William Giauque
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Most Influential Person Across History
American chemist
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Chemistry
William Giauque's Degrees
- PhD Chemistry University of California, Berkeley
Why Is William Giauque Influential?
(Suggest an Edit or Addition)According to Wikipedia, William Francis Giauque was a Canadian-born American chemist and Nobel laureate recognized in 1949 for his studies in the properties of matter at temperatures close to absolute zero. He spent virtually all of his educational and professional career at the University of California, Berkeley.
William Giauque's Published Works
Number of citations in a given year to any of this author's works
Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author
Published Works
- The Entropy of Water and the Third Law of Thermodynamics. The Heat Capacity of Ice from 15 to 273°K. (1936) (516)
- Attainment of Temperatures Below 1° Absolute by Demagnetization of Gd 2 (SO 4 ) 3 .8H 2 O (1933) (372)
- A THERMODYNAMIC TREATMENT OF CERTAIN MAGNETIC EFFECTS. A PROPOSED METHOD OF PRODUCING TEMPERATURES CONSIDERABLY BELOW 1° ABSOLUTE (1927) (362)
- The Thermodynamic Properties of Aqueous Sulfuric Acid Solutions and Hydrates from 15 to 300°K.1 (1960) (240)
- The Heat Capacities and Entropies of Aluminum and Copper from 15 to 300°K. (1941) (160)
- THE HEAT CAPACITY AND ENTROPY OF CARBON MONOXIDE. HEAT OF VAPORIZATION. VAPOR PRESSURES OF SOLID AND LIQUID. FREE ENERGY TO 5000°K. FROM SPECTROSCOPIC DATA (1932) (159)
- The Heat Capacity and Entropy of Nitrogen. Heat of Vaporization. Vapor Pressures of Solid and Liquid. The Reaction 1/2 N2 + 1/2 O2 = NO from Spectroscopic Data (1933) (155)
- THE THIRD LAW OF THERMODYNAMICS. EVIDENCE FROM THE SPECIFIC HEATS OF GLYCEROL THAT THE ENTROPY OF A GLASS EXCEEDS THAT OF A CRYSTAL AT THE ABSOLUTE ZERO (154)
- The Entropies of Nitrogen Tetroxide and Nitrogen Dioxide. The Heat Capacity from 15°K to the Boiling Point. The Heat of Vaporization and Vapor Pressure. The Equilibria N2O4=2NO2=2NO+O2 (1938) (138)
- Carbon Dioxide. The Heat Capacity and Vapor Pressure of the Solid. The Heat of Sublimation. Thermodynamic and Spectroscopic Values of the Entropy (1937) (117)
- THE HEAT CAPACITY OF NITRIC OXIDE FROM 14°K. TO THE BOILING POINT AND THE HEAT OF VAPORIZATION. VAPOR PRESSURES OF SOLID AND LIQUID PHASES. THE ENTROPY FROM SPECTROSCOPIC DATA (1929) (102)
- Molecular Rotation in Ice at 10°K. Free Energy of Formation and Entropy of Water (1933) (100)
- Ammonia. The Heat Capacity and Vapor Pressure of Solid and Liquid. Heat of Vaporization. The Entropy Values from Thermal and Spectroscopic Data (1937) (81)
- THE ENTROPY OF HYDROGEN AND THE THIRD LAW OF THERMODYNAMICS THE FREE ENERGY AND DISSOCIATION OF HYDROGEN (1930) (79)
- THE ENTROPY OF HYDROGEN CHLORIDE. HEAT CAPACITY FROM 16°K. TO BOILING POINT. HEAT OF VAPORIZATION. VAPOR PRESSURES OF SOLID AND LIQUID (75)
- The Entropy of Hydrogen Cyanide. Heat Capacity, Heat of Vaporization and Vapor Pressure. Hydrogen Bond Polymerization of the Gas in Chains of Indefinite Length (1939) (75)
- The Production of Temperatures below One Degree Absolute by Adiabatic Demagnetization of Gadolinium Sulfate (1935) (74)
- The Heat Capacity and Vapor Pressure of Solid and Liquid Nitrous Oxide. The Entropy from its Band Spectrum (1935) (66)
- The Entropy of Water from the Third Law of Thermodynamics. The Dissociation Pressure and Calorimetric Heat of the Reaction Mg(OH)2 = MgO + H2O.. The Heat Capacities of Mg(OH)2 and MgO from 20 to 300°K. (1937) (65)
- Hydrogen Sulfide. The Heat Capacity and Vapor Pressure of Solid and Liquid. The Heat of Vaporization. A Comparison of Thermodynamic and Spectroscopic Values of the Entropy (1936) (61)
- The Heat Capacities and Entropies of Silver and Lead from 15° to 300°K. (1941) (61)
- The Heat Capacity of Mercury from 15 to 330°K. Thermodynamic Properties of Solid Liquid and Gas. Heat of Fusion and Vaporization1. (1953) (58)
- The Heat Capacity and Entropy of Gold from 15 to 300°K.1 (1952) (52)
- The Heat Capacity of Nickel from 15 to 300°K. Entropy and Free Energy Functions1 (1952) (50)
- The Heat of Hydration of Sodium Sulfate. Low Temperature Heat Capacity and Entropy of Sodium Sulfate Decahydrate1 (1958) (49)
- Magnetothermodynamics of Ce2Mg3(NO3)12· 24H2O. II. The evaluation of absolute temperature and other thermodynamic properties of CMN to 0.6 m°K (1973) (47)
- The Entropy of Nitromethane. Heat Capacity of Solid and Liquid. Vapor Pressure, Heats of Fusion and Vaporization (1947) (46)
- Relation of crystalline forms I, III, IV, and V of anhydrous sodium sulfate as determined by the third law of thermodynamics (1972) (46)
- THE CALCULATION OF FREE ENERGY FROM SPECTROSCOPIC DATA (1930) (45)
- Magnetothermodynamics of gadolinium gallium garnet. I. Heat capacity, entropy, magnetic moment from 0.5 to 4.2 °K, with fields to 90 kG along the [100] axis (1973) (44)
- THE HYDROGEN, CHLORINE, HYDROGEN CHLORIDE EQUILIBRIUM AT HIGH TEMPERATURES (1932) (43)
- The Entropies of Nitric Acid and its Mono- and Tri-hydrates. Their Heat Capacities from 15 to 300°K. The Heats of Dilution at 298.1°K. The Internal Rotation and Free Energy of Nitric Acid Gas. The Partial Pressures over its Aqueous Solutions (1942) (43)
- PARAMAGNETISM AND THE THIRD LAW OF THERMO-DYNAMICS. INTERPRETATION OF THE LOW-TEMPERATURE MAGNETIC SUSCEPTIBILITY OF GADOLINIUM SULFATE (1927) (42)
- Ammonium Oxide and Ammonium Hydroxide. Heat Capacities and Thermodynamic Properties from 15 to 300°K.1 (1953) (38)
- THE HEAT CAPACITY OF HYDROGEN IODIDE FROM 15°K. TO ITS BOILING POINT AND ITS HEAT OF VAPORIZATION. THE ENTROPY FROM SPECTROSCOPIC DATA (1929) (37)
- Thermal Conductivity and Heat Capacity of 7740 Pyrex below 4°K and in Magnetic Fields to 90 kG (1968) (35)
- AN ISOTOPE OF OXYGEN, MASS 18. INTERPRETATION OF THE ATMOSPHERIC ABSORPTION BANDS (1929) (35)
- The Entropy of Iodine. Heat Capacity from 13 to 327 K. Heat of Sublimation1 (1959) (34)
- Thermodynamics of the lead storage cell. The heat capacity and entropy of lead dioxide from 15 to 318.degree.K (1968) (34)
- Design of a 100‐Kilogauss 4‐Inch Core Solenoid for Continuous Operation (1960) (30)
- Sulfur Dioxide. The Heat Capacity of Solid and Liquid. Vapor Pressure. Heat of Vaporization. The Entropy Values from Thermal and Molecular Data (1938) (29)
- TRIFLUOROMETHANE: ENTROPY, LOW TEMPERATURE HEAT CAPACITY, HEATS OF FUSION AND VAPORIZATION, AND VAPOR PRESSURE1 (1962) (29)
- An Example of the Difficulty in Obtaining Equilibrium Corresponding to a Macrocrystalline Non-volatile Phase. The Reaction Mg(OH)2⇄ MgO + H2O(g) (1949) (28)
- Isotope Sieve for 4He vs 3He. The Low‐Temperature Heat Capacity of SiO2 Glass before and after Contact with 4He and 3He (1969) (26)
- The Entropy of NH3·2H2O. Heat Capacity from 15 to 300°K.1 (1964) (25)
- SYMMETRICAL AND ANTISYMMETRICAL HYDROGEN AND THE THIRD LAW OF THERMODYNAMICS. THERMAL EQUILIBRIUM AND THE TRIPLE POINT PRESSURE (1928) (25)
- A Test of the Third Law of Thermodynamics by Means of Two Crystalline Forms of Phosphine. The Heat Capacity, Heat of Vaporization and Vapor Pressure of Phosphine. Entropy of the Gas (1937) (25)
- The Entropy of Ethyl Chloride. Heat Capacity from 13 to 287°K. Vapor Pressure. Heats of Fusion and Vaporization (1948) (24)
- Magnetothermodynamics of Ce2Mg3(NO3)12· 24H2O. I. Heat capacity, entropy, magnetic moment from 0.5 to 4.2°K with fields to 90 kG along the a crystal axis. Heat capacity of Pyrex 7740 glass in fields to 90 kG (1973) (24)
- Amorphous Carbon Resistance Thermometer-Heaters for Magnetic and Calorimetric Investigations at Temperatures below 1 °K. (1938) (23)
- Calorimetric Determination of Isothermal Entropy Changes in High Magnetic Fields at Low Temperatures. CoSO4·7H2O (1962) (23)
- Chlorine. The Heat Capacity, Vapor Pressure, Heats of Fusion and Vaporization, and Entropy (1939) (23)
- Propylene. The Heat Capacity, Vapor Pressure, Heats of Fusion and Vaporization. The Third Law of Thermodynamics and Orientation Equilibrium in the Solid (1937) (22)
- ZnSO4·7H2O. ZnSO4·6H2O. Heat Capacities, Entropies and Crystal Perfection at Low Temperatures. Heats of Solution and Transition (1950) (22)
- AN ISOTOPE OF OXYGEN, MASS 17, IN THE EARTH'S ATMOSPHERE (1929) (22)
- The Heat Capacity of Anhydrous NiCl2 from 15 to 300°K. The Antiferromagnetic Anomaly near 52°K. Entropy and Free Energy1 (1952) (22)
- The Low Temperature Heat Capacity and Entropy of Sulfuric Acid Hemihexahydrate. Some Observations on Sulfuric Acid “Octahydrate”1 (1956) (21)
- Magnetothermodynamics of Antiferromagnetic, Ferroelectric β‐Gd2(MoO4)3. III. Heat Capacity, Entropy, Magnetic Moment of the Electrically Polarized Form from 0.4 to 4.2°K with Fields to 90 kG along the b Crystal Axis (1972) (21)
- Carbonyl Chloride. Entropy. Heat Capacity. Vapor Pressure. Heats of Fusion and Vaporization. Comments on Solid Sulfur Dioxide Structure (1948) (20)
- The Heat Capacity and Magnetic Properties of Single Crystal Copper Sulfate Pentahydrate from 0.25 to 4°K.1 (1952) (20)
- Magnetothermodynamics of ferroelectric, ferroelastic, antiferromagnetic β‐terbium molybdate. I. Heat capacity, entropy, magnetic moment of the electrically polarized form from 0.4 to 4.2 °K with fields to 90 kG along the c crystal axis (1975) (20)
- Magnetism and the Third Law of Thermodynamics. Magnetic Properties of Ferrous Sulfate Heptahydrate from 1 to 20°K. Heat Capacity from 1 to 310°K. (1949) (19)
- The Entropy of Cyanogen. Heat Capacity and Vapor Pressure of Solid and Liquid. Heats of Fusion and Vaporization (1939) (18)
- Magnetothermodynamics of Single Crystal CuSO4·5H2O. V. Fields Along the β Axis. Thermodynamic Temperature without Heat Introduction below 0.5°K. A Reference at 0.035°K (1970) (18)
- The Entropy of Iodine Monochloride. Heat Capacity from 17 to 322°K. Vapor Pressure. Heats of Fusion and Vaporization1 (1965) (17)
- Magnetothermodynamics of α‐NiSO4·6H2O. I. Heat Capacity, Entropy, Magnetic Moment, and Internal Energy, from 0.4° to 4.2°K, with Fields 0–90 kG along the c Axis (1967) (17)
- Magnetothermodynamic Properties of MnCl2 from 1.3° to 4.4°K at 90 kG. A Zero Entropy Reference. The Magnetomechanical Process at Absolute Zero (1965) (17)
- The Heat Capacity and Entropy of Sulfuric Acid Trihydrate Glass and Crystals from 15 to 300°K.1 (1952) (17)
- The Thermal Conductivity of Silicon Dioxide Glass from 0.5 to 4.2 K (1969) (17)
- A Decrease in the Electrical Resistance of Gold with a Magnetic Field at Low Temperatures (1937) (17)
- Carbon Thermometer‐Heaters for Use at Low Temperatures. Effects of Particle Size and Adsorption of Hydrogen or Helium (1952) (17)
- The Production of Temperatures below 1° A. The Heat Capacities of Water, Gadolinium Nitrobenzene Sulfonate Heptahydrate and Gadolinium Anthraquinone Sulfonate (1936) (16)
- HYDROGEN GAS THERMOMETER COMPARED WITH THE OXYGEN AND HYDROGEN VAPOR-PRESSURE THERMOMETERS BY MEANS OF A COPPER-CONSTANTAN THERMOCOUPLE (1927) (16)
- THE THERMODYNAMIC PROPERTIES OF SODIUM HYDROXIDE AND ITS MONOHYDRATE. HEAT CAPACITIES TO LOW TEMPERATURES. HEATS OF SOLUTION1 (1962) (16)
- NUCLEAR SPIN AND THE THIRD LAW OF THERMODYNAMICS. THE ENTROPY OF IODINE (1931) (16)
- Aqueous Sulfuric Acid. Heat Capacity. Partial Specific Heat Content of Water at 25 and -20°1 (1952) (16)
- Sample Chamber for Magnetothermodynamic Measurements (1966) (15)
- Magnetothermodynamics of Antiferromagnetic αMnCl2·4H2O. IV. Reversibility Conditions in the a, b, and p Regions with H ‖ c Axis. Spin Flop, an Inappropriate Term (1970) (15)
- Perchloryl Fluoride. Vapor Pressure, Heat Capacity, Heats of Fusion and Vaporization Failure of the Crystal to Distinguish O and F1 (1958) (14)
- Heat Capacity and Entropy of NiSiF6·6H2O from 0.35° to 4.2°K with Magnetic Fields 0–90 kG Perpendicular to the c axis. The Use of 3He Gas Conduction in Calorimetry (1967) (14)
- Magnetothermodynamics of α‐MnCl2·4H2O. II. Heat Capacity, Entropy, Magnetic Moment, from 0.4 to 4.2°K with Fields to 90 kG along the b Crystallographic Axis (1970) (14)
- Temperatures below 1deg (1936) (13)
- Additions and Corrections - The Heat Capacity and Entropy of Carbon Monoxide. Heat of Vaporization. Vapor Pressure of Solid and Liquid. Free Energy to 5000 degrees K. from Spectroscopic Data (1933) (13)
- The Spontaneous Transformation from Macrocrystalline to Microcrystalline Phases at Low Temperatures. The Heat Capacity of MgSO4·6H2O1 (1955) (13)
- Magnetism and the Third Law of Thermodynamics. Magnetic Properties and Heat Capacity of CoSO4·7H2O from 0.1 to 15°K. (1949) (13)
- Magnetism and the Third Law of Thermodynamics. Magnetic Susceptibility, Adiabatic Change of Temperature on Magnetization and Head Capacity of NiSO4. 7H2O1 (1941) (12)
- The Thermodynamic Temperature Scale in the Region Below 1° Absolute (1935) (11)
- The Equilibrium Reaction NiCl2 + H2 = Ni + 2HCl. Ferromagnetism and the Third Law of Thermodynamics1 (1953) (11)
- Experiments Establishing the Thermodynamic Temperature Scale below 1 °K. The Magnetic and Thermodynamic Properties of Gadolinium Phosphomolybdate as a Function of Field and Temperature (1938) (11)
- Induction Heaters for Calorimetry below 1 °K. An Investigation of the Electrical Resistance of Gold-Silver Alloys at Low Temperatures (1938) (11)
- Magnetothermodynamics of CuK2(SO4)2·6H2O. IV. Magnetic Moment, Heat Capacity, Entropy from 0.4 to 4.2°K with Fields to 90 kG along the α Magnetic Axis (1971) (11)
- The Heat Capacity of Gadolinium Sulfate Octahydrate Below 1° Absolute (1933) (11)
- The Heat Capacities and Entropies of Sulfuric Acid and Its Mono- and Dihydrates from 15 to 300°K.1 (1952) (11)
- Thermodynamics of iodine trichloride. Entropy and heat capacity from 15 to 325.deg.K. Composition of the equilibrium iodine monochloride and chlorine gas phase (1969) (11)
- Entropies of the hydrates of sodium hydroxide. II. Low-temperature heat capacities and heats of fusion of NaOH.2H2O and NaOH.3.5H2O (1969) (11)
- The Freezing Point Curves of Concentrated Aqueous Sulfuric Acid1 (1952) (11)
- Arsine. Vapor Pressure, Heat Capacity, Heats of Transition, Fusion and Vaporization. The Entropy from Calorimetric and from Molecular Data1 (1955) (11)
- Magnetic Moment and Susceptibility of MnCl2 as a Function of Field along the b Magnetic Axis to 95 kG from 1.3° to 4.2°K (1965) (10)
- Heat Capacity, Entropy, and Magnetic Moment of Single‐Crystal CuSO4·5 H2O with Fields to 90 kG ‖ to the α Magnetic Axis (1967) (10)
- Magnetothermodynamics of Single‐Crystal CuSO4·5H2O. II. Fields ‖ to the α‐Magnetic Axis. Thermodynamic Temperature and Heat Capacity without Heat Introduction below 0.4°K. Calorimetric Heat Capacity from 0.4°–4.2°K with Fields of 1 and 3 kG (1968) (10)
- THE CONDITIONS FOR PRODUCING TEMPERATURES BELOW 1° ABSOLUTE BY DEMAGNETIZATION OF Gd2(SO4)3·8H2O. TEMPERATURE-MAGNETIC FIELD ISENTROPICS (1932) (10)
- Heat Capacity of MnCl2 from 1.3° to 4.2°K with Magnetic Fields to 50 Kilogauss Parallel to the b Magnetic Axis (1964) (10)
- Determination of Thermodynamic Temperatures near 0°K without Introducing Heat below 1°K (1953) (10)
- Magnetothermodynamics of α‐MnCl2·4H2O. III. Heat Capacity, Entropy, Magnetic Moment, from 0.3 to 4.2°K with Fields to 90 kG along the [100] Crystal Axis (1970) (10)
- Heat and Entropy of Hydration of α‐NiSO4·6H2O to NiSO4·7H2O. Their Low‐Temperature Heat Capacities (1966) (9)
- Pyrex Glass Dewar Vessels and Metal Transfer Tubes for Liquid Helium (1947) (9)
- The Vapor Pressure of Water Over Aqueous Sulfuric Acid at 25°1 (1955) (9)
- The Three Melting Points and Heats of Fusion of Phosgene. Entropy of Solids I and II, and Atomic Exchange Disorder in Solid II1 (1960) (9)
- The Change in Electrical Conductivity of Aqueous Sulfuric Acid near Absolute H2SO4 and H2SO4·H2O1 (1952) (9)
- A Proposal to Redefine the Thermodynamic Temperature Scale: with a Parable of Measures to Improve Weights (1939) (9)
- COPPER-CONSTANTAN THERMOCOUPLES AND THE HYDROGEN THERMOMETER COMPARED FROM 15 TO 283° ABSOLUTE (1927) (9)
- Heat Capacity and Entropy of NiSiF6·6H2O in the Region 0.30°—4.25°K with Magnetic Fields 0–90 kG Parallel to the c Axis (1966) (9)
- The Heat of Hydration of Cobalt Sulfate Hexahydrate to Heptahydrate. Their Solubilities and Heats of Solution1 (1965) (8)
- The Viscosity of Liquid Helium II (1938) (8)
- The Magnetic Flux Distribution when a Cylinder of Constant Permeability Is Placed in a Homogeneous Field. The Magnetic Susceptibility of Gadolinium Oxide at Low Temperatures (1939) (8)
- Measurements of the Viscosity of Liquid Helium II (1939) (8)
- Magnetothermodynamics of Single‐Crystal CuSO4·5H2O. IV. Properties over the Range 0.4°–4.2°K with Fields to 90 kG ‖ to the β Magnetic Axis (1968) (7)
- The Low Temperature Heat Capacity and Entropy of Thallous Chloride1 (1959) (7)
- Use of Platinum Alloy for Electrical Leads at Liquid Helium Temperatures. Heat Conductivity (1965) (7)
- Phosphoryl Chloride. Entropy. Low Temperature Heat Capacity. Heats of Fusion and Vaporization. Vapor Pressure1 (1960) (7)
- Crystal Perfection of ZnSO4·7H2O. Partial Molal Heat Capacity, Heat Content and Vapor Pressure of its Aqueous Solutions. Thermodyanmics of Clark Cell1 (1950) (7)
- The Measurement of Adiabatic Differential Magnetic Susceptibility Near 1° Absolute. The Heat Capacity of Gadolinium Phosphomolybdate Tridecahydrate from 0.17 to 4.7° Absolute (1941) (7)
- The Measurement of Magnetic Susceptibility at Low Temperatures (1949) (6)
- An Experiment on the Adsorption of Helium Gas Used for Thermal Conduction in Calorimetry near 1 °K. The Heat of Adsorption (1938) (6)
- The Measurement of Magnetic Induction in High Magnetic Fields at Low Temperatures. CoSO4·7H2O (1962) (6)
- Erratum: Magnetothermodynamics of MnCl2·4H2O. I. Heat Capacity, Entropy, Magnetic Moment, from 0.4 to 4.2°K with Fields to 90 kG along the c Crystallographic Axis (1969) (6)
- Some Properties of Plastics and the Use of Plastic Apparatus at Low Temperatures (1952) (6)
- Magnetothermodynamics of α–NiSO4·6H2O II. Heat Capacity, Entropy, Magnetic Moment, and Internal Energy, from 0.4 to 4.2°K, with Fields 0‐90 kG Along the Bisector of the a, b Axes (1968) (6)
- The entropy of ethyl chloride; heat capacity from 13 to 287 degrees K. vapor pressure; heats of fusion and vaporization. (1948) (6)
- Magnetothermodynamics of CuK2(SO4)2·6H2O.III. Fields along the γ Axis. Thermodynamic Temperature without Heat Introduction below 0.4°K (1971) (5)
- Entropy, Internal Energy, and Heat Capacity of MnCl2 between 0° and 4.2°K in Magnetic Fields to 100 kG (1965) (4)
- The Heat Capacities and Entropies of Sulfuric Acid Tri- and Tetrahydrates1 (1955) (4)
- NiSiF6·6H2O. Temperature and Other Thermodynamic Properties from Adiabatic Demagnetization without Low‐Temperature Heat Introduction. H ∥ c Axis (1967) (4)
- The Entropies of Methane and Ammonia (1931) (4)
- The Freezing Point Method of Determining Free Energies in a 2-Component System Forming Compounds. Concentrated Aqueous Sulfuric Acid1 (1956) (4)
- The Heat Capacities and Entropies of Cobalt Sulfate Heptahydrate and Hexahydrate from 15 to 330°K.1 (1965) (4)
- Magnetothermodynamics of single crystal CuSO4⋅5H2O. VI. Properties below 0.5 °K by heat introduction with constant fields to 33 kG along the γ axis. The initial T5 dependence of entropy and heat capacity for dipole–dipole magnetic interactions (1975) (4)
- Entropies of the hydrates of sodium hydroxide. III. Low-temperature heat capacities and heats of fusion of the .alpha. and .beta. crystalline forms of sodium hydroxide tetrahydrate (1974) (4)
- The Free Energies and Entropies of Hydrogen, Chlorine and Hydrogen Chloride from Spectroscopic Data1 (1953) (4)
- Magnetothermodynamics of antiferromagnetic, polarized ferroelectric, ferroelastic β‐Gd2(MoO4)3. V. Thermodynamic temperature and other properties with heat introduction below 0.5 °K. Fields to 5 kG along the b crystal axis (1973) (4)
- Thermodynamic Temperature and Heat Capacity of NiSiF6·6H2O without Heat Introduction below 0.35°K. Magnetic Moment and Internal Energy from 0.05° to 4.2°K. Fields 0–90 kG Perpendicular to the c Axis (1967) (4)
- Magnetothermodynamics of α‐NiSO4·6H2O. V. Proton Spin Polarization Rate and Activation Enthalpy as a Function of Temperature and Field to 90 kG along the a Axis (1969) (3)
- Additions and Corrections-The Thermodynamic Properties of Aqueous Sulfuric Acid Solutions and Hydrates from 15 to 300 degrees K (1961) (3)
- Magnetothermodynamics of Nd(C2H5SO4)3⋅9H2O. IV. Determination of absolute temperature scales and other properties below 0.5°K with constant magnetic fields along the a crystal axis (1978) (3)
- Adiabatic Demagnetization of MnCl2 with the Magnetic Field Parallel to the b Magnetic Axis (1965) (3)
- The Decrease in Resistance of Constantan with a Magnetic Field at Temperatures between 1 and 20°K. (1940) (3)
- On the Entropy of Hydrogen (1930) (3)
- A basic thermodynamic method of determining absolute temperatures by utilizing the maximum entropy of electronic multiplets near liquid helium temperatures (1977) (3)
- Magnetothermodynamics of CuK2 (SO4)2· 6H2O. V. Fields along the α Axis. Thermodynamic Temperature without Heat Introduction below 0.5°K. The Freezing‐In of Magnetic Structure in the Lambda Region (1971) (3)
- Magnetic Moment, Magnetic Work, and Internal Energy of NiSiF6·6H2O in the Region 0.3°—4.2°K with Magnetic Fields 0–90 kG Parallel to the c Axis (1966) (3)
- A Fractionating Converter for Producing Para‐Hydrogen (1954) (3)
- THE LOW TEMPERATURE HEAT CAPACITY AND ENTROPY OF MERCUROUS SULFATE TO 300°K.1 (1962) (2)
- Magnetothermodynamics of Ce2Zn3(NO3)12 · 24H2O. I. Heat capacity, entropy, magnetic moment from 0.5 to 4.2 °K with fields to 90 kG along the a crystal axis (1974) (2)
- Additions and Corrections - The Entropy of NH32H2O. Heat Capacity from 15 to 300 degrees K (1964) (1)
- A Static Low Temperature Method for Determining Small Residual Fields Accurately in Magnetic Experiments (1949) (1)
- Magnetothermodynamics of Nd(C2H5SO4)3⋅9H2O. II. Determination of absolute temperature scales and other properties below 0.5 °K with constant fields along the c axis (1976) (1)
- THE FREEZING POINT-SOLUBILITY CURVE OF AQUEOUS SODIUM HYDROXIDE IN THE REGION NEAR THE ANHYDROUS-MONOHYDRATE EUTECTIC1 (1962) (1)
- Measurement of Heat Capacity of Microscopic Particles at Low Temperatures (1956) (1)
- Cadmium Sulfate and its Hydrates. Heat Capacities and Heats of Hydration. Application of the Third Law of Thermodynamics1 (1955) (1)
- Additions and Corrections-Crystal Perfection of ZnSO4-7H2O. Partial Molal Heat Capacity, Heat Content and Vapor Pressure of its Aqueous Solutions. Thermodynamics of Clark Cell (1951) (0)
- Erratum: Apparatus for Measuring Magneto‐thermodynamic Properties to High Fields at Low Temperatures (1964) (0)
- Efficient Bulk Transfer of Liquid Helium as a Superfluid (1964) (0)
- Thermostaten, Thermoregulatoren (0)
- INVESTIGATIONS OF MAGNETIC AND THERMODYNAMIC PROPERTIES PRINCIPALLY NEAR 1 DEGREE ABSOLUTE. (1961) (0)
- Examination of Certain Solid-Solid Transformations in Crystals in an Attempt to Detect the Formation of Microcrystals1 (1960) (0)
- Isotope Effect in Spectra and Precise Atomic Weights (1929) (0)
- Low temperature, chemical, and magneto thermodynamics : the scientific papers of William F. Giauque (1969) (0)
- Wendell M. Latimer, Chemist. (1955) (0)
- MAGNETOTHERMODYNAMICS OF NEODYMIUM ETHYL SULFATE NONAHYDRATE. III. HEAT CAPACITY, ENTROPY, MAGNETIC MOMENT FROM 0.5 TO 4.2°K WITH FIELDS TO 90 KG ALONG THE A CRYSTAL AXIS (1976) (0)
- Correction. The Heat Capacity of Anhydrous NiCl2 from 15 to 300 degrees K. The Antiferromagnetic Anomaly Near 52 degrees K. Entropy and Free Energy (1952) (0)
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