The Au−Cd (Gold-Cadmium) system

• 1889Tam: G. Tammann, “The Constitution of Alloys,”Z. Phys. Chem., 3, 441–449 (1989) in German. (Equi Diagram; Experimental)

  Google Scholar 

• 1892Hey: C. T. Heycock and F. H. Neville, “On the Lowering of the Freezing Points of Cadmium, Bismuth, and Lead When Alloyed with Other Metals,”J. Chem. Soc., 61, 888–914 (1892). (Equi Diagram; Experimental)

  Google Scholar 

• Indicates key paper.06Vog: R. Vogel, “Gold-Cadmium Alloys,”Z. Anorg. Chem., 48, 333–346 (1906) in German. (Equi Diagram; Experimental; Indicates presence of a phase diagram.)

  Article  Google Scholar 

• Indicates key paper.15Sal: P. Saldau, “Gold-Cadmium Alloys,”Int. Z. Metallogr., 7, 3–34 (1915),Zh. Fiz.-Khim. Obshch. 49 449–548 (1917–1918);55, 275–286 (1924);J. Inst. Met., 41, 175–176 (1929). (Equi Diagram, Crys Structure; Experimental; Indicates presence of a phase diagram.)

  Google Scholar 

• 25Wes: A. Westgren and G. Pharagmen, “X-Ray Analysis of Copper-Zinc, and Gold-Zinc Alloys,”Philos. Mag., 50, 339 footnote (1925). (Crys Structure; Experimental)

  Google Scholar 

• 28Wes: A. Westgren and G. Pharagmen,Metallwirtschaft, 7, 702 (1928); quoted in [Hansen]. (Crys Structure; Experimental)

  Google Scholar 

• Indicates key paper 29Dur: P.J. Durrant, “The Constitution of the Cadmium-Rich Alloys of the System Cadmium-Gold,”J. Inst. Met., 41, 139–171 (1929). (Equi Diagram; Experimental; Indicates presence of a phase diagram)

  Google Scholar 

• 32Ola1: A. Olander, “An Electrochemical Investigation of Solid Cadmium-Gold Alloys,”J. Am. Chem. Soc., 54(10), 3819–3833 (1932). (Equi Diagram, Thermo; Experimental)

  Article  Google Scholar 

• 32Ola2: A. Olander, “The Crystal Structure of AuCd,”Z. Kristallogr., 83, 145–148 (1932). (Crys Structure; Experimental)

  Google Scholar 

• 40Kos: W. Koster and A. Schneider, “Elastic Modulus and Damping of Intermetallic Phases in the Gold-Cadmium System,”Z. Metallkd., 32(6), 156–159 (1940) in German. (Equi Diagram, Crys Structure; Experimental)

  Google Scholar 

• Indicates key paper 40Owe: E.A. Owen and E.A.O. Roberts, “Gold-Cadmium Alloys, Rich in Gold,”J. Inst. Met., 66, 389–400 (1940). (Equi Diagram, Crys Structure; Experimental; Indicates presence of a phase diagram)

  Google Scholar 

• 41Owe: E.A. Owen and W.H. Rees, “The Beta Region of the Gold-Cadmium Alloy System,”J. Inst. Met., 67, 141–151 (1941). (Equi Diagram, Crys Structure; Experimental; Indicates presence of a phase diagram)

  Google Scholar 

• 42Edw: O.S. Edwards and H. Lipson, “Imperfections in the Structure of Cobalt. I. Experimental Work and Proposed Structure,”Proc. R. Soc., A180, 268–277 (1942). (Crys Structure; Experimental)

  Article  ADS  Google Scholar 

• 42Sch: A. Schneider and H. Schmid, “Metal Vapor Pressures. III. The Vapor Pressures of Au and Cd over Their Binary Alloys with Cu, Ag and Au,”Z. Elektrochem., 48, 627–639 (1942) in German. (Thermo; Experimental)

  Google Scholar 

• 43Kub: O. Kubaschewski, “Thermochemistry of Alloys. XI. Heats and Entropies of Fusion and Degree of Order of Au and Ag Alloys,”Z. Phys. Chem. (Leipzig), 192, 292–308 (1943) in German. (Equi Diagram, Crys Structure, Thermo; Experimental)

  Google Scholar 

• 47Bys: A. Bystrom and K.E. Almin, “X-Ray Investigation of Gold-Cadmium Alloys Rich in Gold,”Acta Chem. Scand., 1, 76–89 (1947). (Equi Diagram, Crys Structure; Experimental; Indicates presence of a phase diagram)

  Article  Google Scholar 

• 51Cha1: L.C. Chang, “Atomic Displacements and Crystallographic Mechanism in Diffusionless Transformation of Gold-Cadmium Single Crystal Containing 47.5 Atomic Percent Cadmium,”Acta Crystallogr., 4, 320–324 (1951). (Equi Diagram, Crys Structure; Experimental)

  Article  Google Scholar 

• 51Cha2: L.C. Chang and T.A. Read, “Plastic Deformation and Diffusionless Phase Changes in Metals—The Gold-Cadmium Beta Phase,”Trans. AIME, 191(1), 47–52 (1951), (Equi Diagram; Experimental)

  Google Scholar 

• 53Cha: L.C. Chang, T.A. Read, and M.S. Wechesler, “Reversible Single-Crystal Rocking-Curve Broadening,”Acta Crystallogr., 6, 567 (1953). (Crys Structure; Experimental)

  Article  Google Scholar 

• 54Che: C.W. Chen, “The Cubic to Tetragonal Diffusionless Phase Change in the Gold-Cadmium System,” Ph.D. Dissertation, Columbia Univ., NY (1954).Diss. Abstr., 14, 1193–1194 (1954);Chem. Abstr., 48(22), 13392a (1954). (Crys Structure; Experimental)

  Google Scholar 

• 54Mul: L. Muldawer, “On the Relation of the Disordering of a Superlattice to the Melting of the Disordered Alloy,”Acta Metall., 2(6), 555 (1954). (Equi Diagram; Theory)

  Google Scholar 

• 54Ori: R.A. Oriani, “The Relation of the Disordering of a Superlattice to the Melting of the Disordered Alloy,”Acta Metall., 2(3), 343–344 (1954). (Equi Diagram; Theory)

  Google Scholar 

• 55Lie: D.S. Lieberman, M.S. Wechsler, and T.A. Read, “Cubic to Orthorhombic Diffusionless Phase Change—Experimental and Theoretical Studies of AuCd,”J. Appl. Phys., 26(4), 473–484 (1955). (Equi Diagram; Theory)

  Article  ADS  Google Scholar 

• 55Sch: K. Schubert, B. Kiefer, M. Wilkens, and R. Haufler, “On Some Metallic Ordered Phases with Long Period,”Z. Metallkd., 46(9), 692–715 (1955) in German. (Crys Structure; Experimental)

  Google Scholar 

• 56Kle: O.J. Kleppa, “Heats of Formation of Some Solid and Liquid Alloys of Gold with Cadmium, Indium, Tin and Antimony,”J. Phys. Chem., 60(7), 858–863 (1956). (Equi Diagram, Thermo; Experimental)

  Article  Google Scholar 

• 56Wec: M.S. Wechsler and T.A. Read, “Effect of Quenching on the Resistivity of Au−Cd,”J. Appl. Phys., 27(2), 194–195 (1956). (Equi Diagram, Crys Structure; Experimental)

  Article  ADS  Google Scholar 

• 56Zir: S. Zirinsky, “The Temperature Dependence of the Elastic Constants of Gold-Cadmium Alloys,”Acta Metall., 4(3), 164–171 (1956). (Equi Diagram, Crys Structure; Experimental)

  Google Scholar 

• 57Mas: T.B. Massalski, “The Lattice Spacings of Close-Packed Hexagonal Au−In, Au−Cd, and Au−Hg Alloys,”Acta Metall., 5(10), 541–547 (1957). (Equi Diagram, Crys Structure; Experimental)

  Article  Google Scholar 

• 57Sch: K. Schubert, H. Breimer, W. Burkhardt, E. Gunzel, R. Haufler, H.L. Lukas, H. Vetter, J. Wegst, and M. Wilkens, “Some Structural Results of Metallic Phases II,”Naturwissenschaften, 44(7), 229–230 (1957), in German. (Crys Structure; Experimental)

  Article  ADS  Google Scholar 

• 57Stu: W.J. Sturm and M.S. Wechsler, “Density and Resistivity Changes in Au−Cd upon Quenching,”J. Appl. Phys., 28(12), 1509–1510 (1957). (Equi Diagram; Experimental)

  Article  ADS  Google Scholar 

• 57Wec: M.S. Wechsler, “The Quenching-In of Lattice Defects in Gold-Cadmium,”Acta Metall., 5(3), 150–158 (1957). (Equi Diagram; Experimental)

  Article  Google Scholar 

• 58Ahm: A.H.S.U. Ahmed, Thesis, Univ. Illinois (1958); quoted in [72Led2]. (Crys Structure; Experimental)

• 58Weg: J. Wegst and K. Schubert, “Constitution of Gold-Corner of Alloy System Gold-Cadmium-Indium,”Z. Metallkd., 49(10), 533–534 (1958) in German. (Crys Structure; Experimental)

  Google Scholar 

• 59Bir: H.K. Birnbaum, “Stabilization Phenomena in Beta-Phase Au−Cd Alloys,”Trans. AIME, 215 (10), 786–792 (1959). (Equi Diagram; Experimental; Indicates presence of a phase diagram)

  Google Scholar 

• 61Cla: W. Class and D.S. Lieberman, “Some Isothermal Effects in Gold-47.5 Atomic Percent Cadmium Alloys,”J. Aust. Inst. Met., 6(1), 11–16 (1961). (Equi Diagram; Experimental)

  Google Scholar 

• Indicates key paper 61Hir: H. Hirabayashi and S. Ogawa, “Crystal Structure and Phase Transitions of the Gold-Rich Gold-Cadmium Alloy,”Acta Metall., 9(4), 264–274 (1961). (Equi Diagram, Crys Structure; Experimental; Indicates presence of a phase diagram)

  Article  Google Scholar 

• 61Sub: B.S. Subramanya, G.S. Baker, D.S. Lieberman, and T.A. Read, “Quenching Effects and Isothermal Martensitic Transformation in Au−Cd,”J. Aust. Inst. Met., 6(1), 3–10 (1961). (Equi Diagram; Experimental)

  Google Scholar 

• 62Bre: J.F. Breedis, D.S. Lieberman, and T.A. Read, private communication to [72Led2]. (Crys Structure; Experimental)

• 62Hen: B. Henderson and G.V. Raynor, “Lattice Spacing Relationships in the Ternary System Gold+Tin+Cadmium,”Trans. Faraday Soc., 58, 900–903 (1962). (Crys Structure; Experimental)

  Article  Google Scholar 

• Indicates key paper 62Riv: V.G. Rivlin, W. Hume-Rothery, and B. Rader, “The Constitution and Structure of Gold-Cadmium Alloys,”Acta Metall., 10(12), 1143–1150 (1962); “Errata,”Acta Metall., 11(5), 488 (1963). (Equi Diagram, Crys Structure; Experimental; Indicates presence of a phase diagram)

  Article  Google Scholar 

• 63Bon: E. Bonnier and F. Durand, “Determination of the Activitity of Cadmium in the Liquid System Cd−Sn−Cu and Cd−Sn−Au,”C.R. Acad. Sci., Paris, 256, 1772–1775 (1963) in French. (Thermo; Experimental)

  Google Scholar 

• 63Nak: N. Nakanishi and C.M. Wayman, “An Electrical Resistance Study of Phase Transformations in Quenched and Annealed CsCl Au−Cd Alloys,”Trans. Jpn. Inst. Met., 4(3), 179–188 (1963). (Equi Diagram; Experimental)

  Google Scholar 

• Indicates key paper 64Fil: J.D. Filby and J.N. Pratt, “Thermodynamic Measurements on Gold+Cadmium Liquid and Solid Solutions,”Trans. Faraday Soc., 60, 1934–1940 (1964). (Equi Diagram, Thermo; Experimental; Indicates presence of a phase diagram)

  Article  Google Scholar 

• 65Bar: L.J. Bartha and W.A. Alexander, “The Thermodynamic Properties and Phase Diagram of the Gold-Cadmium System by the Isopiestic Method,”Can. J. Chem., 43(8), 2319–2327 (1965). (Equi Diagram, Thermo; Experimental; Indicates presence of a phase diagram)

  Article  Google Scholar 

• 65Iwa: H. Iwasaki, M. Hirabayashi, and S. Ogawa, “Lattice Modulation in the Ordered Alloys with Long Period Studied by X-Ray Diffraction. I. Au₃Cd,”J. Phys. Soc. Jpn., 20(1), 89–97 (1965). (Crys Structure; Experimental)

  Article  ADS  Google Scholar 

• 66Ahm: A.H.S.U. Ahmed, “Thermodynamics of the Diffusionless Phase Transformation in the Gold-Cadmium Alloys System,” Dissertation, Case Inst. Technol.;Diss. Abstr., B., 27(5), 1498 (1966). (Equi Diagram; Experimental)

  Google Scholar 

• 66Ell: G.R.B. Elliott, C.C. Herik, J.F. Lemons, and P.C. Nordine, U.S.A.E.C. Rep., LA-3526; quoted in [Hultgren, B]. (Thermo; Experimental)

• 66Oga: S. Ogawa and H. Iwasaki, “Study of Long-Period Ordered Alloys by X-Ray Diffraction,”Sci. Rep. Res. Inst., Tohoku Univ. A, Suppl. 18, 194–206 (1966). (Crys Structure; Experimental)

  Google Scholar 

• 67Hir: M. Hirabayashi, N. Ino, and K. Hiraga, “Long Period Stacking Order in Close Packed Structures of Au−Cd Alloys,”J. Phys. Soc. Jpn., 22(6), 1509 (1967). (Crys Structure; Experimental)

  Article  ADS  Google Scholar 

• 67Hou: B.L. Houseman, L. Barton, and G.R.B. Elliott, “Cadmium Activity in its Alloys with a Small Amount of Gold from the Electromotive Force of StirredH-cells,” U.S.A.E.C. Rep., LA-4031 (1967). (Thermo; Experimental)

• 67Pre1: B. Predel and W. Schwermann, “Energetics of Diffusion-Free Phase Transformation in the Gold-Cadmium System,”Naturwissenschaften, 54(18), 490 (1967) in German. (Equi Diagram; Thermo; Experimental)

  Article  ADS  Google Scholar 

• 67Pre2: B. Predel and W. Schwermann, “Thermodynamic Investigation of the Diffusion-Free Phase Transformation in the Gold-Cadmium System,”Z. Naturforsch., A, 22(10), 1499–1503 (1967) in German. (Thermo; Experimental)

  ADS  Google Scholar 

• 68Far: R.A. Farrar and H.W. King, “Axial Ratios and Solubility Limits of HCP η Phases in the Systems Cd−Au, Cd−Li, and Zn−Li,”Metallography, 1(1), 79–90 (1968). (Crys Structure; Experimental)

  Article  Google Scholar 

• 68Jen: L. Jenicek and A. Hrbek, “Mixing Entropy and Electrical Mixing Resistance in Binary Metal System,”Freiberger Forsch. Metall. (129), 69–82 (1968) in German. (Thermo; Experimental)

  Google Scholar 

• 68Ott: H.M. Otte, “Concerning the Transformation Mechanism in Au-47.5 Cd,”Scr. Metall., 2(7), 365–373 (1968). (Equi Diagram; Theory)

  Article  Google Scholar 

• 68Sha1: B. Sharan and O.P. Agnihotri, “Stacking Faults in Hexagonal Gold-Cadmium Alloys,”J. Appl. Phys., 39(3), 1489–1492 (1968). (Crys Structure; Experimental)

  Article  ADS  Google Scholar 

• 68Sha2: B. Sharan and O.P. Agnihotri, “Structural Imperfections in Hexagonal Gold-Cadmium Alloys,”Acta Crystallogr. A, 24(4), 437–439 (1968). (Crys Structure; Experimental)

  Article  ADS  Google Scholar 

• Indicates key paper 68Tot: R.S. Toth and H. Sato, “Structure of Martensites in β Gold-Cadmium Alloys,”Acta Metall., 16(3), 413–433 (1968). (Equi Diagram, Crys Structure; Experimental)

  Article  Google Scholar 

• 68Wal1: W. Wallace, W.D. Hoff, and W.V. Kitchingman, “The Structures and Phase Transformations in β AuCd Alloys,”Acta Crystallogr. A, 24(6), 680–683 (1968). (Crys Structure; Experimental)

  Article  ADS  Google Scholar 

• 68Wal2: W. Wallace and W.J. Kitchingman, “The Influence of Plastic Deformation on the Martensite Transformation in a 50 at. % Gold-Cadmium Alloy,”J. Inst. Met., 97(2), 56–59 (1968). (Equi Diagram; Experimental)

  Google Scholar 

• Indicates key paper 68Was: R.J. Wasilewski, “Structure Defects in CsCl Intermetallic Compounds. II. Experimental,”J. Phys. Chem. Solids, 29(1), 51–56 (1968). (Equi Diagram; Experimental; Indicates presence of a phase diagram)

  Article  ADS  Google Scholar 

• 69Ell: G.R.B. Elliott, C.C. Herrick, J.F. Lemons, and P.C. Nordine, “Vapor Pressure and Electrical Conductivity Measurements of Gold-Cadmium Liquid Solutions,”High Temp. Sci., 1, 58–75 (1969). (Thermo; Experimental)

  Google Scholar 

• 69Fer: P.L. Ferraglio, K. Mukherjee, and L.S. Castleman, “First and Second Order Phase Changes in Splat-Cooled Gold-Cadmium and Gold-Zinc Alloys,” U.S. Clearinghouse Fed. Sci. Tech. Infor., AD No. 710807 (1969); U.S. Govt. Res. Develop. Rep.,70(20), 91;Chem. Abstr. 74(24), 131451y. (Equi Diagram; Experimental)

• 69Hav: E.E. Havinga, J.H.N. van Vucht, and K.H.J. Buschow, “Relative Stability of Various Stacking Orders in Close-Packed Metal Structures,”Philips Res. Rep., 24(24), 407–426 (1969). (Equi Diagram; Theory)

  Google Scholar 

• Indicates key paper 69Hir: M. Hirabayashi, K. Hiraga, S. Yamaguchi, and N. Ino, “Close-Packed Structures with Long-Period Modulations of Stacking Sequence and Atomic Order in Gold-Cadmium Alloys,”J. Phys. Soc. Jpn., 27(1), 80–88 (1969). (Crys Structure; Experimental)

  Article  ADS  Google Scholar 

• 69Hou: B.L. Houseman and G.R.B. Elliott, “StirredH-Cell Measurements on Liquid Alloys of Cadmium with a Small Amount of Gold,”J. Electrochem. Soc., 116, 1363 (1969). (Thermo; Experimental)

  Article  Google Scholar 

• 70Con: D.R. Conant and H.S. Swofford, Jr., “Abrupt Changes in Cadmium Activity with Composition for Dilute Copper and Gold Alloys,”J. Chem. Eng. Data., 15(4), 539 (1970). (Thermo; Experimental)

  Article  Google Scholar 

• 70Fer: P.L. Ferraglio, K. Mukherjee, and L.S. Castleman, “Martensitic Transformation in a Splat-Cooled Au-50 at.% Cd Alloy,”Acta Metall., 18(10), 1067–1070 (1970). (Equi Diagram; Experimental)

  Article  Google Scholar 

• 70Hir: M. Hirabayashi, S. Yamaguchi, K. Hiraga, N. Ino, H. Sato, and R.S. Toth, “New Type of Long-Period Superlattice with Hexagonal Symmetry in Gold-Cadmium Alloys,”J. Phys. Chem. Solids, 31(1), 77–94 (1970). (Crys Structure; Experimental)

  Article  ADS  Google Scholar 

• 70Led: H.M. Ledbetter, “Martensite Crystallography of the Cubic to Orthorhombic Transformation in Gold-47.5 Cadmium,”Scr. Metall., 4(11), 931–937 (1970). (Equi Diagram; Theory)

  Article  Google Scholar 

• 70Lie: D.S. Lieberman, “Crystal Geometry and Mechanisms of Phase Transformations in Crystalline Solids,” Paper from Phase Transformations, ASM, 1–58 (1970). (Equi Diagram; Review)

• 70Luo: H.L. Luo and K. Andres, “Superconductivity in Noble-Metal-Rich Hexagonal Close-Packed Phases,”Phys. Rev. B, Conden. Matt., 1, 3002–3006 (1970). (Equi Diagram; Experimental)

  ADS  Google Scholar 

• 70Tac: M. Tachiki and S. Maekawa, “Periods of Long Period Superlattices in Alloys,”J. Phys. Soc. Jpn., 28(2), 375–379 (1970). (Crys Structure; Theory)

  Article  ADS  Google Scholar 

• 71Cha: Y.A. Chang, I. Gyuk, and J. Franks, “Thermodynamics of Lattice Disorder of the Cesium Chloride-Type Intermetallic Phases at Nonstoichiometric Compositions and the Thermodynamic Properties of β′ AuCd and β′ AgMg Phases,”Acta Metall., 19(9), 939–953 (1971). (Thermo; Theory)

  Article  Google Scholar 

• 71Jov: M. Jovanovic, M.E. Brookes, and R.W. Smith, “Effect of Solute Interchange on the Martensitic Transformation in the 52.5 at.% Au−Cd Alloy,”Met. Sci. J., 5(6), 230–232 (1971). (Equi Diagram; Theory)

  Google Scholar 

• Indicates key paper 71Kom: K.L. Komarek and G. Stummerer, “Thermodynamic Investigations in the Au−Cd System,”Monatsh. Chem., 102(5), 1360–1373 (1971) in German. (Equi Diagram, Thermo; Experimental)

  Article  Google Scholar 

• 72Gef: Y. Gefen and M. Rosen, “Behavior of the Elastic and Anelastic Properties of Au-47.5 at.% Cd in the Vicinity of the Cubic-Orthorhombic Phase Transformation,”Philos. Mag., 26(3), 727–736 (1972). (Equi Diagram; Theory)

  Article  ADS  Google Scholar 

• 72Kom: K.L. Komarek and G. Stummerer, “Thermodynamic Investigations in the Gold-Cadmium System,”Monatsh. Chem., 102(5), 1360–1373 (1972) in German. (Thermo; Experimental)

  Google Scholar 

• 72Led1: H.M. Ledbetter and C.M. Wayman, “The Crystallography of the β-to-β″ AuCd Martensitic Transformation,”Acta Metall., 20(1), 19–30 (1972). (Equi Diagram; Theory)

  Article  Google Scholar 

• 72Led2: H.M. Ledbetter and C.M. Wayman, “On βAuCd Martensite,”Metall. Trans., 3(9), 2349–2356 (1972). (Crys Structure; Experimental)

  Article  Google Scholar 

• 73Gef: Y. Gefen, A. Halwany, and M. Rosen, “Effect of Hydrostatic Pressure on the Cubic-Orthorhombic Phase Transformation in Gold-47.5 at.% Cadmium Alloy,”Philos. Mag., 28(1), 1–9 (1973). (Pressure; Experimental)

  Article  ADS  Google Scholar 

• Indicates key paper 73Kom: K.L. Komarek, E. Reiffenstein, and G. Stummerer, “Thermodynamic Investigations in the Gold-Cadmium System. II.,”Monatsh. Chem., 104(6), 1570–1585 (1973) in German. (Equi Diagram, Thermo; Experimental; Indicates presence of a phase diagram)

  Article  Google Scholar 

• 76Miu: S. Miura, T. Mori, N. Nakanishi, Y. Murakami, and S. Kachi, “Study of Superelasticity Associated with the Thermoelastic Martensitic Transformation in Cu−Cd Alloys,”Philos. Mag., 34(3), 337–349 (1976). (Equi Diagram; Experimental)

  Article  ADS  Google Scholar 

• Indicates key paper 77Ala1: K.M. Alasafi and K. Schubert, “Crystal Structure of AuCd₃,”J. Less-Common Met., 51(2), 225–233 (1977) in German. (Equi Diagram, Crys Structure; Experimental; Indicates presence of a phase diagram)

  Article  Google Scholar 

• 77Ala2: K.M. Alasafi and K. Schubert, “Crystal Structure of AuCd.r,”J. Less-Common Met., 55(1), 1–8 (1977) in German. (Equi Diagram; Experimental; Indicates presence of a phase diagram)

  Article  Google Scholar 

• 77Gef: G. Gefen, J. Makovsky, and M. Rosen, “Temperature and Pressure Derivatives of Elastic Constants in Single-Crystal Gold-47.5 at.% Cadmium Near Martensitic Phase Transformation,”J. Phys. Chem. Solids, 38(6), 647–651 (1977). (Equi Diagram; Experimental)

  Article  ADS  Google Scholar 

• 77Tad: T. Tadaki and K. Shimizu, “Modified2H and9R Martensites in a Gold-47.5 at.% Cadmium Alloy,”Trans. Jpn. Inst. Met., 18(10), 735–739 (1977). (Crys Structure; Experimental)

  Google Scholar 

• 78Ala: K.M. Alasafi and K. Schubert, “Crystal Structure of Room-Temperature Au_1.1Cd_0.9,”Z. Kristallogr., 148(3–4), 179–191 (1978). (Crys Structure; Experimental)

  Google Scholar 

• 78Hus: T.E. Huson and C.M. Wayman, “Observations on Sputtered Epitaxial Au₃Cd Films,”Mater. Res. Bull., 13(7), 723–727 (1978). (Equi Diagram; Experimental)

  Article  Google Scholar 

• 78Tad: T. Tadaki, Y. Katano, and K. Shimizu, “Morphological and Crystallographic Studies on Au-5- at.% Cd Martensite,”Acta Metall., 26(5), 883–892 (1978). (Equi Diagram; Experimental)

  Article  Google Scholar 

• Indicates key paper 79Ala: K.M. Alasafi and K. Schubert, “Crystal Structures of Au₃Cd₅ and Au₅Cd₈.h,”J. Less-Common Met., 65(1), P23-P28 (1979) in German. (Equi Diagram; Experimental; Indicates presence of a phase diagram)

  Article  Google Scholar 

• 79Iwa: H. Iwasaki and Y. Watanabe, “Structure of Periodic Antiphase Domain Boundaries in Long-Range Ordered Alloys,” AIP Conf. Proc.,53, Modulated Struc., 247–249 (1979). (Crys Structure; Experimental)

  Article  ADS  Google Scholar 

• 79Koz: E.V. Kozlov and S.V. Starenchenko, “Order-Disorder Phase Transition in Alloy Au₃Cd,”Fiz. Met. Metalloved., 48(6), 1220–1226 (1979) in Russian; TR;Phys. Met. Metallogr., 48(6), 82–87 (1979). (Equi Diagram; Experimental)

  Google Scholar 

• 79Suz: T. Suzuki, A. Nagasawa, and N. Nakanishi, “Relations Between Crystal Structures and Electrical Resistivity Changes of Martensites in Au−Cd Alloys,”Martensitic Transformations, Cambridge, MA, 166–170 (1979). (Equi Diagram; Experimental)

• 79Tad: T. Tadaki and C.M. Wayman, “Morphology and Crystal Structure of Martensite Formed in Quenched Au-47.5 at.% Cd,”Martensitic Transformations, Cambridge, MA, 160–165 (1979). (Equi Diagram; Experimental)

• 79Wil: R.O. Williams, “Elastic Energy and Metastable Phase Equilibria for Coherent Mixtures in Cubic Systems,” ORNL-5509, 18 p (1979). (Equi Diagram; Theory)

• 80Agr: R.D. Agrawal, V.N.S. Marthur, and M.L. Kapoor, “Thermodynamics of Cadmium-Bearing Binary Substitutional Solutions,”J. Phys. F (Met. Phys.), 10(11), 2395–2404 (1980). (Thermo; Theory)

  Article  ADS  Google Scholar 

• 80Bar: J. Baram, J. Avissar, Y. Gefen, and M. Rosen, “Release of Elastic Strain Energy as Acoustic Emission During the Reserse Thermoelastic Phase Transformation in Au-47.5 at.% Cd Alloy,”Scr. Metall., 14(9), 1013–1016 (1980). (Equi Diagram; Experimental)

  Article  Google Scholar 

• 81Bar: J. Baram and M. Rosen, “The Thermoelastic Phase Transition in Au−Cd Alloys Studied by Acoustic Emission,”Philos. Mag. A, 44(4), 895–903 (1981). (Equi Diagram; Experimental)

  Article  ADS  Google Scholar 

• 81Con: D.R. Conant and G.R.B. Elliott, “Second Law Studies. I.—Comparisons of emf Values and Vapor Pressures for Cadmium in Molten Alloys with Small Amounts of Gold. Stable and Metastable Equilibrium and Confirmation of the Second Law,”High Temp. Sci., 14(4), 215–230 (1981). (Thermo; Experimental)

  Google Scholar 

• 81Hir1: M. Hirabayashi, K. Hiraga, and D. Shindo, “High-Voltage, High-Resolution Electron Microscopy of Au−Cd Alloys. I. Hexagonal Long-Period Superstructures Near 30 at.% Cd,”J. Appl. Crystallogr., 14(3), 169–177 (1981). (Crys Structure; Experimental)

  Article  Google Scholar 

• 81Hir2: K. Hiraga, D. Shindo, and M. Hirabayashi, “High-Voltage, High-Resolution Electron Microscopy of Au−Cd Alloys. III. One-Dimensional Long-Period Superstructure of DO₂₃ Type,”J. Appl. Crystallogr., 14(3), 185–190 (1981). (Crys Structure; Experimental)

  Article  Google Scholar 

• 81Shi: D. Shindo, K. Hiraga, and M. Hirabayashi, “High-Voltage, High-Resolution Electron Microscopy of Au−Cd Alloys. II. Double Hexagonal Long-Period Superstructures,”J. Appl. Crystallogr., 14(3), 178–184 (1981). (Crys Structure; Experimental)

  Article  Google Scholar 

• 81Suz: T. Suzuki, M. Takagi, A. Nagasawa, and N. Nakanishi, “The Effect of Quenching on the Martensitic Transformation in β₁ Phase of Au−Cd Alloys,”J. Mater. Sci., 16(11), 3013–3020 (1981). (Equi Diagram; Experimental)

  Article  ADS  Google Scholar 

• 82Ahm: S. Ahmed, “Phase Transformation in Au−Cd Alloy (75 at.% Cd),”Met. Sci., 16(10), 497–498 (1982). (Equi Diagram, Crys Structure; Experimental)

  Google Scholar 

• 82Bar: J. Baram and M. Rosen, “On the Nature of the Thermoelastic Martensitic Phase Transformation in Au-47.5 at.% Cd Determined by Acoustic Emission,”Acta Metall., 30(3), 655–662 (1982). (Equi Diagram; Experimental)

  Article  Google Scholar 

• 83Cha: M.W. Chase, “Heats of Transformation of the Elements,”Bull. Alloy Phase Diagrams, 4(1), 123–124 (1983). (Thermo; Compilation)

  Google Scholar 

• 83Gef: Y. Gefen and J. Baram, “Excess Solubility of Cadmium in Gold by Rapid Solidification,”J. Mater. Sci. Lett., 2(6), 259–262 (1983). (Crys Structure; Experimental)

  Article  Google Scholar 

Download references