Campus Directory

Division Baskin School of Engineering

Department/College/Unit Electrical and Computer Engineering

Title Adjunct Professor

Affiliation Faculty

Faculty Type Adjunct Faculty

Web Site

Primary Office Location Jack Baskin Engineering Building
N/A

Additional Location(s) Baskin Engineering, Room E2-247A

Office Hours By Appointment

Mail Stop SOE2

Summary of Expertise

Modeling of micro/nanoscale electronic materials and devices emphasizing energy-band and equivalent-circuit methods, comparison of modeling and experiments: InP, InSb, ZnO, In2O3, and GaAs semiconducting nanowires; carbon nanotubes/nanofibers devices; Si atomic chain devices; metallic nanoislands; strained Si/SiGe channels; GaAs lateral surface superlattice; Josephson devices, etc.

Research Interests

• Nanoscience and nanotechnology
• Physics of advanced electronic materials and devices including nanowires and nanocarbons for electronic, optoelectronic, and energy applications
• Materials theory and device modeling based on energy bands, equivalent circuits, analytical methods, Monte Carlo, and tight-binding
• Comparison to experiments

Selected Presentations

• T. Yamada, F. R. Madriz, and C. Y. Yang, (invited) "Inductance in One-dimensional Nanostructures," IEEE Trans. Elec. Dev. 56 (9), 1834-1839 (2009).
• T. Yamada, H. Yamada, A. J. Lohn, and N. P. Kobayashi, (invited) "Transport in fused InP nanowire device in dark and under illumination: Coulomb staircase scenario," (8106-19) SPIE Optics + Photonics 2011, San Diego, CA, Aug 22-25, 2011.
• A. Orphanou, T. Yamada*, and C. Y. Yang, (invited) "Modeling carbon nanotube ultracapacitor," IEEE Nanotechnology Materials and Devices Conference 2010 (NMDC 2010), Monterey, CA, Oct. 12-15, 2010.
• T. Yamada, (invited) "Precise Nanoelectronics with Adatom Chains," in the 196th Electrochemical Society Meeting, Honolulu, HI, Oct. 18-22, 1999
• T. Yamada, (invited) "Atomic Wires and their Electronic Properties," in the 24th Annual Conference on the Physics and Chemistry of Semiconductor Interfaces, Research Triangle, NC, Jan. 12-15, 1997.

Selected Publications

• T. Yamada, H. Yamada, A. J. Lohn, and N. P. Kobayashi, "Room-temperature Coulomb Staircase in Semiconducting InP Nanowires Modulated with Light Illumination", Nanotechnology 22 (5), 055201 (2011).
• T. Yamada, "Equivalent circuit model for carbon nanotube Schottky barrier: Influence of neutral polarized gas molecules," Appl. Phys. Lett. 88 (8), 083106 (2006).
• T. Yamada, "Modeling of Carbon Nanotube Schottky Barrier Modulation under Oxidizing Conditions," Phys. Rev. B 69 (12), 125408 (2004).
• T. Yamada, "Modeling of Kink-shaped Carbon-nanotube Schottky Diode with Gate Bias Modulation," Appl. Phys. Lett. 80 (21), 4027-4029 (2002).
• H. Kitsuki, T. Yamada*, D. Fabris, J. R. Jameson, P.Wilhite, M. Suzuki, and C. Y. Yang, "Length dependence of current-induced breakdown in carbon nanofiber interconnects," Appl. Phys. Lett. 92 (17), 173110 (2008).
• A. Orphanou*, T. Yamada*, and C. Y. Yang, "Modeling of a Carbon Nanotube Ultracapacitor," Nanotechnology 23 (9), 095401 (2012).
• T. Yamada, Y. Yamamoto, and W. A. Harrison, "Energy Band of Manipulated Atomic Structures on an Insulator Substrate," J. Vac. Sci. Technol. B 14 (2), 1243-1249 (1996).
• T. Yamada, "Modeling of electronic transport in scanning tunneling microscope tip-carbon nanotube systems," Appl. Phys. Lett. 78 (12), 1739-1741 (2001).
• P. Nguyen, H.T. Ng, T. Yamada, M. K. Smith, J. Li, J. Han, and M. Meyyappan, "Direct Integration of Metal Oxide Nanowire in Vertical Field-effect Transistor," Nano Lett. 4 (4), 651-657 (2004).
• T. Yamada, H. Yabutani, T. Saito, and C. Y. Yang, "Temperature Dependence of Carbon Nanofiber Resistance," Nanotechnology 21 (26), 265707 (2010).
• T. Yamada, C. W. Bauschlicher, and H. Partridge, "Substrate for Atomic Chain Electronics," Phys. Rev. B 59 (23), 15430-15436 (1999).
• H. T. Ng, J. Han, T. Yamada, P. Nguyen, Y. Chen, and M. Meyyapan, "Single Crystal Nanowire Vertical Surround Gate Field-effect Transistor," Nano Lett. 4 (7) 1247-1252 (2004).
• T. Yamada and D. K. Ferry, "Magnetotransport properties of lateral-surface superlattices by molecular-dynamics Monte Carlo simulation," Phys. Rev. B 47 (3), 1444-1452 (1993).

Courses EE135 Elemag Fields Waves: W06, W07
EE293 Special Topics Elect Eng: W14
EE227 Fund Semicond Physics: F14, F15, F16
EE232 Quantum Electronics: Sp15, Sp16, Sp17