D. J. Witte scite author profile

Graphoepitaxy is a technique that has been demonstrated as a means for fashioning regions of single crystal semiconductors on amorphous substrates. In that earlier work the heating period was long ͑1 s or more͒ and the substrate needed to be held close to the melting point of the semiconductor. With a view to achieving three-dimensional integrated circuits, the authors have investigated the possibility using graphoepitaxy to yield device quality single crystal islands of silicon on an amorphous substrate without excessive heating of the underlying layers by using transient ͑Ͻ1 ms͒ heating. A stationary laser pulse of 532 nm wavelength, 100 s duration, and 22 m diameter impinged on a 50 nm thick amorphous silicon film deposited on 12 nm thick SiO 2 inverted pyramid template. We demonstrated successful graphoepitaxial orientation of crystallized silicon but only under conditions that gave excessive heating ͑Ͼ400°C͒ of lower layers, thus indicating that this technique is impractical for three-dimensional integrated circuits.

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D. J. Witte

Low Thermal Budget Processing for Sequential 3-D IC Fabrication

Engineering of strained III–V heterostructures for high hole mobility

Lamellar crystallization of silicon for 3-dimensional integration

Nano-graphoepitaxy of semiconductors for 3D integration

Pulsed laser techniques for nanographoepitaxy

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D. J. Witte

Low Thermal Budget Processing for Sequential 3-D IC Fabrication

Engineering of strained III&#x2013;V heterostructures for high hole mobility

Lamellar crystallization of silicon for 3-dimensional integration

Nano-graphoepitaxy of semiconductors for 3D integration

Pulsed laser techniques for nanographoepitaxy

Contact Info

Product

Resources

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Engineering of strained III–V heterostructures for high hole mobility