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Computer simulation of interdiffusion microstructures in multi-component and multiphase systemsWu, Kaisheng. January 2004 (has links)
Thesis (Ph. D.)--Ohio State University, 2004. / Title from first page of PDF file. Document formatted into pages; contains xvii, 155 p. : ill. (some col.). Advisor: Yunzhi Wang, Department of Materials Science and Engineering. Includes bibliographical references (p. 151-155).
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Alloying effects on high temperature deformation behavior of nickel aluminide intermetallicsCoulter, Robert A., January 2000 (has links)
Thesis (M.S.)--West Virginia University, 2000. / Title from document title page. Document formatted into pages; contains xi, 94 p. : ill. (some col.). Vita. Includes abstract. Includes bibliographical references (p. 88-89).
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Creep behavior in stoichiometric NiAlKanne, William Rudolph, January 1968 (has links)
Thesis (Ph. D.)--University of Wisconsin--Madison, 1968. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.
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Modeling of thermal and mechanical effects during friction stir processing of nickel-aluminum bronzeJamison, Jay Dee 09 1900 (has links)
Approved for Public Release; Distribution is Unlimited / Friction Stir Processing (FSP), although relatively simple in concept, results in an extremely complex thermomechanical treatment to the material being processed. Previous studies of FSP have shown that the process results in extremely high strain, strain rates and temperatures as well as gradients in strain, strain rate and temperature within a small volume of material. This thesis will study the effect of varying FSP parameters during the processing of Nickel-Aluminum-Bronze (NAB) propeller material. The modeling program CTH was used to define the relationship between tool rotation speed, traversing speed and the total power input to the material. The tool's mechanical power and the power generated by deformation of the material has been investigated. The modeling experiments were designed to gain an understanding of the relationship of process parameters, microstructure and mechanical properties, and to enhance our understanding of the flow patterns and thermal histories of the NAB material in the stir zone. / Lieutenant, United States Navy
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Effects of platinum, iridium, and hafnium to nickel-aluminium alloys under cyclic oxidation conditions.Kartono, Rahmat, Materials Science & Engineering, Faculty of Science, UNSW January 2007 (has links)
A thermally grown oxide (TGO) such as the alumina scale formed on a bondcoat enhances the oxidation and corrosion resistance of thermal barrier coating (TBC)- bondcoat-superalloy substrate systems. As the external alumina scale lies between the thermal barrier coating and bondcoat, its first spallation and subsequent TBC delamination become critical. Once the external alumina scale spalls, it will spall together with the TBC, leaving the system with no temperature barrier protection. Operational factors such as thermal cycling conditions, water vapour in the oxidation atmosphere, and alloying elements comprising the bondcoat system affect alumina scale adherence. Another problem that arises for the majority of bondcoat systems, β (Ni,Pt)Al and MCrAlY (M=Metal), are rich in aluminium. This causes aluminium to diffuse into the substrate, enriching it with aluminium during service, transforming phases in the substrate alloying system. The purpose of this study was to develop bondcoat materials that promote formation of a strongly adherent TGO, but have an aluminium content near the substrate composition. Cyclic oxidation experiments were performed with Ni-Al, Ni-Pt-Al, and Ni-Pt-Al-Ir alloys in dry air and air-12%H2O. Thermal cycles of 1 hr at 1200OC and 10 minutes at 80OC were carried out in flowing gases at a total pressure of 1 atm. Experiments in N2- 12%H2O were performed only on Ni-Al binary alloys. Binary Ni-Al cast alloys were tested for fundamental study purposes, while Ni-Pt-Al and Ni-Pt-Al-Ir cast alloys were intended to be models for aluminide coatings, with attention focused on γ+γ' -Ni-(20 to 23)Al. Comparisons were made with β-Ni-50Al, as it forms an external alumina scale and was found to have the smallest weight loss rate during testing of binary alloys. Assessments of Pt and Pt-Ir additions, with and without hafnium, to the γ+γ' binary alloy were made. Compared to binary alloys, platinum was found to reduce the total weight loss caused by scale spallation. Experiments in air-12%H2O led to more rapid weight loss than in dry air. This was due to enhanced spallation. However, the degradation rate was slower than in platinum-free alloys exposed to the same atmosphere. Partial replacement of platinum with iridium was found to improve alloy scale adherence during exposure in both dry and wet air. Addition of 1wt% hafnium was found to reduce oxide thickness and increase the oxide adherence simultaneously. The hafnium addition was essential in order to reduce spallation rate in wet air. Water vapour in the presence of oxygen generally increased the spallation rate. It weakened the oxide metal interface, causing subsequent spallation to be increased, but only if the gas had access to the alloy-scale interface. Water vapour did not affect the spallation rate of the strongly adherent oxide grown on Ni-22Al-30Pt+1wt%Hf and Ni- 20Al-15Pt-10Ir+1wt%Hf.
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Development of nickel aluminide (NiAl) microchannel array devices for high-temperature applicationsKanlayasiri, Kannachai 21 March 2003 (has links)
The miniaturization of Microtechnology-based Energy, Chemical and
Biological Systems (MECS) is made possible by the use of high aspect ratio
microchannel arrays to increase the surface-area-to-volume ratio of the flow
conduits within the devices, resulting in an improvement in the heat and mass
transfer performance of the devices. However, advantages of the MECS concept
cannot be applied to high-temperature applications (above 650��C) due to lack of
high-temperature MECS devices; therefore, the development of high-temperature
MECS devices is necessary to overcome this bottleneck. This dissertation involves
the development of high-temperature MECS devices from a high-temperature
material, nickel aluminide (NiAl). NiAl foil was synthesized from elemental nickel
(Ni) and aluminum (Al) foils through a two step process--tack bonding and
reactive diffusion. The elemental foils were tack bonded at 500��C, 3.9 MPa for
15 minutes. The reactive diffusion process was then performed through a heat
treatment at 1000��C for a period of time corresponding to the thickness of the
composite foil. The synthesized NiAl foil showed an atomic ratio of Al to Ni up to
0.96. The foil also showed a decent flatness and surface roughness. This
dissertation proposes a reactive diffusion bonding as a joining technique of nickel
aluminides. An investigation of bonding parameter effects on the warpage of
nickel aluminide fins in the reactive diffusion bonding process was performed.
Results showed that bonding time and temperature had significant effects on
warpage of the fin. The fin warpage increased with the increase of bonding time
and bonding temperature. Results also suggested that the bonding pressure had an
effect on the fin warpage. However, chemical compositions of the fin were not
significant to the warpage. This research also proposes a new fabrication procedure
for producing NiAl MECS devices. NiAl foils were used as the starting material,
and the reactive diffusion bonding technique was employed as the joining
technique. The research outcome indicated the viability of the proposed method in
fabricating NiAl MECS devices. This method achieved leak-tight devices with a
reasonable fin flatness. / Graduation date: 2003
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Microstructure characterization of friction-stir processed nickel-aluminum bronze through orientation imaging microscopy /Cuevas, Assunta Mariela. January 2002 (has links)
Thesis (M.S. in Mechanical Engineering)--Naval Postgraduate School, September 2002. / Thesis advisor(s): Terry R. McNelley. Includes bibliographical references (p. 53-55). Also available online.
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Synthesis and microstructure of NixAl1-x (0.5 x 1) thin filmsAnand, Thangaraj Joseph Sahaya. January 2004 (has links)
published_or_final_version / abstract / toc / Mechanical Engineering / Doctoral / Doctor of Philosophy
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Effects of platinum, iridium, and hafnium to nickel-aluminium alloys under cyclic oxidation conditions.Kartono, Rahmat, Materials Science & Engineering, Faculty of Science, UNSW January 2007 (has links)
A thermally grown oxide (TGO) such as the alumina scale formed on a bondcoat enhances the oxidation and corrosion resistance of thermal barrier coating (TBC)- bondcoat-superalloy substrate systems. As the external alumina scale lies between the thermal barrier coating and bondcoat, its first spallation and subsequent TBC delamination become critical. Once the external alumina scale spalls, it will spall together with the TBC, leaving the system with no temperature barrier protection. Operational factors such as thermal cycling conditions, water vapour in the oxidation atmosphere, and alloying elements comprising the bondcoat system affect alumina scale adherence. Another problem that arises for the majority of bondcoat systems, β (Ni,Pt)Al and MCrAlY (M=Metal), are rich in aluminium. This causes aluminium to diffuse into the substrate, enriching it with aluminium during service, transforming phases in the substrate alloying system. The purpose of this study was to develop bondcoat materials that promote formation of a strongly adherent TGO, but have an aluminium content near the substrate composition. Cyclic oxidation experiments were performed with Ni-Al, Ni-Pt-Al, and Ni-Pt-Al-Ir alloys in dry air and air-12%H2O. Thermal cycles of 1 hr at 1200OC and 10 minutes at 80OC were carried out in flowing gases at a total pressure of 1 atm. Experiments in N2- 12%H2O were performed only on Ni-Al binary alloys. Binary Ni-Al cast alloys were tested for fundamental study purposes, while Ni-Pt-Al and Ni-Pt-Al-Ir cast alloys were intended to be models for aluminide coatings, with attention focused on γ+γ' -Ni-(20 to 23)Al. Comparisons were made with β-Ni-50Al, as it forms an external alumina scale and was found to have the smallest weight loss rate during testing of binary alloys. Assessments of Pt and Pt-Ir additions, with and without hafnium, to the γ+γ' binary alloy were made. Compared to binary alloys, platinum was found to reduce the total weight loss caused by scale spallation. Experiments in air-12%H2O led to more rapid weight loss than in dry air. This was due to enhanced spallation. However, the degradation rate was slower than in platinum-free alloys exposed to the same atmosphere. Partial replacement of platinum with iridium was found to improve alloy scale adherence during exposure in both dry and wet air. Addition of 1wt% hafnium was found to reduce oxide thickness and increase the oxide adherence simultaneously. The hafnium addition was essential in order to reduce spallation rate in wet air. Water vapour in the presence of oxygen generally increased the spallation rate. It weakened the oxide metal interface, causing subsequent spallation to be increased, but only if the gas had access to the alloy-scale interface. Water vapour did not affect the spallation rate of the strongly adherent oxide grown on Ni-22Al-30Pt+1wt%Hf and Ni- 20Al-15Pt-10Ir+1wt%Hf.
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Planar fault energies and dislocation core spreadings in B2 NiAl /Vailhe, Christophe N. P., January 1992 (has links)
Thesis (M.S.)--Virginia Polytechnic Institute and State University, 1992. / Vita. Abstract. Includes bibliographical references (leaves 107-111). Also available via the Internet.
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