Result: Nano-graphoepitaxy of semiconductors for 3D integration

Title:
Nano-graphoepitaxy of semiconductors for 3D integration
Authors:
CRNOGORAC, F, WITTE, D. J, CHOU, S. Y, PEASE, R. F. W, XIA, Q, RAJENDRAN, B, PICKARD, D. S, LIU, Z, MEHTA, A, SHARMA, S, YASSERI, A, KAMINS, T. I
Source:
Proceedings of the 32nd International Conference on Micro- and Nano-Engineering, Barcelona, 17-20 September 2006Microelectronic engineering. 84(5-8):891-894
Publisher Information:
Amsterdam: Elsevier Science, 2007.
Publication Year:
2007
Physical Description:
print, 8 ref
Original Material:
INIST-CNRS
Subject Terms:
Electronics, Electronique, Sciences exactes et technologie, Exact sciences and technology, Sciences appliquees, Applied sciences, Electronique, Electronics, Electronique des semiconducteurs. Microélectronique. Optoélectronique. Dispositifs à l'état solide, Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices, Transistors, Circuits intégrés, Integrated circuits, Conception. Technologies. Analyse fonctionnement. Essais, Design. Technologies. Operation analysis. Testing, Fabrication microélectronique (technologie des matériaux et des surfaces), Microelectronic fabrication (materials and surfaces technology), Circuit intégré monolithique, Monolithic integrated circuit, Circuito integrado monolítico, Circuit intégré, Integrated circuit, Circuito integrado, Couche mince, Thin film, Capa fina, Couche épaisse, Thick film, Capa espesa, Dispositif semiconducteur, Semiconductor device, Dispositivo semiconductor, Fabrication microélectronique, Microelectronic fabrication, Fabricación microeléctrica, Laser continu, CW laser, Laser continuo, Matériau amorphe, Amorphous material, Material amorfo, Nanolithographie, Nanolithography, Onde entretenue, Continuous wave, Onda continua, Structure 3 dimensions, Three dimensional structure, Estructura 3 dimensiones, Surchauffe, Superheating, Sobrecalentamiento, Transistor, Crystallization, Graphoepitaxy, Nanoimprint, Transient heating
Document Type:
Conference Conference Paper
File Description:
text
Language:
English
Author Affiliations:
Stanford University, Stanford, CA 94305, United States
Nanostructures Laboratory, Princeton University, Princeton, NJ 08544, United States
Quantum Science Research, Hewlett-Packard Laboratories, Palo Alto, CA 94304, United States
ISSN:
0167-9317
Access URL:
http://pascal-francis.inist.fr/vibad/index.php?action=search&terms=18807336
Rights:
Copyright 2007 INIST-CNRS
CC BY 4.0
Sauf mention contraire ci-dessus, le contenu de cette notice bibliographique peut être utilisé dans le cadre d’une licence CC BY 4.0 Inist-CNRS / Unless otherwise stated above, the content of this bibliographic record may be used under a CC BY 4.0 licence by Inist-CNRS / A menos que se haya señalado antes, el contenido de este registro bibliográfico puede ser utilizado al amparo de una licencia CC BY 4.0 Inist-CNRS
Notes:
Electronics
Accession Number:
edscal.18807336
Database:
PASCAL Archive

Further Information

The advantages of integrating semiconductor devices at more than one level ('3D integration') are now recognized. Key to achieving monolithic 3DICs is the ability to form single crystal semiconductor islands at the upper level without unduly heating the lower level structures. In prior work a surface relief grating of 3.8 μm pitch in the substrate was used to mediate single crystal formation while continuous wave (CW) heating a thin film of amorphous silicon; the term 'graphoepitaxy' was coined. CW heating is not possible in our case because it would overheat the lower layers. Moreover the area of the crystallites need only be about 100 nm to accommodate today's transistors. Thus we have chosen a substrate grating pitch of 190 nm (hence the term 'nano-graphoepitaxy') and a modulated CW laser to reduce the heating time to several μs. Preliminary results indicate the substrate grating lines can indeed determine the position of the crystallite boundaries when the film thickness is 100 nm; the effect is much less pronounced in 500 nm thick films.