Preface Second Edition. Preface First Edition. Acknowledgments. Symbols.
Chapter 1 Importance and uses of cryogenic fluid properties. 1.1 Thermodynamic property information. 1.2 Thermodynamic property formulations. 1.3 Special considerations for modeling cryogenic fluids. 1.4 Computer programs for thermodynamic property calculation.
Chapter 2 Equation of State Development and Use. 2.1 Fundamental Equations of State. 2.2 Development of thermodynamic property formulations. 2.3 Use of fundamental equations of state for cryogenic fluids. 2.4 Ancillary functions.
Chapter 3 Helium. 3.1 Formulation for Helium. 3.2 Property Plots for Helium. 3.3 Thermodynamic Data Tables for Helium.
Chapter 4 Hydrogen. 4.1 Formulation for Parahydrogen. 4.2 Property Plots for Parahydrogen. 4.3 Thermodynamic Data Tables for Parahydrogen. 4.4 Formulation for Hydrogen. 4.5 Property Plots for Hydrogen. 4.6 Thermodynamic Data Tables for Hydrogen. 4.7 Formulation for Orthohydrogen.
Chapter 5 Deuterium. 5.1 Formulation for Deuterium. 5.2 Property Plots for Deuterium. 5.3 Thermodynamic Data Tables for Deuterium.
Chapter 6 Neon. 6.1 Formulation for Neon. 6.2 Property Plots for Neon. 6.3 Thermodynamic Data Tables for Neon.
Chapter 7 Nitrogen. 7.1 Formulation for Nitrogen. 7.2 Property Plots for Nitrogen. 7.3 Thermodynamic Data Tables for Nitrogen.
Chapter 8 Air. 8.1 Formulation for Air. 8.2 Property Plots for Air. 8.3 Thermodynamic Data Tables for Air.
Chapter 9 Carbon Monoxide. 9.1 Formulation for Carbon Monoxide. 9.2 Property Plots for Carbon Monoxide. 9.3 Thermodynamic Data Tables for Carbon Monoxide.
Chapter 10 Fluorine. 10.1 Formulation for Fluorine. 10.2 Property Plots for Fluorine. 10.3 Thermodynamic Data Tables for Fluorine.
Chapter 11 Argon. 11.1 Formulation for Argon. 11.2 Property Plots for Argon. 11.3 Thermodynamic Data Tables for Argon.
Chapter 12 Oxygen. 12.1 Formulation for Oxygen. 12.2 Property Plots for Oxygen. 12.3 Thermodynamic Data Tables for Oxygen.
Chapter 13 Methane. 13.1 Formulation for Methane. 13.2 Property Plots for Methane. 13.3 Thermodynamic Data Tables for Methane.
Chapter 14 Krypton. 14.1 Formulation for Krypton. 14.2 Property Plots for Krypton. 14.3 Thermodynamic Data Tables for Krypton.
Dr. Richard Jacobsen is Executive Director for Research and Technology Transfer and Professor of Nuclear Engineering at Idaho State University (ISU). Dr. Jacobsen’s research publications include 11 books and chapters in books; 60 refereed journal publications; 11 refereed conference proceedings; and 108 research reports, notes and technical reports.
Dr Steven Penoncello is a faculty member in the Department of Mechanical Engineering at U Idaho, and director of the Center for Applied Thermodynamic Studies (CATS).
Dr. Eric Lemmon received his Ph.D. at the University of Idaho in 1996. His current work focuses on the Refprop program (www.nist.gov/srd/nist23.cfm) and on national and international standards for the properties of natural gas.
Dr. Jacob Leachman is a faculty member of the School of Mechanical and Materials Engineering at Washington State University and heads the HYdrogen Properties for Energy Research (HYPER) laboratory.
This update to a classic reference text provides practising engineers and scientists with accurate thermophysical property data for cryogenic fluids. The equations for fifteen important cryogenic fluids are presented in a basic format, accompanied by pressure-enthalpy and temperature-entropy charts and tables of thermodynamic properties.
It begins with a chapter introducing the thermodynamic relations and functional forms for equations of state, and goes on to describe the requirements for thermodynamic property formulations, needed for the complete definition of the thermodynamic properties of a fluid. The core of the book comprises extensive data tables and charts for the most commonly-encountered cryogenic fluids.
This new edition sees significant updates to the data presented for air, argon, carbon monoxide, deuterium, ethane, helium, hydrogen, krypton, nitrogen and xenon. The book supports and complements NIST’s REFPROP - an interactive database and tool for the calculation of thermodynamic properties of cryogenic fluids.