Causes and Prevention of Temperature-Dependent Bubbles in Silicon Wafer Bonding

It is generally known that Volker Lehmann has made numerous important contributions to the science and technology of the various forms of porous silicon. Less well known is that he started his education in the world of art and that he kept this interest alive, even after a professional career in engineering, materials science, physics and electrochemistry. In addition he was an athlete, enjoying all kinds of sports and physical challenges. The paper will be based upon the personal experience of the authors who worked directly with Volker Lehmann or in related fields of research for over two decades.

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“…He wrote a number of well-cited papers in this area (6,7). However, his scientific heart was still pounding for the electrochemistry of silicon.…”

Section: Postdoc Time At Duke Universitymentioning

confidence: 99%

Volker Lehmann: An Unconventional Scientist

Gösele

Föll

2008

ECS Trans.

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“…Direct silicon bonding refers to the adhesion mechanism of two mirror-polished, flat and clean silicon surfaces, brought into contact at room temperature, due to short range intermolecular forces, as the van der Walls forces [16][17] ; to strengthen the bond across the interface the bonded wafers have to undergo a heating step at high temperature 18 .…”

Section: Bonding Of the Silicon Grating Onto The Silicon Prismmentioning

confidence: 99%

<title>Silicon grisms fabricated by anisotropic wet etching and direct silicon bonding for high-resolution IR spectroscopy</title>

Cianci¹,

Foglietti²,

Vitali

et al. 2001

SPIE Proceedings

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Silicon grisms are very attractive as devices for IR spectroscopy in terms of high resolving power and compactness, necessary for many astronomical applications and for implementation of spectroscopic modes in large telescopes respectively. We present the fabrication process of a silicon grism as composed by an IR transmission grating coupled to a silicon prism. The silicon gratings were manufactured using silicon micromachining techniques, as electron beam lithography and wet anisotropic etching, achieving good uniformity over all the large surface (32x32 mm 2 ) and grating facets of excellent optical quality; the final grism was realized by means of direct bonding of the grating onto the prism face. The results of laboratory tests on the first prototype are presented.

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“…However, if the bonded materials have different expansion coefficients, thermal strain will develop in the course of annealing and cooling. Furthermore, a big internal strain will severely affect the bonding quality and induce a high density of dislocations [12][13][14], even result in the failure to bond [15]. Therefore, it is important to study the strain of bonded wafers and the distribution of stresses, and to put forward an effective method to reduce these stresses.…”

Section: Introductionmentioning

confidence: 99%