<P>Materials and methods to achieve electronics intimately integrated on the surfaces of substrates with complex, curvilinear shapes are described. The approach exploits silicon membranes in circuit mesh structures that can be deformed in contro...
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https://www.riss.kr/link?id=A107624987
2009
-
SCOPUS,SCIE
학술저널
2703-2709(7쪽)
0
상세조회0
다운로드다국어 초록 (Multilingual Abstract)
<P>Materials and methods to achieve electronics intimately integrated on the surfaces of substrates with complex, curvilinear shapes are described. The approach exploits silicon membranes in circuit mesh structures that can be deformed in contro...
<P>Materials and methods to achieve electronics intimately integrated on the surfaces of substrates with complex, curvilinear shapes are described. The approach exploits silicon membranes in circuit mesh structures that can be deformed in controlled ways using thin, elastomeric films. Experimental and theoretical studies of the micromechanics of such curvilinear electronics demonstrate the underlying concepts. Electrical measurements illustrate the high yields that can be obtained. The results represent significant experimental and theoretical advances over recently reported concepts for creating hemispherical photodetectors in electronic eye cameras and for using printable silicon nanoribbons/membranes in flexible electronics. The results might provide practical routes to the integration of high performance electronics with biological tissues and other systems of interest for new applications.</P>
<B>Graphic Abstract</B>
<P>Strategies for conformal wrapping of single crystalline silicon electronics onto the surfaces of curvilinear substrates are presented (see image). The approach uses silicon membranes in non-coplanar mesh layouts with thin, elastomeric transfer elements to accomplish a planar to curvilinear geometry transformation. Detailed experimental studies, together with analytical and finite element modeling of the micromechanics, reveal all of the key aspects of the process.
<img src='wiley_img/16136810-2009-5-23-SMLL200900934-content.gif' alt='wiley_img/16136810-2009-5-23-SMLL200900934-content'>
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Restriction-Enzyme-Coded Gold-Nanoparticle Probes for Multiplexed DNA Detection