Zhang, K. Hinzer, and T.J. Hall,"Low noise InAs/InP quantum dot C-band monolithic multiwavelength lasers for WDM-PONs", The 2009 Optical Fiber Communication Conference / The National Fiber Optic Engineers Conference (OFC/ NFOEC 2009), San Diego, California, USA, JWA27, (22-26 March 2009). [14 citations]
  64. Z.G. Lu, J.R. Liu, P.J. Poole, P.J. Barrios, D. Poitras, S. Raymond, and G. Pakulski, "A passive mode-locked InAs/InP quantum dot laser with pulse duration of less than 300 fs", SPIE Photonics West 2009, San Jose, CA, USA, paper 722413, (27-29 January 2009). [1 citation]
  65. J.A. Gupta, P.J. Barrios, J. Lapointe, G.C. Aers, D. Poitras, C. Storey and P. Waldron, "Single-Mode 2.4um InGaAsSb/AlGaAsSb Distributed Feedback Lasers for Gas Sensing", Proc. SPIE Vol. 7222, 7222-59 (2009).
  66. S Haffouz, S Raymond, ZG Lu, PJ Barrios, JR Liu, D Poitras. “Emission energy tuning of InAs-quantum dots for fabrication of broadband superluminescent diodes,” 9th IEEE-NANO Conference on Nanotechnology, pp. 246-247, 2009.
  67. W Sinclair, Jens H Schmid, Philip Waldron, Daniel Poitras, Siegfried Janz, Trevor Mischki, Gregory Lopinski, Adam Densmore, Dan-Xia Xu, Jean Lapointe, Andre Delâge. “Silicon photonic evanescent field molecular sensor using resonant grating interrogation,” CLEO/QELS, IEEE, paper JTuD89, 2009.
  68. J.R. Liu, Z.G. Lu, S. Raymond, P.J. Poole, P.J. Barrios and D. Poitras. “Dual-wavelength 92.5GHz self-mode-locked InP-based quantum dot laser,” Optics Letters 33(15), 1702-1704 (2008). [60 citations]
  69. Z.G. Lu, J.R. Liu, S. Raymond, P.J. Poole, P.J. Barrios and D. Poitras. “312-fs pulse generation from a passive C-band InAs/InP quantum dot mode-locked laser,” Optics Express 16(14), 10835-10840 (2008). [77 citations]
  70. A.J. Zilkie, J. Meier, M. Mojahedi, A.S. Helmy, P.J. Poole, P. Barrios, D. Poitras, T.J. Rotter, C. Yang, A. Stintz, K.J. Malloy, P.W.E. Smith, J.S. Aitchison, "Time-Resolved Linewidth Enhancement Factors in Quantum Dot and Higher-Dimensional Semiconductor Amplifiers Operating at 1.55 um", Journal of Lightwave Technology, 2008. 26(11): p. 1498-1509. [50 citations]
  71. C. Py, D. Poitras, C-C Kuo and H. Fukutani, “High-contrast Organic Light Emitting Diodes with a partially absorbing anode", Optics Letters 33(10), p1126-8, May 2008. [8 citations]
  72. D. Poitras, C.-C. Kuo, C. Py, "Design of high-contrast OLEDs with microcavity effect", Opt. Express 16(11), 8003-8015 (2008). [36 citations]
  73. J. Liu, Z. Lu, S. Raymond, P.J. Poole, P.J. Barrios, and D. Poitras, "1.6-µm multiwavelength emission of an InAs/InGaAsP quantum dot laser", IEEE Photonics Technology Letters 20(2), 81-83, (2008) [33 citations]
  74. S. Calvez, N. Laurand, H.D. Sun, J. Weda, D. Burns, M.D. Dawson, A. Harkonen, T. Jouhti, M. Pessa, M. Hopkinson, D. Poitras, J.A. Gupta, C.G. Leburn, C.T.A. Brown and W. Sibbett. “GaInNAs(Sb) surface normal devices,” Physica Status Solidi A 205(1). 85-92 (2008). [15 citations]
  75. Z.G. Lu, J.R. Liu, X.P. Zhang, S. Raymond, P.J. Poole, P.J. Barrios, D. Poitras, S. Haffouz, Z. Wasilewski and G. Pakulski, "Multiwavelength quantum-dot semiconductor fiber ring laser", SPIE Proceedings of Asia-Pacific Optical Communications (APOC 2008), Hangzhou, P.R. China, Proc. SPIE 7135, paper 713521 (26-30 October 2008).
  76. Z.G. Lu, J.R. Liu, S. Raymond, P.J. Poole, P.J. Barrios, and D. Poitras, "Femtosecond pulse generation in a C-band quantum dot laser", SPIE Proceedings of Asia-Pacific Optical Communications (APOC 2008), Hangzhou, P.R. China, SPIE7135, paper 71352L (26-30 October 2008). [2 citations]
  77. Z.G. Lu, J.R. Liu, S. Raymond, P.J. Poole, P.J. Barrios, and D. Poitras, "A quantum-dot-based wavelength multicasting system", SPIE Photonics North 2008, Montreal, QC, Canada, 41-HWHX-112 (1-4 June, 2008).
  78. Z.G. Lu, S. Haffouz, S. Raymond, J.R. Liu, P.J. Barrios, D. Poitras, Z. Wasilewski, and P.J. Poole, "Broadband quantum-dot superluminescent diodes at 1000 nm", SPIE Photonics North 2008, Montreal, QC, Canada, 41-WHMA-222 (1-4 June 2008).
  79. J.A. Gupta, S. Calvez, N. Laurand, J. Weda, D. Burns, D. Poitras, G.C. Aers and M.D. Dawson,"Characteristics of GaInNAsSb/GaAs VCSELs Operating Near 1.55um", Integrated Optoelectronic Devices, Proc. SPIE Vol. 6908, paper 69080E (2008).
  80. A.J. Zilkie, J. Meier, M. Mojahedi, P.J. Poole, P. Barrios, D. Poitras, T.J. Rotter, C. Yang, A. Stintz, K.J. Malloy, P.W.E. Smith, J.S. Aitchison, "Carrier Dynamics of Quantum-Dot, Quantum-Dash, and Quantum-Well Semiconductor Optical Amplifiers Operating at 1.55 um", IEEE Journal of Quantum Electronics, 43 (11), 982-991 (2007). [81 citations]
  81. J. Liu, Z. Lu, S. Raymond, P.J. Poole, P.J. Barrios, G. Pakulski, D. Poitras, G. Xiao, Z. Zhang, “Uniform 90-channel multiwavelength InAs/InGaAsP quantum dot laser”, IEE Electronics Letters, Vol. 43, No. 8, 458-460 (2007). [18 citations]
  82. S. Owega, D. Poitras, "Local similarity matching algorithm for determining SPR angle in surface plasmon resonance sensors", Sens. Actuators B 123, 35-41 (2007). [13 citations]
  83. D. Poitras, C.C. Kuo, C. Py, L. Li, "High-Contrast OLED with Microcavity Effect," in Optical Interference Coatings on CD-ROM (The Optical Society of America, Washington, DC), ThC3, 2007.
  84. Z.G. Lu, J.R. Liu, S. Raymond, P.J. Poole, P.J. Barrios, S. Haffouz, G. Pakulski, D. Poitras, G.Z. Xiao, Z.Y. Zhang, S. Taebi, Y. Song, X.P. Zhang, and T. Hall, "Self-assembled quantum-dot semiconductor optical devices", The Photonics North 2007, Ottawa, ON, Canada, 95-m12Q-151 (4-7 June 2007).
  85. Z.G. Lu, J.R. Liu, S. Raymond, P.J. Poole, P.J. Barrios, S. Haffouz, D. Poitras, G. Pakulski, S. Taebi, Y. Song, X.P. Zhang, and T. Hall, "Quantum-dot semiconductor waveguide devices," Asia-Pacific Optical Communications, Wuhan, P.R. China, Proc. SPIE 6782, paper 67821Y, 2007. [2 citations]
  86. J.A. Gupta, P.J. Barrios, G. Pakulski, G.C. Aers, J.A. Caballero, D. Poitras and X. Wu, “Properties of GaInNAsSb narrow ridge waveguide laser diodes in continuous-wave operation at 1.55um”, Proc. Of SPIE Vol. 6485, 64850S-1 (2007). [7 citations]
  87. S. Fairchild, L. Grazulis, M. Cahay, K. Garre, D. Poitras, X. Wu, D.J. Lockwood, V. Semet and Vu Thien Binh, “Lanthanum Monosulfide Thin Films Grown on MgO Substrates for Field Emission”, Technical Digest of the 20th International Vacuum Nanoelectronics Conference (H. Busta, Ed.), IEEE Cat. No. 07TH8951, 253 (2007).
  88. D. Poitras, C.C. Kuo, C. Py, L. Li,"High-Contrast OLED with Microcavity Effect", in Optical Interference Coatings on CD-ROM (The Optical Society of America, Washington, DC, 2007), presentation ThC3.
  89. Z. G. Lu, J. R. Liu, S. Raymond, P. J. Poole, P. J. Barrios, G. Pakulski, D. Poitras, F. G. Sun, S. Taebi, and T. Hall, " Ultra-Broadband Quantum-Dot Semiconductor Optical Amplifier and Its Applications," in Optical Fiber Communication Conference and Exposition and The National Fiber Optic Engineers Conference, OSA Technical Digest Series (CD), paper JThA33, 2007. [10 citations]
  90. A. J. Zilkie, J. Meier, P. W. E. Smith, M. Mojahedi, J. S. Aitchison, P. J. Poole, P. Barrios, D. Poitras, R. H. Wang, T. J. Rotter, C. Yang, A. Stintz, and K. J. Malloy, " Linewidth Enhancement Factors in 1.55 μm Quantum Dot, Quantum Dash, and Quantum Well Amplifiers," 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 CThK2. [1 citation]
  91. Sandy Owega, Daniel Poitras, and Karim Faid, “Solid-state optical coupling for surface plasmon resonance sensors,” Sensors and Actuators B, 114(1) 212-217 (2006). [8 citations]
  92. A.J. Zilkie, J. Meier, P.W.E. Smith, M. Mojahedi, J.. Aitchison, P.J. Poole, C. Nì. Allen, P. Barrios, D. Poitras, "Femtosecond gain and index dynamics in an InAs/InGaAsP quantum dot amplifier operating at 1.55 ìm", Optics Express 14(23), 11453-11459 (2006).  [44 citations]
  93. G. Ortner, C. Ni. Allen, C. Dion, P. Barrios, D. Poitras, D. Dalacu, G. Pakulski, J. Lapointe, P.J. Poole, W. Render, S. Raymond, “External cavity InAs/InP quantum dot laser with a tuning range of 166nm”, Appl Phys Lett, 88(12) 121119 (2006). [49 citations]
  94. J.A. Dobrowolski, Yanen Guo, Tom Tiwald, Penghui Ma and Daniel Poitras, “Toward perfect antireflection coatings. 3. Experimental results obtained with the use of Reststrahlen materials,” Appl. Opt. 45(7), 1555-1562 (2006). [43 citations]
  95. M. Cahay, K. Garre, X. Wu, D. Poitras, D.J. Lockwood, S. Fairchild, “Physical properties of lanthanum monosulfide thin films grown on (100) silicon substrates”, J. Appl. Phys. 99, 123502 (2006). [17 citations]
  96. J. A. Gupta, P. J. Barrios, J. A. Caballero, D. Poitras, G. C. Aers, G. Pakulski, and X. Wu, “Gain and lifetime of GaInNAsSb narrow ridge waveguide laser diodes in continuous-wave operation at 1.56  µm,” Appl. Phys. Lett. 89, 151119 (2006). [20 citations]
  97. Z.G. Lu, J.R. Liu, S. Raymond, P.J. Poole, P.J. Barrios, D. Poitras, F.G. Sun, G. Pakulski, P.J. Bock, and T. Hall, “Highly efficient non-degenerate four-wave mixing process in InAs/InGaAsP quantum dots,” Electron. Lett. 42, 1112 (2006). [31 citations]
  98. A. J. Zilkie, J. Meier, P. W. Smith, M. Mojahedi, J. S. Aitchison, P. J. Poole, C. N. Allen, P. Barrios, and D. Poitras, "Ultrafast Gain and Index Dynamics in an InAs/InGaAsP Quantum Dot Amplifier Operating at 1.55 µm," in Conference on Lasers and Electro-Optics/Quantum Electronics and Laser Science Conference and Photonic Applications Systems Technologies, Technical Digest (CD), paper CMJJ5, 2006. [1 citation]
  99. AJ Zilkie, J Meier, PWE Smith, M Mojahedi, JS Aitchison, PJ Poole, C Ni Allen, P Barrios, D Poitras, RH Wang, TJ Rotter, C Yang, A Stintz, KJ Malloy. “Comparison of the gain recovery times in low dimensional semiconductor amplifiers at 1.55 μm,” Conference on Lasers and Electro-Optics(LEOS), IEEE Technical Digest, paper TuN3, 2006.
  100. J.A. Gupta, P.J. Barrios, X. Zhang, J. Lapointe, D. Poitras, G. Pakulski, X. Wu, A. Delage, “Room-temperature continuous-wave operation of GaInNAsSb laser diodes at 1.55um”, Electron. Lett. 41, 1060-1062 (2005). [32 citations]
  101. S. Frederick, D. Dalacu, D. Poitras, G.C. Aers, P.J. Poole, J. Lefebvre, D. Chithrani, R.L. Williams, “Near-infrared single photon sourceds employing site-selected InAs/InP quantum dot microcavities,” Microelectronics J. 36, 197-9 (2005). [5 citations]
  102. I. Golub, D. Poitras, A. Delage, E. Simova, P. Barrios, “Brewster angle based ARROW polarizer using high refractive index contrast materials,” in Integrated Photonics Research and Applications/Nanophotonics for Information System Topical Meetings on CD-ROM (The optical society of america, Washington DC, 2005), Paper IWG4.
  103. D. Poitras, “Dealing with Sensitivity Variations During the Manufacture of Optical Coatings,” Proc. 48th Annual Tech. Conf. Proc. Society of Vacuum Coaters, p. 20-24 (2005). [1 citation]
  104. Aaron J. Zilkie, Joachim Meier, Peter W. E. Smith, Mohammad Mojahedi, J. Stewart Aitchison, Philip J. Poole, Claudine Ni. Allen, Pedro Barrios, Daniel Poitras, "Characterization of the ultrafast carrier dynamics of an InAs/InGaAsP quantum dot semiconductor optical amplifier operating at 1.55 μm," Proc. SPIE 5971, Photonic Applications in Nonlinear Optics, Nanophotonics, and Microwave Photonics, 59710G (1 October 2005); [7 citations]
  105. L. Tay, N.L. Rowell, D. Poitras, D.J. Lockwood, and R. Boukherroub, "Bovine serum albumin adsorption on passivated porous silicon layers," Can. J. Chem., 82, 1545–1553 (2004). [23 citations]
  106. X. Liu, D. Poitras, Y. Tao, C. Py, and A. John, "Optically pumped lasing from organic microcavity" Can. J. Phys. 82, 481–487 (2004). [6 citations]
  107. X. Liu, D. Poitras, Y. Tao and C. Py, "Microcavity organic light emitting diodes with double sided light emission of different colors," J. Vac. Sci. Technol. A, 22(3), 764–767 (2004). [31 citations]
  108. D. Dalacu, D. Poitras, J. Lefebvre, P. J. Poole, G. C. Aers, and R. L. Williams, "InAs/InP quantum dot pillar microcavities using SiO2/Ta2O5 Bragg reflectors with emission around 1.5 micrometer," Appl Phys Lett , 84(17), 3235–3237 (2004). [24 citations]
  109. D. Dalacu, R. L. Williams, D. Poitras, J. Lefbevre, P. J. Poole, and G. C. Aers, "InAs/InP quantum dot microcavities employing dielectric Bragg mirrors," Physica E  21, 840–845 (2004). [1 citation]
  110. D. Poitras and J.A. Dobrowolski, "Towards perfect antireflection coatings:  2. Theory," Appl. Opt., 43(6), 1286–1295 (2004). [188 citations]
  111. M. Cahay, K. Garre, P. Dravian, P. Boolchand, S. Fairchild, J. Jones, X. Wu, D. Poitras, D.J. Lockwood, V. Semet, Vu-Thien-Binh, “Pulsed laser deposition of lanthanum sulfide thin films on silicon and indium phosphide substrates: growth, characterization, and field emission properties,” IEEE Technical Digest of the 17th International Vacuum Nanoelectronics Conference, vol. 266- 267, 2004.
  112. G. Pakulski, J.A. Gupta, P.J. Barrios, A. Delage, D. Poitras, X. Wu, E. Post, Z.R. Wasilewski, “Transparency current density of GaInNAs lasers,” SPIE Photonics North, Proc. SPIE, vols. 5577-5579, p. 82-87 (2004).  [2 citations]
  113. L. Li, D. Poitras, and X. Tong, "Broadband tunable Fabry-Perot filters," in Optical Interference Coatings, OSA Technical Digest (Optical Society of America, Washington DC, 2004), pp. ThB3-1–3. [1 citation]
  114. J.A. Dobrowolski, Y. Guo, D. Poitras, P. Ma, and T. Tiwald, “Wide-angle antireflection coatings based on the use of Reststrahlen materials,” in Optical Interference Coatings, OSA Technical Digest (Optical Society of America, Washington DC, 2004), pp. FB2-1–2.
  115. J. A. Dobrowolski, Y. Guo, T. Tiwald, D. Poitras, and P. Ma, " Some reflections on the history of optical thin films," in Optical Interference Coatings, OSA Technical Digest Series (Optical Society of America, 2004), paper MA2.
  116. D. Poitras, "Asymmetrical Dual-Cavity filters: Theory and application," Optics Express, 11(25) 3393–3403 (2003). [5 citations]
  117. Daniel Poitras, J. A. Dobrowolski, Tom Cassidy, and Simona Moisa, "Ion-beam etching for the precise manufacture of optical coatings: erratum," Appl. Opt. 42, 5749-5749 (2003)   [5 citations]
  118. D. Poitras, J.A. Dobrowolski, T. Cassidy, and S. Moisa, "Ion beam etching for the precise manufacture of optical coatings," Appl. Opt., 42(19), 4037–4044 (2003). [20 citations]
  119. D. Dalacu, D. Poitras, J. Lefebvre, P. J. Poole, G. C. Aers, J.-F. Girard and R. Williams, " InAs/InP quantum dots in SiO2/Ta2O5-based microcavities," Appl. Phys. Lett., 82(26), 4803–4805 (2003)  [7 citations]
  120. J.-Y. Duboz, N. Brière de l'Isle, L. Dua, P. Legagueux, M. Mosca, J.-L. Reverchon, N. Grandjean, F. Semond, J. Massies, R. Dudeck, D. Poitras, and T. Cassidy, "Microcavity light emitting diodes based on GaN membranes grown by molecular beam epitaxy on silicon," Jap. J. Appl. Phys., 42, 118–121 (2003).  [3 citations]
  121. P. Barrios, S. Janz, I. Golub, P. Poole, P. Chow-Chong, D. Poitras, I. Sproule, M. Malloy, A. Delage, R. McKinnon, B. Syrett, S. El-Mougy and S. Abdalla, "O+-Ion implantation for practical InP-based digital optical switches," International Electronic Packaging Technical Conference and Exhibition (IPACK03), Hawaii, June 2003. [1 citation]
  122. D. Poitras, D. Dalacu, X. Liu, J. Lefebvre, P.J. Poole, and R.L. Williams, “Luminescent devices with symmetrical and asymmetrical microcavity structures,” in Proceedings of the Forty-Sixth Annual Technical Conference of the Society of Vacuum Coaters (Society of Vacuum Coaters, Albuquerque, NM, 2003), pp.317--322. [3 citations]
  123. D. Poitras, "Progress in the fabrication of complex optical coatings," in Dielectrics in Emerging Technologies,  Electrochemical Society Proc. 2003-01D, p. 172,  Misra, K. Worhoff and P. Mascher, Eds. (Electrochemical Society, Pennington NJ, 2003).
  124. D. Poitras, S. Larouche, and L. Martinu, "Design and plasma-deposition of dispersion-corrected multiband rugate filters," Appl. Opt., 41, 5249–5255 (2002). [63 citations]
  125. D. Poitras, "Admittance diagrams of accidental and premeditated optical inhomogeneities in coatings," Appl. Opt., 41, 4671–4679 (2002). [5 citations]
  126. J.A. Dobrowolski, D. Poitras, P. Ma, H. Vakil and M. Acree, "Towards perfect antireflection coatings: Numerical investigation," Appl. Opt., 41, 3075–3083 (2002). [236 citations]
  127. D. Poitras, J.A. Dobrowolski, T. Cassidy, C. Midwinter, and C. Thomas McEroy, "Black layer coatings for the photolithographic manufacture of diffraction gratings," Appl. Opt., 41, 3306–3311 (2002).
  128. D. Dalacu, D. Poitras, J. Lefebvre, P. J. Poole, G. C. Aers, J.-F. Girard and R. L. Williams, "Optical properties of InAs/InP planar quantum dot microcavities," MRS Symp. Proc. 737, p. 53-58, 2002.
  129. P. Ma, J.A. Dobrowolski, D. Poitras, T. Cassidy, and F. Lin. "Toward the manufacture of ‘perfect’ antireflection coatings,” Proceedings of the 45th Annual Technical Conference of the Society of Vacuum Coaters (Society of Vacuum Coaters, Albuquerque, NM, 2002), pp. 216-219. [6 citations]
  130. D. Poitras, T. Cassidy, S. Moisa, and J.A. Dobrowolski. "The use of etching during the precise manufacture of optical multilayer coatings," Proceedings of the 45th Annual Technical Conference of the Society of Vacuum Coaters (Society of Vacuum Coaters, Albuquerque, NM, 2002), pp. 262-265. [1 citation]
  131. J.A. Dobrowolski, D. Poitras, T. Cassidy, P. Ma, H. Vakil, and M. Acree, “ Towards perfect antireflection coatings, ”, in Optical Interference Coatings, OSA Technical Digest (Optical Society of America, Washington DC, 2001), pp. MD3-1–3. [1 citation]
  132. D. Poitras, J.A. Dobrowolski, T. Cassidy, C. Midwinter, and C.T. McElroy, “ Black layer coatings for the photolithographic manufacture of diffraction gratings, in Optical Interference Coatings, OSA Technical Digest (Optical Society of America, Washington DC, 2001), pp. ThC2-1–3. [1 citation]
  133. D. Poitras and L. Martinu, “Admittance diagrams of accidental and premeditated inhomogeneities in coatings, ”, in Optical Interference Coatings, OSA Technical Digest (Optical Society of America, Washington DC, 2001), pp. TuA3-1–3 (2001). [1 citation]
  134. D. Poitras, S. Larouche, and L. Martinu, “ Design and plasma-deposition of dispersion-corrected multiband rugate filters, ”, in Optical Interference Coatings, OSA Technical Digest (Optical Society of America, Washington DC, 2001), pp. MB7-1–3.
  135. D. Poitras, T. Cassidy and S. Guétré, “Asymmetrical dual-cavity filters: Theory and application”, in Optical Interference Coatings, OSA Technical Digest (Optical Society of America, Washington DC, 2001), pp. MD3-1–3 (2001). [4 citations]
  136. L. Martinu, D. Poitras, "Invited review paper: Plasma deposition of optical films and coatings: A review," J. Vac. Sci. and Technol. A, 18(6) 2619–2645 (2000). [513 citations]
  137. D. Poitras, L. Martinu, "Interphase in plasma-deposited films on plastics: effect on the spectral properties of optical filters," Appl. Opt., 39, 1168–1173 (2000). [28 citations]
  138. A. Bergeron, D. Poitras, L. Martinu, "Interphase in plasma-deposited silicon nitride optical films on polycarbonate: in situ ellipsometric characterization," Opt. Eng., 39, 825–831 (2000). [10 citations]
  139. D. Rats, D. Poitras, J.M. Soro, L. Martinu and J. von Stebut, "Mechanical properties of plasma-deposited silicon-based inhomogeneous optical coatings," Surf. Coat. Technol., 111, 220–228 (1999). [34 citations]
  140. D. Poitras, L. Martinu, "A simple method for the determination of slowly varying refractive index profiles from in situ spectrophotometric measurements," Appl. Opt., 37, 4160–4167 (1998). [11 citations]
  141. A. Bergeron, D. Poitras and L. Martinu, “Effect of the interphase on the properties of optical filters fabricated by PECVD on polycarbonate,” OSA Optical Interference Coatings, June 7–12, Tucson AZ, USA, 1998.
  142. J.E. Klemberg-Sapieha, D. Poitras, L. Martinu, N.L.S. Yamasaki and C.W. Lantman, "Effect of interface on the characteristics of functional films deposited on polycarbonate in dual-frequency plasma," J. Vac. Sci. Technol. A, 15, 985–991 (1997). [51 citations]
  143. D. Poitras, P. Leroux, J.E. Klemberg-Sapieha, S.C. Gujrathi and L. Martinu, "Characterization of homogeneous and inhomogeneous Si-based optical coatings deposited in dual-frequency plasma," Opt. Eng., 35, 2693–2699 (1996). [31 citations]
  144. S.C. Gujrathi, D. Poitras, J.E. Klemberg-Sapieha and L. Martinu, "ERD-TOF characterization of silicon-compound multilayer and graded-index optical coatings," Nucl. Instr. and Meth. B, 118, 560–565 (1995). [15 citations]
  145. W. Brinker, W. Wirges, G. Przyrembel, R. Gerhard-Multhaupt, J.E. Klemberg-Sapieha, L. Martinu, D. Poitras and M.R. Wertheimer, "Metallized viscoelastic control layers for light-valve projection displays", Displays, 16, 13–20 (1995). [17 citations]
  146. D. Poitras, P. Leroux, J.E. Klemberg-Sapieha, S.C. Gujrathi and L. Martinu, "Characterization of Silicon-Compound Multilayer and Graded-Index Optical Coatings deposited by Dual-Frequency Plasma", Proceedings of the  37th Annual Technical Conference of the Society of Vacuum Coaters (Society of Vacuum Coaters, Albuquerque, NM, 1994), pp. 31–36. [1 citation]
  147. L. Martinu, A. Raveh, D. Boutard, S. Houle, D. Poitras, N. Vella and M.R. Wertheimer, “Properties and stability of diamond-like carbon films related to bonded and unbonded hydrogen”, Diamond and Related Materials, 2, 673–677 (1993). [43 citations]
  148. D. Poitras, J.E. Klemberg-Sapieha, A. Moussi and L. Martinu, "Properties of multilayers and graded-index Si-based coatings deposited in dual-frequency plasma", Proc. SPIE, 2046, 179–188 (1993). [4 citations]
  149. O.M. Kuettel, L. Martinu, D. Poitras, J.E. Klemberg-Sapieha and M.R. Wertheimer, “Diamond-like carbon films deposited in a dual microwave radiofrequency plasma”, Mat. Sci. and Engineer., B11, 321–324 (1992). [15 citations]
  150. D. Poitras, O.M. Küttel, A. Raveh, J.E. Klemberg-Sapieha, L. Martinu and M..R. Wertheimer, "Comparison of processes in radio- and microwave frequency plasmas by optical emission spectroscopy", Proc. International Symposium on Plasma Chemistry (ISPC), 10, 6 pp (1991). [2 citations]
Daniel Poitras

Daniel Poitras

Agent(e) de recherches senior
Électronique et photonique avancées
1200, chemin de Montréal
Ottawa, Ontario K1A 0R6
Langue préférée : français
Autre(s) : anglais
Téléphone : 613-990-5965

Expertise

Sciences, Physique, Physique atomique, moléculaire et optique