Aniwat Tandaechanurat, Ph.D.
International School of Engineering, Faculty of Engineering, Chulalongkorn University, Bangkok 10330
Phone: +66-84-726-7270 Email: firstname.lastname@example.org
April 2006 – March 2009 Ph.D. in Electronic Engineering, The University of
April 2004 – March 2006 M. Eng. in Electronic Engineering, The University of
April 1999 – March 2003 B. Eng. with Honors in Electrical Engineering,
Chulalongkorn University,Bangkok, Thailand
- Work Experience:
October 2016 – Present Lecturer at ISE (Nano Engineering Program),
Faculty of Engineering, Chulalongkorn University,
March 2013 – September 2016 Project Engineer at PTT Innovation Park Project,
PTT Research & Technology Institute, PTT Public
Company Limited, Thailand
April 2009 – February 2013 Project Research Associate at Institute for Nano
Quantum Information Electronics (NanoQuine),
The University of Tokyo,Tokyo, Japan
- Courses Taught at ISE:
2182280 Semiconductor Devices I
2141400 Principles of Nanostructured Materials
2182440 Introduction to Nanoelectronics
2182480 Semiconductor Devices II
- Research Interests:
Quantum nanostructures, quantum dots, graphene, physics of photons and electrons in semiconductor nanostructures, nanofabrication technologies, nanophotonics, renewable energies, solar cells, energy storage, semiconductor-based devices, infrared light sources and detectors, lasers, waveguides, photonic crystals, photonic integrated circuits, application of nanophotonic devices to classical and quantum information processing
Numerical Simulation Tools: finite-difference time-domain (FDTD) method, plane-wave expansion (PWE) method, RSoft, MATLAB, and C
Semiconductor Fabrication Processes: molecular beam epitaxy, electron beam lithography, photolithography, inductively coupled plasma reactive ion etching, magnetron sputter deposition system, electron beam evaporation system, scanning electron microscopy, atomic force microscopy, and micromanipulation system. Experience with GaAs/AlGaAs/InAs/InGaAs/InSb/GaSb Germanium and Silicon material systems
Optical Characterization: room temperature and low temperature micro-photoluminescence/time-resolved photoluminescence measurements. Experience with lasers, optical spectrum analyzers, a liquid He microscopy cryostat, vacuum systems, computer-controlled data acquisition using LabVIEW, and single photon spectroscopy
Languages: Thai (native), English (fluent), Japanese (fluent, JLPT level N1)
- Honors and Awards:
September 2010 Poster Award 1st prize at The 9th International Photonic &
Electromagnetic Crystal Structures Meeting
(PECS IX, 2010), Granada, Spain
April 2010 2010 Solid State Devices and Materials (SSDM 2010)
Young Researcher Award
April 2009 CUDOS Oral prizes 1st prize at The 8th International
Photonic & Electromagnetic Crystal Structures Meeting
(PECS VIII, 2009),Sydney, Australia
October 2003 – March 2009 Monbukagakusho (Japan’s Ministry of Education, Culture,
Sports, Science and Technology) Scholarships
- Membership of Professional Societies:
1. Optical Society of America (OSA)
2. Japan Society of Applied Physics (JSAP)
- Selected Journal Publications:
1. A. Tandaechanurat*, N. Hauke*, T. Zabel, T. Reichert, H. Takagi, M. Kaniber, S. Iwamoto, D. Bougeard, J. J. Finley, G. Abstreiter, and Y. Arakawa, “A three-dimensional silicon photonic crystal nanocavity with enhanced emission from embedded germanium islands,” New Journal of Physics 14, 083035 (2012). (*These authors contributed equally to this work)
2. A. Tandaechanurat, S. Ishida, D. Guimard, M. Nomura, S. Iwamoto, and Y. Arakawa, “Lasing oscillation in a three-dimensional photonic crystal nanocavity with a complete bandgap,” Nature Photonics 5, 91-94 (2011).
3. A. Tandaechanurat, S. Ishida, D. Guimard, D. Bordel, M. Nomura, S. Iwamoto, and Y. Arakawa, “Lasing characteristics of a quantum-dot-3D-photonic-crystal-nanocavity coupled system: Interaction between fully confined electrons and photons,” AIP Conf. Proc. 1399, 1007-1008 (2011).
4. A. Tandaechanurat, S. Ishida, K. Aoki, D. Guimard, M. Nomura, S. Iwamoto, and Y. Arakawa, “Demonstration of high-Q (>8600) three-dimensional photonic crystal nanocavity embedding quantum dots,” Applied Physics Letters 94, 171115 (2009).
5. A. Tandaechanurat, S. Iwamoto, M. Nomura, N. Kumagai, and Y. Arakawa, “Increase of Q-factor in photonic crystal H1-defect nanocavities after closing of photonic bandgap with optimal slab thickness,” Optics Express 16, 448-455 (2008). (Selected as a recommended paper of the issue)
6. P. Narabadeesuphakorn, S. Thainoi, A. Tandaechanurat, S. Kiravittaya, N. Nuntawong, S. Sopitopan, S. Kanjanachuchai, S. Ratanathammaphan, and S. Panyakeow, “Twin InSb/GaAs Quantum Nano-Stripes: Growth Optimization and Related Properties,” MRS Communications (2017). (submitted)
7. P. Narabadeesuphakorn, J. Supasil, S. Thainoi, A. Tandaechanurat, S. Kiravittaya, N. Nuntawong, S. Sopitopan, S. Kanjanachuchai, S. Ratanathammaphan, and S. Panyakeow, “Growth Control of Twin InSb/GaAs Nano-Stripes by Molecular Beam Epitaxy,” MRS Advances (2017). (submitted)
8. T. Tajiri, S. Takahashi, A. Tandaechanurat, S. Iwamoto, and Y. Arakawa, “Design of a three-dimensional photonic crystal nanocavity based on a < 110 >-layered diamond structure,” Japanese Journal of Applied Physics 53, 04EG08 (2014).
9. S. Takahashi, A. Tandaechanurat, R. Igusa, Y. Ota, J. Tatebayashi, S. Iwamoto, and Y. Arakawa, “Giant optical rotation in a three-dimensional semiconductor chiral photonic crystal,” Optics Express 21, 29905-29913 (2013).
10. J.P. Fu, A. Tandaechanurat, S. Iwamoto, and Y. Arakawa, “Design of large-bandwidth single-mode operation waveguides in silicon three-dimensional photonic crystals using two guided modes,” Optics Express 21, 12443-12450 (2013).
11. D. Cao, A. Tandaechanurat, S. Nakayama, S. Ishida, S. Iwamoto, and Y. Arakawa, “Silicon-based three-dimensional photonic crystal nanocavity laser with InAs quantum-dot gain,” Applied Physics Letters 101, 191107 (2012).
12. Y. Arakawa, S. Iwamoto, M. Nomura, A. Tandaechanurat, and Y. Ota, “Cavity Quantum Electrodynamics and Lasing Oscillation in Single Quantum Dot-Photonic Crystal Nanocavity Coupled Systems,” IEEE Journal of Selected Topics in Quantum Electronics 18, 1818-1829 (2012).
13. Y. Arakawa, A. Tandaechanurat, S. Iwamoto, M. Nomura, and D. Guimard, “Advances in 3D Photonic Crystal Nanocavity with Quantum Dots,” Proceedings of SPIE. 7608, Quantum Sensing and Nanophotonic Devices VII, 76081A (2010).
14. M. Nomura, S. Iwamoto, A. Tandaechanurat, Y. Ota, N. Kumagai, and Y. Arakawa, “Photonic band-edge micro lasers with quantum dot gain,” Optics Express 17, 640-648 (2009).
15. L. Martiradonna, L. Carbone, A. Tandaechanurat, M. Kitamura, M. Nomura, M. Nishioka, S. Ishida, B. Antonazzo, T. Nakaoka, S. Iwamoto, C. Roberto and Y. Arakawa, “Two-dimensional photonic crystal resist membrane nanocavity embedding colloidal dot-in-a-rod nanocrystals,” Nano Letters 8, 260-264 (2008).
16. Y. Wakayama, A. Tandaechanurat, S. Iwamoto, and Y. Arakawa, “Design of high-Q photonic crystal microcavities with a graded square lattice for application to quantum cascade lasers,” Optics Express 16, 21321-21332 (2008).
**A full list of Journal and Conference Publications is available upon request**