Presentation is loading. Please wait.

Presentation is loading. Please wait.

Fabrication of Silicon Nanocones Using RF Microplasma Jet at Atmospheric Pressure 18th SYMPOSIUM ON PLASMA SCIENCE FOR MATERIALS (SPSM-18) ○ Zhongshi Yang.

Published byCathleen Skinner Modified over 8 years ago

Similar presentations

Presentation on theme: "Fabrication of Silicon Nanocones Using RF Microplasma Jet at Atmospheric Pressure 18th SYMPOSIUM ON PLASMA SCIENCE FOR MATERIALS (SPSM-18) ○ Zhongshi Yang."— Presentation transcript:

1 Fabrication of Silicon Nanocones Using RF Microplasma Jet at Atmospheric Pressure 18th SYMPOSIUM ON PLASMA SCIENCE FOR MATERIALS (SPSM-18) ○ Zhongshi Yang  Research Background  Micro-analysis of the Cone Structures  Mechanism of the SNC Growth  Conclusions

2 背景背景 Synthesis of silicon and carbon nanostructures Research Background field emission devices, UV laser, FET, sensors RF microplasma jet at atmospheric pressure on Fe coated c-Si using a CH 4 -Ar mixture CNTs Nanocones Nanopillars CVD, laser ablation, RIE, electrodeposition

3 c-Si Fe CH 4 Ar Plasma Fabrication Conditions Fabrication Conditions Cathode: WC tube with d of 700 µm Substrate: Fe coated c-Si Fr(Ar):50sccm Fr(CH 4 ) :50 sccm D : 4 mm T s :400ºC RF power:40W

4 The inner diameter of Electrode : 700 µm : 400 ~ ~ 600 μ μ m m : 600 ~ ~ 800 μ μ m m B B C C 100nm SEM Image 1.5 μ m 1.5 μ m A : 400μm : 400μm

5 Si O 5μ m Surface Distribution of elements EDX Spectra SEM Image 5μ m C Fe Silicon nanocones (SNCs) Come-shaped products were mainly composed of silicon and SiO 2.

6 TEM 像 SNC A region 60 nm B region CNT SNWs 67nm 20nm 14nm Si 1 1 μ μ m m 1 1 μ μ m m EDX analysis Si nanocrystals are embedded in the cone region

7 Linear Surface Profile CH 4 introduction and Fe film are very important to the SNCs growth. (a) Ar & Ar+CH 4 plasma c-Si etched hole& no cones (a) Ar & Ar+CH 4 plasma c-Si etched hole & no cones (b) Ar plasma Fe/c-Si etched hole& no cones (b) Ar plasma Fe/c-Si etched hole & no cones (c) Ar+CH 4 plasma Fe/c-Si SNCs, SNWs, CNTs plasma substrate results plasma substrate results Fe/c-Si surface

8 ② 照射時間依存 1min 1min 30min 60min 10min ・ Number density increased ・ Average size increased 1 μm H R

9 Growth Model of SNCs Ar plasma jet ~20 nm thick Fe layer 1 High gas temperature (2000-3000K) of Ar microplasma jet. 2 Formation of FeSix and FeCx nanoclusters. 3 Catalytic growth by a diffusion of Si and nanocrystalline silicon particles through the FeSix nanoclusters. 4 Silicon oxidation at the outer walls by the plasma heating. CH 4 T g : 2000 ~ 3000K c-Si CH 4 nc-Si particle Si oxidation

10 Si Nanocones (SNCs) were synthesized on Fe-coated c-Si using RF microplasma jet at atmospheric pressure. 18th SYMPOSIUM ON PLASMA SCIENCE FOR MATERIALS (SPSM-18)

Download ppt "Fabrication of Silicon Nanocones Using RF Microplasma Jet at Atmospheric Pressure 18th SYMPOSIUM ON PLASMA SCIENCE FOR MATERIALS (SPSM-18) ○ Zhongshi Yang."

Similar presentations

A 10-a editie a Seminarului National de nanostiinta si nanotehnologie 18 mai 2011 Biblioteca Academiei Romane The versatility of catalytic LCVD technique.

A 10-a editie a Seminarului National de nanostiinta si nanotehnologie 18 mai 2011 Biblioteca Academiei Romane The versatility of catalytic LCVD technique.
FABRICATION PROCESSES

FABRICATION PROCESSES
National Science Foundation Synthesis of Solid Electrolyte (Li x Al y Si z O) via ALD Jane P. Chang, University of California-Los Angeles, DMR 0932761.

National Science Foundation Synthesis of Solid Electrolyte (Li x Al y Si z O) via ALD Jane P. Chang, University of California-Los Angeles, DMR
Atomic Emission Spectroscopy

Atomic Emission Spectroscopy
Production Methods of Carbon Nanomaterials

Production Methods of Carbon Nanomaterials
Silicon Nanowire based Solar Cells

Silicon Nanowire based Solar Cells
© intec 2002http://www.intec.rug.ac.be/groupsites/opto Fabrication Process Lithography Resist coating + soft bake Exposure Post-exposure bake + development.

© intec 2002http:// Fabrication Process Lithography Resist coating + soft bake Exposure Post-exposure bake + development.
Epitaxial growth of SiC on Si covered by SiC nanocrystals G

Epitaxial growth of SiC on Si covered by SiC nanocrystals G
Techniques of Synthesizing Wafer-scale Graphene Zhaofu ZHANG 2022 2056 1.

Techniques of Synthesizing Wafer-scale Graphene Zhaofu ZHANG
Metal-free-catalyst for the growth of Single Walled Carbon Nanotubes P. Ashburn, T. Uchino, C.H. de Groot School of Electronics and Computer Science D.C.

Metal-free-catalyst for the growth of Single Walled Carbon Nanotubes P. Ashburn, T. Uchino, C.H. de Groot School of Electronics and Computer Science D.C.
D. Nkazi, K. Owusu-Ansah and S.E. Iyuke Investigating the effect of a zeolite and calcium carbonate catalyst support on the production of carbon nanotubes.

D. Nkazi, K. Owusu-Ansah and S.E. Iyuke Investigating the effect of a zeolite and calcium carbonate catalyst support on the production of carbon nanotubes.
Effect of Environmental Gas on the Growth of CNT in Catalystically Pyrolyzing C 2 H 2 Minjae Jung*, Kwang Yong Eun, Y.-J. Baik, K.-R. Lee, J-K. Shin* and.

Effect of Environmental Gas on the Growth of CNT in Catalystically Pyrolyzing C 2 H 2 Minjae Jung*, Kwang Yong Eun, Y.-J. Baik, K.-R. Lee, J-K. Shin* and.
Bottom up method for preparing nanostructures: growth of carbon nanotubes Akos Kukovecz Universität Wien 2002.

Bottom up method for preparing nanostructures: growth of carbon nanotubes Akos Kukovecz Universität Wien 2002.
Chemical Nanoparticle Deposition of Oxide Nanostructured Thin Films 6. Conclusions 2. Experimental Setup 1. Abstract We have developed a novel approach.

Chemical Nanoparticle Deposition of Oxide Nanostructured Thin Films 6. Conclusions 2. Experimental Setup 1. Abstract We have developed a novel approach.
Structural and phase composition features of carbon films grown by DC PECVD process A.A. Zolotukhin, A.P. Volkov, A.O. Ustinov, A.N. Obraztsov, Physics.

Structural and phase composition features of carbon films grown by DC PECVD process A.A. Zolotukhin, A.P. Volkov, A.O. Ustinov, A.N. Obraztsov, Physics.
1 WIREBONDING CHARACTERIZATION AND OPTIMIZATION ON THICK FILM SU-8 MEMS STRUCTURES AND ACTUATORS LIGA and Biophotonics Lab NTHU Institute of NanoEngineering.

1 WIREBONDING CHARACTERIZATION AND OPTIMIZATION ON THICK FILM SU-8 MEMS STRUCTURES AND ACTUATORS LIGA and Biophotonics Lab NTHU Institute of NanoEngineering.
Chemical Vapor Deposition ( CVD). Chemical vapour deposition (CVD) synthesis is achieved by putting a carbon source in the gas phase and using an energy.

Chemical Vapor Deposition ( CVD). Chemical vapour deposition (CVD) synthesis is achieved by putting a carbon source in the gas phase and using an energy.
1 Reunion SOS nanotube12 13 octobre 2011 H. Okuno, J. Dijon, E. De Vito, E. Quesnel CEA Grenoble Liten-DTNM SOS nanotubes 12-13 octobre 2011.

1 Reunion SOS nanotube12 13 octobre 2011 H. Okuno, J. Dijon, E. De Vito, E. Quesnel CEA Grenoble Liten-DTNM SOS nanotubes octobre 2011.
Thin Film Deposition Prof. Dr. Ir. Djoko Hartanto MSc

Thin Film Deposition Prof. Dr. Ir. Djoko Hartanto MSc
Mg 2 NiH 4 thin films synthesis results. Main goals: hydrogenation of Mg 2 Ni thin films in high hydrogen pressure and temperature (p,T); analysis of.

Mg 2 NiH 4 thin films synthesis results. Main goals: hydrogenation of Mg 2 Ni thin films in high hydrogen pressure and temperature (p,T); analysis of.

Similar presentations

Ads by Google