Brian D. Kernan scite author profile

In the Floating Silicon Method (FSM), a single-crystal Si ribbon is grown while floating on the surface of a Si melt. In this paper, we describe the phenomenology of FSM and the observation of approximately regularly spaced "facet lines" on the ribbon surface whose orientation aligns with (111) crystal planes.Sb demarcation experiments sectioned through the thickness of the ribbon reveal that the solid/melt interface consists of dual (111) planes and that the leading edge facet growth is saccadic in nature, rather than steady-state.To explain this behavior, we propose a heuristic solidification limit cycle theory, using a continuum level of description with anisotropic kinetics as developed by others, and generalizing the interface kinetics to include a roughening transition as well as a re-faceting mechanism that involves curvature and the Gibbs-Thomson effect.

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Three-dimensional printing of tungsten carbide–10wt% cobalt using a cobalt oxide precursor

Kernan

Sachs

Oliveira

et al. 2007

International Journal of Refractory Metals and Hard Materials

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Alumina-doped silica gradient-index (GRIN) lenses by slurry-based three-dimensional printing (S-3DP™)

Wang

Cima

Kernan

et al. 2004

Journal of Non-Crystalline Solids

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Densification of a powder-metal skeleton by transient liquid-phase infiltration

Lorenz

Sachs

Kernan

et al. 2004

Metall Mater Trans A

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Transient liquid-phase infiltration (TLI) is a new method for densifying a powder-metal skeleton that produces a final part of homogeneous composition without significant dimensional change, offering advantages over traditional infiltration and full-density sintering. Fabrication of direct metal parts with complex geometry is possible using TLI in conjunction with solid freeform fabrication (SFF) processes such as three-dimensional printing, which produce net-shape powder-metal skeletons directly from computer-aided design models. The TLI method uses an infiltrant material similar in composition to the skeleton, but also containing a melting-point depressant (MPD), which allows the liquid metal to fill the skeleton void space and later facilitates homogenization. The materials requirements for such a system are discussed, and four experimental material systems were developed with final compositions of approximately Ni-40 wt pct Cu, Ni-4 wt pct Si, Fe-3 wt pct Si, and Fe-12 wt pct Cr-1 wt pct C, with copper, silicon, and carbon serving as the MPDs. Infiltration techniques include gating the introduction of liquid, saturating the melt to prevent erosion, and controlling variations in bulk composition along the infiltration path. Infiltration lengths exceeded 200 mm in the two nickel systems and exceeded 100 mm in the two iron systems. After infiltration, various heat treatments were conducted and mechanical properties were tested, including the tensile, hardness, and impact strength.

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Brian D. Kernan

Traditional and additive manufacturing of a new Tungsten heavy alloy alternative

Floating Silicon Method single crystal ribbon – observations and proposed limit cycle theory

Three-dimensional printing of tungsten carbide–10wt% cobalt using a cobalt oxide precursor

Alumina-doped silica gradient-index (GRIN) lenses by slurry-based three-dimensional printing (S-3DP™)

Densification of a powder-metal skeleton by transient liquid-phase infiltration

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