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200 10$aDistributed defense $enew operational concepts for integrated air and missile defense /$fThomas Karako, Wes Rumbaugh
210  1$aLanham, Maryland :$cCSIS :$cLexington Books,$d2017.
210  4$dİ2017
215   $a1 online resource (54 pages) $cillustrations (some color), photographs, tables
300   $a"A Report of the CSIS Missile Defense Project."
311   $a1-4422-8043-3 
327   $aDistributed Defense -- Contents -- List of Figures -- List of Tables -- List of Acronyms -- Acknowledgments -- CHAPTER 1.
330   $aDespite the rising salience of missile threats, current air and missile defense forces are far too susceptible to suppression. Today's U.S. air and missile defense (AMD) force lacks the depth, capacity, and operational flexibility to simultaneously perform both missions. Discussions about improving AMD usually revolve around improvements to the capability and capacity of interceptors or sensors. Rather than simply doing more of the same, the joint integrated air and missile defense (IAMD) efforts might be well served by new or reinvigorated operational concepts, here discussed collectively as "Distributed Defense." By leveraging networked integration, Distributed Defense envisions a more flexible and more dispersible air and missile defense force capable of imposing costs and dilemmas on an adversary, complicating the suppression of U.S. air and missile defenses. Although capability and capacity improvements remain essential to the high-end threats, the Distributed Defense concept focuses on creating a new architecture for today's fielded or soon-to-be fielded IAMD force to boost flexibility and resilience
606   $aAir defenses
606   $aBallistic missile defenses
615  0$aAir defenses.
615  0$aBallistic missile defenses.
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702   $aRumbaugh$b Wes
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200 10$aPhysical properties of high-temperature superconductors /$fRainer Wesche
210  1$aChichester, England :$cWiley,$d2015.
210  4$dİ2015
215   $a1 online resource (546 p.)
225 1 $aWiley Series in Materials for Electronic and Optoelectronic Applications
300   $aDescription based upon print version of record.
311   $a1-118-69669-7 
311   $a1-119-97881-5 
320   $aIncludes bibliographical references at the end of each chapters and indexes.
327   $aCover; Title Page; Copyright; Contents; About the Author; Series Preface; Preface; Acknowledgment; List of Tables; Nomenclature; Chapter 1 Brief History of Superconductivity; 1.1 Introduction; 1.2 Milestones in the Field of Superconductivity; 1.2.1 Early Discoveries; 1.2.2 Progress in the Understanding of Superconductivity; 1.2.3 Discovery of High-Temperature Superconductivity; 1.2.4 Importance of Higher Transition Temperatures for Applications; References; Chapter 2 The Superconducting State; 2.1 Introduction; 2.2 Electrical Resistance; 2.3 Characteristic Properties of Superconductors
327   $a2.4 Superconductor Electrodynamics2.5 Thermodynamics of Superconductors; References; Chapter 3 Superconductivity: A Macroscopic Quantum Phenomenon; 3.1 Introduction; 3.2 BCS Theory of Superconductivity; 3.3 Tunneling Effects; References; Chapter 4 Type II Superconductors; 4.1 Introduction; 4.2 The Ginzburg-Landau Theory; 4.3 Magnetic Behavior of Type I and Type II Superconductors; 4.4 Critical Current Densities of Type I and Type II Superconductors; 4.5 Anisotropic Superconductors; References; Chapter 5 Cuprate Superconductors: An Overview; 5.1 Introduction
327   $a5.2 Families of Superconductive Cuprates5.3 Variation of Charge Carrier Density (Doping); 5.4 Summary; References; Chapter 6 Crystal Structures of Cuprate Superconductors; 6.1 Introduction; 6.2 Diffraction Methods; 6.2.1 Bragg Condition; 6.2.2 Miller Indices; 6.2.3 Classification of Crystal Structures; 6.2.4 X-ray Diffraction; 6.2.5 Neutron Diffraction; 6.3 Crystal Structures of the Cuprate High-Temperature Superconductors; 6.3.1 The Crystal Structure of La2CuO4; 6.3.2 The Crystal Structure of YBa2Cu3O7-?; 6.3.3 The Crystal Structures of Bi-22(n - 1)n High-Temperature Superconductors
327   $a6.3.4 The Crystal Structures of Tl-based High-Temperature Superconductors6.3.5 The Crystal Structures of Hg-based High-Temperature Superconductors; 6.3.6 Lattice Parameters of Cuprate Superconductors; References; Chapter 7 Empirical Rules for the Critical Temperature; 7.1 Introduction; 7.2 Relations between Charge Carrier Density and Critical Temperature; 7.3 Effect of the Number of CuO2 Planes in the Copper Oxide Blocks; 7.4 Effect of Pressure on the Critical Temperature; 7.5 Summary; References; Chapter 8 Generic Phase Diagram of Cuprate Superconductors; 8.1 Introduction
327   $a8.2 Generic Phase Diagram of Hole-Doped Cuprate Superconductors8.2.1 Generic Phase Diagram: An Overview; 8.2.2 Symmetry of the Superconducting Order Parameter; 8.2.3 The Pseudogap; 8.3 Summary; References; Chapter 9 Superconducting Properties of Cuprate High-Tc Superconductors; 9.1 Introduction; 9.2 Characteristic Length Scales; 9.3 Superconducting Energy Gap; 9.4 Magnetic Phase Diagram and Irreversibility Line; 9.5 Critical Current Densities in Cuprate Superconductors; 9.5.1 Definitions of the Critical Current; 9.5.2 Critical Currents in Polycrystalline Cuprate Superconductors
327   $a9.5.3 Critical Currents in Bulk Cuprate Superconductors
410  0$aWiley series in materials for electronic and optoelectronic applications.
606   $aHigh temperature superconductors
615  0$aHigh temperature superconductors.
676   $a621.3/5
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