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.com

Volume 6

Research & Reviews: Journal of Material Sciences

Advanced Materials 2018

September 19-21, 2018

September 19-21, 2018 Tokyo, Japan

22

nd

International Conference on

Advanced Materials and Nanotechnology

Res. Rev. J Mat. Sci. 2018, Volume 6

DOI: 10.4172/2321-6212-C4-024

Ultra high pulse repetition frequency laser irradiation for in-depth melting and subsequent flawless

solidification of semiconducting material

Jong Kab Park

AP Systems Inc., Republic of Korea

A

n Ultra High Pulse Repetition Frequency (UHPRF) or Quasi Continuous Wave (QCW) laser was elaborately controlled and irradiated

on semiconductor layer steering bottomless melting of the void material to eventually aim at dense solidification. A massive deposition

of amorphous semiconductor, interconnection purpose for instant leads great number of defects and sizable voids which would result

in degradation of electrical performances of the device. There are numerous trials to remove or minimize such drawback by means of

physically trampling flaws by deposition of heavier atomic material otherwise pulsed laser irradiation which intends to do fully packed solid

transformation of the molten layer during solidification. In the case of photonic way, it is crucial to secure sufficient laser pulse duration

with energetic intensity simultaneously which is contradictory since high pulse energy from the laser is the outcome of extraction of laser

light in very short period of time. Either insufficient light intensity or short of pulse duration will cause shortage in melt volume, so the

defects and voids may not fully be covered. On the other hands, UHPRF laser emits selected wavelength of light ranging from ultra violet

to green with the pulsing period of 10 nanoseconds to 50 nanoseconds. Laser pulses come out extremely fast, so there is no time allowed

the material to undergo cooling and on the contrary, accumulation of successive laser energy while the material is remained yet in liquid

phase would effectively work to homogenously melt the entire material in depth. We have demonstrated complete melting followed by

firm recrystallization result originally starting from 400 nm a-Si via cross section TEM and diffraction pattern measurement which proves

dense transformation. Carefully manipulating key parameters would contribute for taking good control of melt depth, melt degree, surface

roughness, etc. Melting, annealing and recrystallization sort of semiconductor heat treatments can be appropriately applicable with it.

jonkpark1@apsystems.co.kr