Biography:Junichiro Kono

From HandWiki
Revision as of 21:30, 19 December 2020 by imported>BotanyGa (simplify)
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)

Junichiro Kono
Nationality Japan
Alma materUniversity of Tokyo
University at Buffalo
AwardsAndrew Heiskell Award
Scientific career
FieldsPhysics
Electrical engineering
InstitutionsUniversity of California, Santa Barbara
Stanford University
Rice University

Junichiro Kono is a professor in the Departments of Electrical and Computer Engineering, Physics and Astronomy, and Materials Science and NanoEngineering, at Rice University.

Bio

Junichiro Kono received his B.S. and M.S. degrees in applied physics from the University of Tokyo in 1990 and 1992, respectively, and completed his Ph.D. in physics from the State University of New York at Buffalo in 1995. He was a postdoctoral research associate in condensed matter physics at the University of California Santa Barbara from 1995-1997, and the W. W. Hansen Experimental Physics Laboratory Fellow in the Department of Physics at Stanford University from 1997-2000. He joined the Department of Electrical and Computer Engineering of Rice University in 2000 as an Assistant Professor and was promoted to Associate Professor in 2005 and to Professor in 2009. He is currently a Professor in the Departments of Electrical & Computer Engineering, Physics & Astronomy, and Materials Science & Nanoengineering at Rice University.[1] His research focuses on optical studies of condensed matter systems and photonic applications of nanosystems, including semiconductor nanostructures and carbon-based nanomaterials.[2] He has made a number of pioneering contributions to the diverse fields of semiconductor optics, terahertz spectroscopy and devices, ultrafast and quantum optics, and condensed matter physics.[3] In 2009 he was named a Fellow of the American Physical Society[4] and, in 2015, he was elected a Fellow of the Optical Society of America.[5]

Research

The Kono Lab's research focuses on optical studies of condensed matter systems and photonic applications of nanosystems, including semiconductor nanostructures and carbon-based nanomaterials.[2] He has made a number of pioneering contributions to the diverse fields of semiconductor optics, terahertz spectroscopy and devices, ultrafast and quantum optics, and condensed matter physics.[3]

Kono Lab

Prof. Kono's research is currently focused on the physics and applications of semiconductor nanostructures and quantum device structures. They use state-of-the-art spectroscopic techniques to study charge, spin, and vibrational dynamics in a variety of nanostructures. The impact of their research includes: increased understanding of the quantum states and dynamics of interacting, confined, or strongly driven electrons in nanostructures; new spectroscopy techniques; novel device concepts and implementations (especially towards all-optical switches and spin-based devices); establishment of the quantum nature of semiconductor-light interaction; progress towards the solid-state realization of quantum information processing, computation and communications; and provision of a controlled environment in which to address unanswered questions in many-body physics. Click here to read more about the Kono Lab.

RAMBO: Rice Advanced Magnet with Broadband Optics

Kono's lab has developed a truly unique experimental facility, called the Rice Advanced Magnet with Broadband Optics (RAMBO).[6] This facility houses an ultracompact pulsed magnet capable of producing a peak field of 30 Tesla, combined with an arsenal of state-of-the-art instruments for modern materials research. A unique feature of this system is the marriage of a strong magnetic field and ultrashort laser pulses from nearly “DC to daylight.” This unconventional coupling of two extreme conditions will likely lead to new scientific knowledge, advancing the frontier of materials research.

Group Members

For more information on Kono Group members and alumni see the People page of the lab website.

Research highlights of the Kono Lab

Educational Initiatives and International Collaboration/Internationalization

In collaboration with his colleagues Sarah Phillips (Rice University) and Dr. Cheryl Matherly (University of Tulsa), Kono established the nationally recognized[43][44][45] NSF-PIRE funded NanoJapan: IREU program (2006 - 2015).[46] Based on this program model, Kono and Rice University were selected by the Nakatnai Foundation of Japan to implement their 2016 - 2018 Nakatani RIES: Research and International Experience Fellowship for U.S. and Japanese undergraduates. Kono and Phillips have also received funding from the U.S.-Japan Council's TOMODACHI Initiative for the development of the 2016 - 2018 TOMODACHI STEM @ Rice University program for female Japanese undergraduates.

Kono has also developed an online ELEC 261: Electronic Materials and Quantum Devices[47] course that is offered during the summer term and open to students worldwide.

International Collaboration and Internationalization Efforts

As a faculty member at Rice, Kono has been instrumental to the initiation and implementation of numerous Memorandum of Understanding (MOUs) between Rice University and institutions worldwide including:

  • June 2018: Rice signs MOU with Federal University of Toulouse Midi-Pyrénées[48] (France)
  • October 2017: MOU with the Toyota Technological Institute (Japan)
  • July 2017: MOU with Chiba University (Japan)
  • July 2017: MOU with Kyoto University (Japan)
  • May 2017: MOU with Tohoku University (Japan)
  • July 2015: MOU with the Tokyo Institute of Technology (Japan)
  • May 2015: MOU with Osaka University (Japan)
  • May 2015: Renewal of MOU with Osaka Institute of Technology (Japan)
  • September 2014: School of Engineering level MOU with Tottori University (Japan)
  • April 2014: Rice, University of Tokyo Agree to Collaborate[49] (Japan)
  • October 2011: Exchange Agreement with Osaka University (Japan)
  • October 2011: MOU with Hokkaido University(Japan)
  • February 2010: MOU with the Osaka Institute of Technology (Japan)

Education Innovation Awards

  1. 2013 NASPA: Association of Student Affairs Administrators in Higher Education Best Practices in International Education Award for Study Abroad Programming
  2. 2013 Finalist for the NAFSA: Association of International Educator's Simon Spotlight Award
  3. 2012 National Academy of Engineering Report on "Infusing Real World Experiences into Engineering Education" [43]
    • One of only two international programs selected from entries nationwide to be profiled in the National Academy of Engineering’s 2012 Infusing Real World Experiences into Engineering Education
  4. 2008 Institute of International Education Heiskell Award as a ‘Best Practice’ in Study Abroad[44]
    • For the expansion of international opportunities to engineering and science students.

Alumni Updates

Educational Research Publications and Presentations

  1. Matherly, C.A., & and Phillips, S.R. (2016, November), Global Education through PIRE: Challenges and Successes of the NanoJapan Program. Invited talk at 18th Annual Colloquium on International Engineering Education, New York, New York.
  2. Matherly, C., & Ragusa, G., & Phillips, S. R., & Chapman, C. A. (2016, June), International vs. Domestic Research Experiences for Undergraduates (REU): A Three-Year Assessment of the Preparation of Students for Global Workforces. Paper presented at 2016 ASEE Annual Conference & Exposition, New Orleans, Louisiana. DOI: 10.18260/p. 27320[52]
  3. Matherly, C., & Phillips, S. R., & Chapman, C. A. (2015, June), The Impact of International Research Experiences on Undergraduate Learning. Paper presented at 2015 ASEE Annual Conference & Exposition, Seattle, Washington. DOI: 10.18260/p. 24881[53]
  4. Ragusa, G., & Matherly, C, & Phillips, S.R. (2014, October), Comparison of the Impact of Two Research Experiences for Undergraduate Programs on Preparing Students for Global Workforces. Paper presented at 2014 IEEE: Frontiers in Education Conference (FIE), Madrid, Spain. DOI: 10.1109/FIE.2014.7044297[54]
  5. Phillips, S.R., & Matherly, C.A, & Kono, J. (2014, September), NanoJapan-International research experience for undergraduates program: Fostering U.S.-Japan Research Collaborations in Terahertz Science and Technology of Nanostructures. Paper presented at Proc. SPIE 9188, Optics Education and Outreach III, 918805, San Diego, California. DOI:10.1117/12.2060166
  6. Phillips, S.R., & Matherly, C.A. (2014). "Expanding International Opportunities for Science and Engineering Students: A Case Study of the NanoJapan International Research Experience for Undergraduates Program", IIE Networker, Fall 2014.[55]
  7. Phillips, S.R., & Matherly, C.A., & Kono, J. (2014). "NanoJapan: An International Research Experience," Optics & Photonics News, June 2014, pp. 18–19.[56]
  8. Matherly, C., & Phillips, S. R., & Kono, J., & Curtis, S. M. (2014, June), Why Invest in International Research Experiences for Undergraduates?: Intercultural Maturity in Domestic and International REU Participants. Paper presented at 2014 ASEE International Forum, Indianapolis, Indiana. https://peer.asee.org/17205[57]
  9. Matherly, C., & Phillips, S. R., & Kono, J. (2013, June), NanoJapan International Research Experience for Undergraduates. Paper presented at 2013 ASEE International Forum, Atlanta, Georgia. https://peer.asee.org/17260[58]
  10. Besterfield-Sacre, M. E., & Ragusa, G., & Matherly, C., & Phillips, S. R., & Shuman, L. J., & Howard, L. (2013, June), Assessing the Spectrum of International Undergraduate Engineering Educational Experiences Paper presented at 2013 ASEE International Forum, Atlanta, Georgia. https://peer.asee.org/1722[59]
  11. Matherly, C.A., & Phillips, S.R., & Brooks, E., & and Yamada, M. (2012, December), A U.S. And Japanese Student Outlook On The Impact Of International Research Internships. Invited talk at the Third International Symposium on Terahertz Nanoscience, Honolulu, Hawaii.
  12. Matherly, C.A, & Phillips, S.R., & and Kono, J. (2011). "NanoJapan: Connecting U.S. Undergraduates with the Best of Nanoscience Research in Japan," APS Physics Forum on Education Newsletter, Spring 2011.[60]
  13. Matherly, C.A., & and Phillips, S.R. (2011). "NanoJapan: Preparing Globally Savvy Researchers," IIE Networker, (Spring 2011).[61]
  14. Kono, J., & Phillips, S.R., & and Matherly, C.A. (2008). "Rice University NanoJapan Program: Connecting US Undergraduates with Leading Japanese Nanotechnology Research Laboratories: National Science Foundation and NSF PIRE:U.S.-Japan Cooperative Research and Education Ultrafast and Nonlinear Optics in 6.1 Angstrom Semiconductors", Tokyo Regional Office National Science Foundation, Tokyo Regional Office: Special Scientific Report #08-01.[62]
  15. Alexander, L., & Matherly, C., & Besterfield-Sacre, M., & Shuman, L. (2008, June), Internationalizing Our Engineers: Short Term Experiential Programs Abroad For Engineering Students Paper presented at 2008 Annual Conference & Exposition, Pittsburgh, Pennsylvania. https://peer.asee.org/3669[63]
  16. Phillips, S.R. (2008, March), Study Abroad for Science and Technology Students, Invited talk at 3rd Annual IIE Best Practices Conference, New York City, New York.
  17. Matherly, C., & Nolting, W. (2007, March). Educational experience abroad: Preparation for a globalized workplace. National Association of Colleges and Employers (NACE) Journal, 14–44.

Media Articles

Undergraduate Peer-reviewed Journal Articles

To date, 13 undergraduate students participating in the NanoJapan: IREU and the Nakatani RIES Fellowship have also had their summer research published in peer-reviewed journals including the following. Undergraduate student authors are in bold.

  1. Liu, H., Ukhtary, M.S., and Saito, R., "Hidden symmetries in N-layer dielectric stacks", Journal of Physics: Condensed Matter 29, 45 (2017).[75]
    • This paper was recognized by the Journal of Physics: Condensed Matter to be spotlighted as one of their 2017 Highlights.[76] This collection includes outstanding articles published in the journal during 2017. These articles were selected on the basis of a range of criteria including referee endorsements, presentation of outstanding research and popularity with our online readership.
  2. C.B. Reynolds, M. Shoufie Ukhtary, and R. Saito, “Absorption of THz Electromagnetic Wave in Two Mono-layers of Graphene,” Journal of Physics D: Applied Physics 49, 195306 (2016).[77]
  3. Sano, I. Kawayama, M. Tabata, K. A. Salek, H. Murakami, M. Wang, R. Vajtai, P. M. Ajayan, J. Kono, and M. Tonouchi, “Imaging Molecular Adsorption and Desorption Dynamics on Graphene Using Terahertz Emission Spectroscopy,” Scientific Reports, (2014). doi:10.1038/srep06046[78]
  4. He, N. Fujimura, J. M. Lloyd, K. J. Erickson, A. A. Talin, Q. Zhang, W. Gao, Q. Jiang, Y. Kawano, R. H. Hauge, F. Léonard, and J. Kono, “Carbon Nanotube Terahertz Detector,” Nano Letters 14, 7 (2014). Doi: 10.1021/nl5012678
  5. Ushiba, J. Hoyt, K. Masui, J. Kono, S. Kawata, and S. Shoji, “Macroscopic Ensembles of Aligned Carbon Nanotubes in Bubble Imprints Studied by Polarized Raman Microscopy,” Journal of Nanomaterials 2014, 632501 (2014).[79]
  6. R. T. Nugraha, E. I. Rosenthal, E. H. Hasdeo, G. D. Sanders, C. J. Stanton, M. S. Dresselhaus, and R. Saito, “Excitonic Effects on Coherent Phonon Dynamics in Single-Wall Carbon Nanotubes,” Physical Review B 88, 075440 (2013). doi: 10.1103/PhysRevB.88.075440[80]
  7. Ushiba, S. Shoji, K. Masui, P. Kuray, J. Kono, and S. Kawata, "3D Microfabrication of Single-Wall Carbon Nanotube/Polymer Composites by Two-Photon Polymerization Lithography," Carbon 59, 283 (2013). doi: 10.1016/j.carbon.2013.03.020[81]
  8. M. Mahjoub, A. Nicol, T. Abe, T. Ouchi, Y. Iso, M. Kida, N. Aoki, K. Miyamoto, T. Omatsu, J. P. Bird, D. K. Ferry, K. Ishibashi, and Y. Ochiai, "GR-FET Application for High-frequency Detection Device,” Nanoscale Research Letters 8, 22 (2013). doi: 10.1186/1556-276X-8-22[82]
  9. Ren, Q. Zhang, C. L. Pint, A. K. Wójcik, M. Bunney, T. Arikawa, I. Kawayama, M. Tonouchi, R. H. Hauge, A. A. Belyanin, and J. Kono, "Collective Antenna Effects in the Terahertz and Infrared Response of Highly Aligned Carbon Nanotube Arrays," Physical Review B 87, 161401(R) (2013). doi: 10.1103/PhysRevB.87.161401[83]
  10. T. Yuan, M. Toh, K. Morimoto, W. Tan, F. Wei, H. Shimotani, Ch. Kloc, and Y. Iwasa, "Liquid-Gated Electric-Double-Layer Transistor on Layered Metal Dichalcogenide, SnS2," Applied Physics Letters 98, 012102 (2011).[84]
  11. Zhao, E. Einarsson, G. Lagoudas, J. Shiomi, S. Chiashi, and S. Maruyama "Tunable Separation of Single-walled Carbon Nanotubes by Dual-surfactant Density Gradient Ultracentrifugation," Nano Research 4, 623 (2011).[85]
  12. Dresselhaus-Cooper, L., H. Amano, M. Hiraide, S. Houkyou, I. Y. Jang, Y. J. Kim, H. Muramatsu, J. H. Kim, T. Hayashi, Y. A. Kim, M. Endo, and M. S. Dresselhaus, "Freestanding, Bendable, Thin Film for Supercapacitors Using DNA-Dispersed Double Walled Carbon Nanotubes," Applied Physics Letters 95, 233104 (2009).[86]
  13. Murakami,T., B. Lu, S. Kazaoui, N. Minami, T. Okubo, and S. Maruyama, "Photoluminescence Sidebands of Carbon Nanotubes Below the Bright Singlet Excitonic Levels," Physical Review B 79, 195407 (2009).

References

  1. "Junichiro Kono | Department of Electrical and Computer Engineering (ECE) | Rice University" (in en). https://eceweb.rice.edu/junichiro-kono. 
  2. 2.0 2.1 "Research | Junichiro Kono Laboratory" (in en-US). http://kono.rice.edu/research/. 
  3. 3.0 3.1 "Publications | Junichiro Kono Laboratory" (in en-US). http://kono.rice.edu/kono-bio/publications/. 
  4. "APS Fellowship" (in en). https://www.aps.org/units/dcmp/fellowship/index.cfm?year=. 
  5. "Kono named Optical Society fellow" (in en-US). http://news.rice.edu/2014/12/04/kono-named-optical-society-fellow/. 
  6. 6.0 6.1 "RAMBO a small but powerful magnet" (in en-US). http://news.rice.edu/2014/01/06/rambo-a-small-but-powerful-magnet/. 
  7. "Rice U. lab finds evidence of matter-matter coupling" (in en-US). http://news.rice.edu/2018/08/23/rice-u-lab-finds-evidence-of-matter-matter-coupling-2/. 
  8. "Scientists go deep to quantify perovskite properties" (in en-US). http://news.rice.edu/2018/06/08/scientists-go-deep-to-quantify-perovskite-properties-2/. 
  9. "'Exceptional' research points way toward quantum discoveries" (in en-US). http://news.rice.edu/2018/04/30/exceptional-research-points-way-toward-quantum-discoveries-2/. 
  10. "Quantum shift shows itself in coupled light and matter" (in en-US). http://news.rice.edu/2018/04/16/quantum-shift-shows-itself-in-coupled-light-and-matter-2/. 
  11. "Plasmons triggered in nanotube quantum wells" (in en-US). http://news.rice.edu/2018/03/16/plasmons-triggered-in-nanotube-quantum-wells-2/. 
  12. "Rules for superconductivity mirrored in 'excitonic insulator'" (in en-US). http://news.rice.edu/2017/12/07/rules-for-superconductivity-mirrored-in-excitonic-insulator-2/. 
  13. "Light and matter merge in quantum coupling" (in en-US). http://news.rice.edu/2016/08/22/light-and-matter-merge-in-quantum-coupling-2/. 
  14. "Nanotubes line up to form films" (in en-US). http://news.rice.edu/2016/04/04/nanotubes-line-up-to-form-films-2/. 
  15. 15.0 15.1 "New test reveals purity of graphene" (in en-US). http://news.rice.edu/2014/08/13/new-test-reveals-purity-of-graphene-2/. 
  16. "Terahertz tech gets a major push at Rice" (in en-US). http://news.rice.edu/2014/06/24/terahertz-tech-gets-a-major-push-at-rice-2/. 
  17. 17.0 17.1 "Nanotubes boost terahertz detectors" (in en-US). http://news.rice.edu/2014/06/11/nanotubes-boost-terahertz-detectors/. 
  18. "Rice's carbon nanotube fibers outperform copper" (in en-US). http://news.rice.edu/2014/02/13/rices-carbon-nanotube-fibers-outperform-copper-2/. 
  19. "Scientists scale terahertz peaks in nanotubes" (in en-US). http://news.rice.edu/2013/12/06/scientists-scale-terahertz-peaks-in-nanotubes-2/. 
  20. "Flashes of brilliance" (in en-US). http://news.rice.edu/2013/11/25/flashes-of-brilliance-2/. 
  21. "Broadband photodetector for polarized light" (in en-US). http://news.rice.edu/2013/07/16/broadband-photodetector-for-polarized-light-2/. 
  22. "Not-weak knots bolster carbon fiber" (in en-US). http://news.rice.edu/2013/07/08/not-weak-knots-bolster-carbon-fiber-2/. 
  23. "Rice builds nanotube photodetector" (in en-US). http://news.rice.edu/2013/02/27/rice-builds-nanotube-photodetector-2/. 
  24. "Essential armchair reading for nanotube researchers" (in en-US). http://news.rice.edu/2013/02/05/essential-armchair-reading-for-nanotube-researchers-2/. 
  25. "New nanotech fiber: Robust handling, shocking performance" (in en-US). http://news.rice.edu/2013/01/10/new-nanotech-fiber-robust-handling-shocking-performance-2/. 
  26. "Feds enlist Rice for nanocarbon project" (in en-US). http://news.rice.edu/2012/10/16/feds-enlist-rice-for-nanocarbon-project-2/. 
  27. "Electrified graphene a shutter for light" (in en-US). http://news.rice.edu/2012/06/14/electrified-graphene-a-shutter-for-light-2/. 
  28. Horiuchi, Noriaki (Feb 2012). "Terahertz nano-exploration" (in En). Nature Photonics 6 (2): 82–83. doi:10.1038/nphoton.2012.4. ISSN 1749-4885. Bibcode2012NaPho...6...82H. https://www.nature.com/articles/nphoton.2012.4. 
  29. "Many bodies make one coherent burst of light" (in en-US). http://news.rice.edu/2012/01/30/many-bodies-make-one-coherent-burst-of-light/. 
  30. "Terahertz polarizer nears perfection" (in en-US). http://news.rice.edu/2012/01/25/terahertz-polarizer-nears-perfection/. 
  31. "Scientists solve mystery of colorful armchair nanotubes" (in en-US). http://news.rice.edu/2012/01/11/scientists-solve-mystery-of-colorful-armchair-nanotubes/. 
  32. 32.0 32.1 "Rice University's award-winning NanoJapan program wins $4M grant" (in en-US). http://news.rice.edu/2010/09/21/rice-universitys-award-winning-nanojapan-program-wins-4m-grant/. 
  33. "Magnets trump metallics" (in en-US). http://news.rice.edu/2010/07/08/magnetic-fields-can-block-conductivity-of-carbon-nanotubes/. 
  34. "Nano parfait a treat for scientists" (in en-US). http://news.rice.edu/2010/05/12/nano-parfait-a-treat-for-scientists-2/. 
  35. "Gecko's lessons transfer well" (in en-US). http://news.rice.edu/2010/01/22/geckos-lessons-transfer-well-2/. 
  36. "Rice lab makes solid material transparent to terahertz waves" (in en-US). http://news.rice.edu/2009/12/09/rice-lab-makes-solid-material-transparent-to-terahertz-waves/. 
  37. "Fulbright scholarship winner Jonah Shaver heads to France to expand nanotechnology research" (in en-US). http://news.rice.edu/2008/07/17/fulbright-scholarship-winner-jonah-shaver-heads-to-france-to-expand-nanotechnology-research/. 
  38. "NSF center to transform sensor technology" (in en-US). http://news.rice.edu/2006/05/04/nsf-center-to-transform-sensor-technology/. 
  39. "Rice-led team sheds light on nanotube mystery of dark excitons" (in en-US). http://news.rice.edu/2006/01/12/rice-led-team-sheds-light-on-nanotube-mystery-of-dark-excitons/. 
  40. 40.0 40.1 "Rice receives $2.2M for international project" (in en-US). http://news.rice.edu/2005/12/15/rice-receives-2-2m-for-international-project/. 
  41. "Three faculty win NSF grants" (in en-US). http://news.rice.edu/2005/02/17/three-faculty-win-nsf-grants/. 
  42. "Professors earn Welch grants for chemistry research" (in en-US). http://news.rice.edu/2001/05/24/professors-earn-welch-grants-for-chemistry-research/. 
  43. 43.0 43.1 National Research Council. (2012). "NanoJapan: Connecting U.S. Undergraduates with the Best of Nanotechnology Research in Japan", Infusing Real World Experiences into Engineering Education, Washington, DC: The National Academies Press, pp. 35.
  44. 44.0 44.1 S. Bishop. (2008). "2008 Heiskell Awards: Best Practices in International Education", IIENetworker, Spring, pp. 12 – 18.
  45. "Rice University & The University of Tulsa". https://www.iie.org/en/Research-and-Insights/Best-Practices-Resource/Award-Winners/Study-Abroad/Rice-and-Tulsa-2008. 
  46. "TeraNano PIRE/NanoJapan: IREU (Archived Site) | 2006 – 2015 NSF-PIRE, PI Prof. Junichiro Kono, Rice University" (in en-US). http://nanojapan.blogs.rice.edu/. 
  47. "ELEC 261: Electronic Materials & Quantum Devices | Rice Online Learning" (in en-US). Rice Online Learning. http://online.rice.edu/courses/elec-261/. 
  48. "Rice signs MOU with Federal University of Toulouse Midi-Pyrénées" (in en-US). http://news.rice.edu/2018/06/18/rice-signs-mou-with-federal-university-of-toulouse-midi-pyrenees/. 
  49. "Rice, University of Tokyo agree to collaborate" (in en-US). http://news.rice.edu/2014/04/07/rice-university-of-tokyo-agree-to-collaborate/. 
  50. "Voices of the TOMODACHI Generation: Natsumi Komatsu" (in en-US). TOMODACHI. http://usjapantomodachi.org/get-involved/tomodachi-generation/natsumi_komatsu/. 
  51. "Three engineers named Goldwater Scholars | Rice Engineering | Rice University" (in en). https://engineering.rice.edu/news/three-engineers-named-goldwater-scholars. 
  52. Matherly, Cheryl; Ragusa, Gisele; Phillips, Sarah; Chapman, Cody (2016-06-26). International vs. Domestic Research Experiences for Undergraduates (REU): A Three-Year Assessment of the Preparation of Students for Global Workforces. doi:10.18260/p.27320. ISBN 9780692685655. http://peer.asee.org/27320. 
  53. Matherly, Cheryl; Phillips, Sarah; Chapman, Cody (2015-06-14). The Impact of International Research Experiences on Undergraduate Learning. 26.1544.1–26.1544.27. doi:10.18260/p.24881. ISBN 9780692501801. http://peer.asee.org/24881. 
  54. Ragusa, Gisele; Matherly, Cheryl; Phillips, Sarah (Oct 2014) (in en-US). Comparison of the impact of two research experiences for undergraduate programs on preparing students for global workforces. doi:10.1109/fie.2014.7044297. ISBN 9781479939220. http://ieeexplore.ieee.org/document/7044297/. 
  55. "Expanding International Opportunities for Engineering and Science Students". http://www.naylornetwork.com/iie-nwl/articles/index.asp?aid=292076&issueID=33380. 
  56. Phillips, S.R., & Matherly, C.A., & Kono, J. (2014). "NanoJapan: An International Research Experience," Optics & Photonics News, June 2014, pp. 18-19. https://www.osa-opn.org/home/articles/volume_25/june_2014/departments/nanojapan_an_international_research_experience/
  57. Curtis, Cheryl Matherly, Sarah R. Phillips, Junichiro Kono, Shane M (2014-06-14). "Why Invest in International Research Experiences for Undergraduates?: Intercultural Maturity in Domestic and International REU Participants". 2014 ASEE International Forum. https://peer.asee.org/17205. 
  58. Kono, Cheryl Matherly, Sarah R. Phillips, Junichiro (2013-06-22). "NanoJapan International Research Experience for Undergraduates:". 2013 ASEE International Forum. https://peer.asee.org/17260. 
  59. Rad, Amir Jokar, Hakan Gurocak, Dave Kim, Xiaolin Chen, Hamid (2007-06-24). "Multi Dimensional And Interactive Learning Model For Introduction To Mechanical Engineering". 2007 Annual Conference & Exposition. ISSN 2153-5965. https://peer.asee.org/1722. 
  60. "NanoJapan: Connecting U.S. Undergraduates with the Best of Nanoscience Research in Japan" (in en). https://www.aps.org/units/fed/newsletters/spring2011/matherly.cfm. 
  61. Matherly, C.A., & and Phillips, S.R. (2011). "NanoJapan: Preparing Globally Savvy Researchers," IIE Networker, (Spring 2011)
  62. Kono, J., & Phillips, S.R., & and Matherly, C.A. (2008). "Rice University NanoJapan Program: Connecting US Undergraduates with Leading Japanese Nanotechnology Research Laboratories: National Science Foundation and NSF PIRE:U.S.-Japan Cooperative Research and Education Ultrafast and Nonlinear Optics in 6.1 Angstrom Semiconductors", Tokyo Regional Office National Science Foundation, Tokyo Regional Office: Special Scientific Report #08-01.
  63. Shuman, Lauren Alexander, Cheryl Matherly, Mary Besterfield-Sacre, Larry (2008-06-22). "Internationalizing Our Engineers: Short Term Experiential Programs Abroad For Engineering Students". 2008 Annual Conference & Exposition. ISSN 2153-5965. https://peer.asee.org/3669. 
  64. "Tomodachi Women in STEM Visit to DOE" (in en). https://www.energy.gov/ne/articles/tomodachi-women-stem-visit-doe. 
  65. "NanoJapan a big experience" (in en-US). http://news.rice.edu/2013/08/05/nanojapan-a-big-experience/. 
  66. "Rice-Columbia course examines frontiers of physics research" (in en-US). http://news.rice.edu/2013/12/10/rice-columbia-course-examines-frontiers-of-physics-research/. 
  67. "Academy report is twice as nice for Rice engineering" (in en-US). http://news.rice.edu/2012/11/15/academy-report-is-twice-as-nice-for-rice-engineering-2/. 
  68. staff, Compiled by Photonics Spectra. "Earthquake impact reverses NanoJapan plans". https://www.photonics.com/a47964. 
  69. "The beat goes on for NanoJapan program" (in en-US). http://news.rice.edu/2011/06/16/the-beat-goes-on-for-nanojapan-program/. 
  70. "Reverse NanoJapan: Rice to host 25-30 Japanese students" (in en-US). http://news.rice.edu/2011/05/11/reverse-nanojapan-rice-to-host-25-30-japanese-students-2/. 
  71. "NanoJapan expands summer intern program" (in en-US). http://news.rice.edu/2009/07/14/nanojapan-expands-summer-intern-program/. 
  72. Moore, Kenneth J.. "International Internships | November 3, 2008 Issue - Vol. 86 Issue 44 | Chemical & Engineering News". https://cen.acs.org/articles/86/i44/International-Internships.html. 
  73. Moore, Kenneth J.. "Cultural Confusion | November 3, 2008 Issue - Vol. 86 Issue 44 | Chemical & Engineering News". https://cen.acs.org/articles/86/i44/Cultural-Confusion.html. 
  74. "Rice wins innovation award for international program" (in en-US). http://news.rice.edu/2008/01/30/rice-wins-innovation-award-for-international-program-2/. 
  75. Liu, Haihao; Ukhtary, M. Shoufie; Saito, Riichiro (2017). "Hidden symmetries in N -layer dielectric stacks" (in en). Journal of Physics: Condensed Matter 29 (45): 455303. doi:10.1088/1361-648X/aa865c. ISSN 0953-8984. PMID 28809756. Bibcode2017JPCM...29S5303L. http://stacks.iop.org/0953-8984/29/i=45/a=455303. 
  76. "Highlights of 2017 - Journal of Physics: Condensed Matter - IOPscience" (in en). http://iopscience.iop.org/journal/0953-8984/page/Highlights-2017. 
  77. Reynolds, Cole B.; Ukhtary, M. Shoufie; Saito, Riichiro (2016). "Absorption of THz electromagnetic wave in two mono-layers of graphene" (in en). Journal of Physics D: Applied Physics 49 (19): 195306. doi:10.1088/0022-3727/49/19/195306. ISSN 0022-3727. Bibcode2016JPhD...49s5306R. http://stacks.iop.org/0022-3727/49/i=19/a=195306. 
  78. Sano, Y.; Kawayama, I.; Tabata, M.; Salek, K. A.; Murakami, H.; Wang, M.; Vajtai, R.; Ajayan, P. M. et al. (2014-08-13). "Imaging molecular adsorption and desorption dynamics on graphene using terahertz emission spectroscopy" (in En). Scientific Reports 4 (1): 6046. doi:10.1038/srep06046. ISSN 2045-2322. PMID 25116593. PMC 4131213. Bibcode2014NatSR...4E6046S. http://www.nature.com/articles/srep06046. 
  79. Ushiba, Shota; Hoyt, Jordan; Masui, Kyoko; Kono, Junichiro; Kawata, Satoshi; Shoji, Satoru (2014). "Macroscopic Ensembles of Aligned Carbon Nanotubes in Bubble Imprints Studied by Polarized Raman Microscopy" (in en). Journal of Nanomaterials 2014: 1–7. doi:10.1155/2014/632501. ISSN 1687-4110. 
  80. Nugraha, A. R. T. (2013). "Excitonic effects on coherent phonon dynamics in single-wall carbon nanotubes". Physical Review B 88 (7): 075440. doi:10.1103/PhysRevB.88.075440. Bibcode2013PhRvB..88g5440N. 
  81. Ushiba, Shota; Shoji, Satoru; Masui, Kyoko; Kuray, Preeya; Kono, Junichiro; Kawata, Satoshi (Aug 2013). "3D microfabrication of single-wall carbon nanotube/polymer composites by two-photon polymerization lithography". Carbon 59: 283–288. doi:10.1016/j.carbon.2013.03.020. ISSN 0008-6223. http://linkinghub.elsevier.com/retrieve/pii/S000862231300239X. 
  82. Mahjoub, Akram M.; Nicol, Alec; Abe, Takuto; Ouchi, Takahiro; Iso, Yuhei; Kida, Michio; Aoki, Noboyuki; Miyamoto, Katsuhiko et al. (2013-01-10). "GR-FET application for high-frequency detection device". Nanoscale Research Letters 8 (1): 22. doi:10.1186/1556-276X-8-22. ISSN 1556-276X. PMID 23305264. Bibcode2013NRL.....8...22M. 
  83. Ren, L. (1614). "Collective antenna effects in the terahertz and infrared response of highly aligned carbon nanotube arrays". Physical Review B 87 (16): 161401. doi:10.1103/PhysRevB.87.161401. Bibcode2013PhRvB..87p1401R. 
  84. Zhao, Pei; Einarsson, Erik; Lagoudas, Georgia; Shiomi, Junichiro; Chiashi, Shohei; Maruyama, Shigeo (2011-03-24). "Tunable separation of single-walled carbon nanotubes by dual-surfactant density gradient ultracentrifugation" (in en). Nano Research 4 (7): 623–634. doi:10.1007/s12274-011-0118-9. ISSN 1998-0124. 
  85. H. T. Yuan, M. Toh, K. Morimoto, W. Tan, F. Wei, H. Shimotani, Ch. Kloc, and Y. Iwasa, "Liquid-gated electric-double-layer transistor on layered metal dichalcogenide", Applied Physics Letters 91, 1 (2011). https://doi.org/10.1063/1.3535613
  86. Dresselhaus-Cooper, L., H. Amano, M. Hiraide, S. Houkyou, I. Y. Jang, Y. J. Kim, H. Muramatsu, J. H. Kim, T. Hayashi, Y. A. Kim, M. Endo, and M. S. Dresselhaus, "Freestanding, Bendable, Thin Film for Supercapacitors Using DNA-Dispersed Double Walled Carbon Nanotubes," Applied Physics Letters 95, 233104 (2009). https://doi.org/10.1063/1.3271768

External links