Andreas M. Glaeser
University of California, Berkeley
65 Papers
847 Citations
Andreas M. Glaeser is an academic researcher from University of California, Berkeley. The author has contributed to research in topics: Ceramic & Microstructure. The author has an hindex of 22, co-authored 65 publications. Previous affiliations of Andreas M. Glaeser include Center for Advanced Materials & University of California.
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Papers
Grain Boundary Migration in Ceramics
J.D. Powers,Andreas M. Glaeser +1 more
TL;DR: In this paper, the authors examined grain boundary migration in ceramics and discussed the effects of solutes, pores, and liquid phases on grain boundary migrations, and their role in the development of anisotropic (anisometric) microstructures.
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Ceramic joining: Part I Partial transient liquid-phase bonding of alumina via Cu/Pt interlayers
TL;DR: In this paper, a method of ceramic-ceramic joining that exploits a thin layer of a transient liquid phase to join alumina to alumina has been developed, and the results of its application to joining alumina are reported.
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New approaches to joining ceramics for high-temperature applications
TL;DR: In this paper, a thin transient liquid phase (TLP) layer is employed to join oxide and non-oxide ceramics by a brazing-like process, which allows the formation of ceramic-ceramic joints with high melting point metals at temperatures that are typically several hundred degrees lower than those required for more conventional joining methods.
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•Book
Ceramic microstructures : control at the atomic level
Antoni P. Tomsia,Andreas M. Glaeser +1 more
- 01 Jan 1998
TL;DR: In this paper, the impact of interface nonstoichiometry on Gas/Solid Kinetics was discussed. But the authors focused on the structure and composition of interfaces in ceramics and composites.
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Ceramic joining III bonding of alumina via Cu/Nb/Cu interlayers
TL;DR: In this paper, a multilayer interlayer designed to form a thin, potentially transient layer of liquid phase has been used to join alumina to alumina, achieving bonding at 1150 degrees C. Flexure strengths of as-bonded samples ranged from 119 to 255 MPa, with an average of ≈ 181 MPa.
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