Title :
Space-charge dynamics in a semiconductor nanoparticle and its potential for terahertz applications
Author :
Shen, Tina ; Yan, M. ; Wong, Ted
Author_Institution :
Coll. of Mater. Sci. & Eng., Kunming Univ. of Sci. & Technol., Kunming, China
Abstract :
Adjustable carrier concentration is an attractive feature of semiconductor nanoparticle that allows its surface plasmon resonance to be tuned. While quasi-static treatment of the electromagnetic interactions with the charge species can account for the polarization process in a conductive nanoparticle, a full-wave solution of the Maxwell´s equations is needed to give a realistic portrait of the current distribution when the nominal charge density exceeds 1020cm-3 in a typical nanoparticle. The analysis can be facilitated by the use of equivalent circuits, which readily give the induced dipole moment on a semiconductor nanoparticle in terms of material parameters and the radius of the particle. Prospects of semiconductor nanoparticles in terahertz technology are highlighted.
Keywords :
Maxwell equations; carrier density; current distribution; electric moments; nanoparticles; semiconductor materials; space charge; surface plasmon resonance; Maxwell equations; adjustable carrier concentration; conductive nanoparticle; current distribution; electromagnetic interactions; equivalent circuits; full-wave solution; induced dipole moment; nominal charge density; polarization process; quasistatic treatment; semiconductor nanoparticle; space-charge dynamics; surface plasmon resonance; terahertz applications; terahertz technology; Current distribution; Doping; Equations; Equivalent circuits; Materials; Nanoparticles; Plasmons;
Conference_Titel :
Nanotechnology (IEEE-NANO), 2013 13th IEEE Conference on
Conference_Location :
Beijing
Print_ISBN :
978-1-4799-0675-8
DOI :
10.1109/NANO.2013.6720860
