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Book Chapter

Solidification Research in Microgravity

By Martin E. Glicksman
Book: Casting
Series: ASM Handbook
Volume: 15
Publisher: ASM International
Published: 01 December 2008
DOI: 10.31399/asm.hb.v15.a0005228
EISBN: 978-1-62708-187-0
..., as discussed in this article, proves to be a far more daunting and expensive technological challenge. Availability of Reduced Gravity: Past, Present, and Future Short-duration free-fall research facilities, known as drop towers and drop tubes, are available worldwide in heights between a few meters...
Abstract
Gravity has profound influences on most solidification and crystal growth processes. Modification of gravity over practical time scales for the purposes of modifying or controlling solidification proves to be a far more daunting and expensive technological challenge. This article discusses various microgravity solidification experiments that involve pure metals, alloys, and semiconductors and presents the official NASA acronyms for them. MEPHISTO, TEMPUS, the isothermal dendritic growth experiment, and advanced gradient heating facility, are also discussed.
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Schematic of Naval <span class="search-highlight">Research</span> Laboratory implantation facility for surface al...

Schematic of Naval Research Laboratory implantation facility for surface al...

in Ion Implantation > Surface Engineering
Published: 01 January 1994
Fig. 4 Schematic of Naval Research Laboratory implantation facility for surface alloying. Mass analyzed 52 Cr + beam being transported for the implantation of bearing components to improve their corrosion resistance. The footprint of this machine is about 2.5 × 4 m. Source: Ref 9 More
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Naval <span class="search-highlight">Research</span> Laboratories-type riser size curve for manganese bronze (all...

Naval Research Laboratories-type riser size curve for manganese bronze (all...

in Casting of Copper and Copper Alloys > Casting
Published: 01 December 2008
Fig. 36 Naval Research Laboratories-type riser size curve for manganese bronze (alloy C86500). Source: Ref 33 More
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Naval <span class="search-highlight">Research</span> Laboratories-type riser curve for manganese bronze (alloy C8...

Naval Research Laboratories-type riser curve for manganese bronze (alloy C8...

in Casting of Copper and Copper Alloys > Casting
Published: 01 December 2008
Fig. 37 Naval Research Laboratories-type riser curve for manganese bronze (alloy C86500) using different types of exothermic hot topping and top risers. Source: Ref 34 More
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Naval <span class="search-highlight">Research</span> Laboratories-type riser curve for aluminum bronze (alloy C95...

Naval Research Laboratories-type riser curve for aluminum bronze (alloy C95...

in Casting of Copper and Copper Alloys > Casting
Published: 01 December 2008
Fig. 38 Naval Research Laboratories-type riser curve for aluminum bronze (alloy C95300) using different types of exothermic hot topping and top risers. Source: Ref 34 More
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Naval <span class="search-highlight">Research</span> Laboratories-type riser curve for Cu-30Ni (alloy C96400) usi...

Naval Research Laboratories-type riser curve for Cu-30Ni (alloy C96400) usi...

in Casting of Copper and Copper Alloys > Casting
Published: 01 December 2008
Fig. 39 Naval Research Laboratories-type riser curve for Cu-30Ni (alloy C96400) using exothermic sleeves and hot topping versus hot topping alone. Source: Ref 34 More
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Mid-chamber ceramic barrier. Courtesy of LAM <span class="search-highlight">Research</span> Corporation

Mid-chamber ceramic barrier. Courtesy of LAM Research Corporation

in Corrosion in Semiconductor Wafer Fabrication > Corrosion: Environments and Industries
Published: 01 January 2006
Fig. 9 Mid-chamber ceramic barrier. Courtesy of LAM Research Corporation More
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Microwave heating system. (a) Components. (b) Naval <span class="search-highlight">Research</span> Laboratory 6 k...

Microwave heating system. (a) Components. (b) Naval Research Laboratory 6 k...

in Pressing and Sintering of Titanium Powders > Powder Metallurgy
Published: 30 September 2015
Fig. 13 Microwave heating system. (a) Components. (b) Naval Research Laboratory 6 kW, 2.45 GHz microwave system for titanium sintering experiments. More
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Upright (a) and inverted (b) <span class="search-highlight">research</span>-quality bench microscopes. Courtesy o...

Upright (a) and inverted (b) research-quality bench microscopes. Courtesy o...

in Light Microscopy > Metallography and Microstructures
Published: 01 December 2004
Fig. 3 Upright (a) and inverted (b) research-quality bench microscopes. Courtesy of Carl Zeiss, Inc. and Leica, Inc. More
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United States Council for Automotive <span class="search-highlight">Research</span> demonstration structure built...

United States Council for Automotive Research demonstration structure built...

in Heat Treating of Magnesium Alloy Metal-Matrix Composites > Heat Treating of Nonferrous Alloys
Published: 01 June 2016
Fig. 2 United States Council for Automotive Research demonstration structure built using (a) friction stir linear welding and (b) laser-assisted self-pierce rivet joining processes. Source: Ref 7 More
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Bending fatigue test results from the Gear <span class="search-highlight">Research</span> Institute study for dif...

Bending fatigue test results from the Gear Research Institute study for dif...

in Induction Hardening of Gears and Gear-Like Components > Induction Heating and Heat Treatment
Published: 09 June 2014
Fig. 40 Bending fatigue test results from the Gear Research Institute study for different gear-hardening methods. Source: Ref 24 More
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Complex ballast tank piping. Courtesy of Naval <span class="search-highlight">Research</span> Laboratory

Complex ballast tank piping. Courtesy of Naval Research Laboratory

in Marine Coatings > Protective Organic Coatings
Published: 30 September 2015
Fig. 3 Complex ballast tank piping. Courtesy of Naval Research Laboratory More
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Schematics of (a) <span class="search-highlight">research</span>-type ion implantation system and (b) a productio...

Schematics of (a) research-type ion implantation system and (b) a productio...

in Surface Modification Using Energy Beams > Corrosion: Fundamentals, Testing, and Protection
Published: 01 January 2003
Fig. 1 Schematics of (a) research-type ion implantation system and (b) a production-type semiconductor implanter More
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Torque-tension <span class="search-highlight">research</span> head, 800 kN capacity

Torque-tension research head, 800 kN capacity

in Mechanical Testing of Threaded Fasteners and Bolted Joints > Mechanical Testing and Evaluation
Published: 01 January 2000
Fig. 4 Torque-tension research head, 800 kN capacity More
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Cutaway of typical test setup using torque-tension <span class="search-highlight">research</span> head. T A , t...

Cutaway of typical test setup using torque-tension research head. T A , t...

in Mechanical Testing of Threaded Fasteners and Bolted Joints > Mechanical Testing and Evaluation
Published: 01 January 2000
Fig. 17 Cutaway of typical test setup using torque-tension research head. T A , tightening torque for generating load F V ; T G , component of tightening torque acting in threads; T K , frictional torque acting at bearing face of bolt head or nut; P , thread pitch More
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Welding <span class="search-highlight">Research</span> Council (WRC-1988) diagram used to predict weld metal ferr...

Welding Research Council (WRC-1988) diagram used to predict weld metal ferr...

in Corrosion of Weldments > Welding, Brazing, and Soldering
Published: 01 January 1993
Fig. 8 Welding Research Council (WRC-1988) diagram used to predict weld metal ferrite content. Source: Ref 18 More
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Two sizes of the standard specimen for the Naval <span class="search-highlight">Research</span> Laboratory standa...

Two sizes of the standard specimen for the Naval Research Laboratory standa...

in Mechanical Testing > Metals Handbook Desk Edition
Published: 01 December 1998
Fig. 28 Two sizes of the standard specimen for the Naval Research Laboratory standardized dynamic tear test. In the specimens, a crack with a sharp tip is produced by making a brittle electron beam weld or by pressing with a knife edge. With either method of providing the crack tip More
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Optical image of a <span class="search-highlight">research</span>-grade LIFT experimental system

Optical image of a research-grade LIFT experimental system

in Laser-Induced Forward Transfer Processes in Additive Manufacturing > Additive Manufacturing Processes
Published: 15 June 2020
Fig. 3 Optical image of a research-grade LIFT experimental system More
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Positioning part consolidation <span class="search-highlight">research</span> in the scope of design for additive...

Positioning part consolidation research in the scope of design for additive...

in Part Consolidation and Assemblies > Additive Manufacturing Design and Applications
Published: 30 June 2023
Fig. 3 Positioning part consolidation research in the scope of design for additive (DFAM) manufacturing and general product development More
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Future of 3D bioprinting in terms of application, <span class="search-highlight">research</span> and development,...

Future of 3D bioprinting in terms of application, research and development,...

in Micro/Nanoscale Plotting of Biomaterials > Additive Manufacturing in Biomedical Applications
Published: 12 September 2022
Fig. 17 Future of 3D bioprinting in terms of application, research and development, and commercialization. OOC, organ-on-a-chip More