05407nam 2200721Ia 450 991101984060332120200520144314.097866123196319780470570463047057046697811191983521119198356978128231963912823196399780470570449047057044X(CKB)2550000000001352(EBL)565058(OCoLC)512905538(SSID)ssj0000309545(PQKBManifestationID)12106853(PQKBTitleCode)TC0000309545(PQKBWorkID)10286229(PQKB)10919932(MiAaPQ)EBC565058(PPN)150894007(FR-PaCSA)45007602(FRCYB45007602)45007602(Perlego)1010408(EXLCZ)99255000000000135220090625d2009 uy 0engur|n|---|||||txtccrSingle point of failure the ten essential of supply chain risk management /Gary S. LynchHoboken, NJ Wiley2009, c20101 online resource (317 p.)Includes index.9780470424964 0470424966 Single Point of Failure: The Ten Essential Laws of Supply Chain Risk Management; Contents; About the Author; Preface; Acknowledgments; Introduction: Getting to the Truth; Chapter 1: The Laws of the Laws; Laws of the Laws; Risk Management Defined; Law of the Laws #1: Everyone, without Exception, Is Part of a Supply Chain; Law of the Laws #2: No Risk Strategy Is a Substitute for Bad Decisions and a Lack of Risk Consciousness; Law of the Laws #3: It's All in the Details; Law of the Laws #4: People Always Operate from Self-Interest; Indirect and Secondary Impacts; What Can You Conclude?Chapter 2: Law #1: If You Don't Manage and Lead Change, You Have to Surrender to ItThe Risk Wake-Up Call-Planned Change, Unplanned Consequences; We Can't Change the Past, but . . . Can We Change the Future?; Can You See the Icebergs Ahead?; Chapter 3: Law #2: The Paradigm Should Destroy the Parasite; The Paradigm in Action; Why Does the Organization Need to Identify a Supply Chain Risk Paradigm?; Beware! The Paradigm Can Shift without Notice; If the Shoe Fits; Chapter 4: Law #3: Manage Your Business DNA in a Petri Dish of Evolving Risk; Expanding the Risk Awareness UniverseKnow Your Business-Know Your SurroundingsThe Keys to Your Risk Kingdom; Your Operation's Complete Footprint; Your Action Plan; Chapter 5: Law #4: In Supply Chain Risk Management, Demand Trumps Supply; Everyone's Customer; Building Your Demand-Based Strategy; Market and Client Factors to Consider; Chapter 6: Law #5: Never Set Up Your Suppliers for Failure; Supply Chain Risk Management Program; Sourcing Strategies That Create More Risk, Not Less; Trust but Verify; Chapter 7: Law #6: Managing Production Risk Is a Dirty Job; Going Global with the Production of Risk; A New Collaborative EffortWhy Is Production So Critical?Part Two of the Double Whammy: Labor; Chapter 8: Law #7: The Logistics Risk Management Rule: Managing the Parts Does Not Equal Managing the Whole; What Is Logistics Risk?; Cargo and Warehouse Theft; The Piracy Risk; What's at Risk?; Single Points of Failure and Aggregate Risk; Supply Chains Don't Survive on Product Flows Alone; Information Flows Are Essential; In the End It's All about the Priorities and Economics; Chapter 9: Law #8: Mitigation: If Supply Chain Risk Management Isn't Part of the Solution, It Will Become the Problem; Now What Do I Do?Enter the Risk Intelligent Supply ChainEconomic Change-A Catalyst for Redefining Resiliency Management; What Is Risk Mitigation?; Chapter 10: Law #9: Financing; Insurance and Its Role in Supply Chain Risk Management; Background on Insurance in the Supply Chain Risk Area; Current Insurance Solutions and Their Limitations; Introducing Supply Chain Insurance: Approach and Challenges; Corporate Customer Benefits Arising from Supply Chain Insurance; Conclusions; What Does the Future Hold?; A View from the Insurer's Side; Chapter 11: Law #10: Manage the Risk as You Manage Your OwnQuestioning Old AssumptionsOver the past decade organizations have faced relentless customer demand for better value at less cost, individual customization, greater choice, faster delivery, higher quality, exceptional service, and more recently - increased environmental and social consciousness. The organization's weapon of choice to address this increasing demand has been the supply chain. However, as the supply chain footprint changed (e.g. outsourcing, off-shoring and customer/vendor empowerment) so did the organization's exposure to uncertainty. Organizations were taken by surprise since this exposure was unaBusiness logisticsRisk managementBusiness logistics.Risk management.658.5/03658.7Lynch Gary S(Gary Scott),1958-1842250MiAaPQMiAaPQMiAaPQBOOK9911019840603321Single point of failure4422268UNINA06850nam 2200565 a 450 991095323520332120251116210106.01-61728-391-6(CKB)2560000000015784(EBL)3020804(SSID)ssj0000416636(PQKBManifestationID)12191859(PQKBTitleCode)TC0000416636(PQKBWorkID)10422961(PQKB)10450472(MiAaPQ)EBC3020804(Au-PeEL)EBL3020804(CaPaEBR)ebr10680942(OCoLC)667175728(BIP)33698009(BIP)25773056(EXLCZ)99256000000001578420090728d2009 uy 0engur|n|---|||||txtccrElectron-phonon interactions in novel nanoelectronics /Takashi Kato1st ed.New York Nova Sciencec20091 online resource (97 p.)"Novinka."--Cover.1-60692-170-3 Includes bibliographical references (p. [79]-84) and index.Intro -- ELECTRON-PHONONINTERACTIONS IN NOVELNANOELECTRONICS -- CONTENTS -- PREFACE -- INTRODUCTION -- THEORETICAL BACKGROUND -- A. Vibronic Interactions between the Twofold DegenerateFrontier Orbitals and the E2g Vibrational Modes InBenzene -- B. Vibronic Interactions between the Twofold DegenerateFrontier Orbitals and the A1g Vibrational Modes inBenzene -- C. Vibronic Interactions between the NondegenerateFrontier Orbitals and the Ag Vibrational Modes inPolyacenes -- D. Vibronic Interactions in Polyfluoroacenes, B, NSubstitutedPolyacenes, and Polycyanodienes -- ELECTRON-PHONON COUPLING CONSTANTSFOR THE CHARGED ELECTRONIC STATESOF POLYACENES, POLYFLUOROACENES, B,N-SUBSTITUTED POLYACENES, ANDPOLYCYANODIENES -- A. Twofold Degenerate Electronic States of TheMonocations of Monoanions of Benzene,Hexafluorobenzene, and Borazine -- B. Nondegenerate Electronic Systems of Polyacenes,Polyfluoroacenes, B, N-Substituted Polyacenes, andPolycyanodienes -- OPTIMIZED STRUCTURES -- A. Benzene and Polyacenes -- B. Polyfluoroacenes -- C. B, N-Substituted Polyacenes -- D. Polycyanodienes -- C. B, N-Substituted Polyacenes -- D. Polycyanodienes -- ELECTRON-PHONON COUPLING CONSTANTS -- A. The Monocations and Monoanions of Benzene andPolyacenes -- B. Polyfluoroacenes -- 1. Monocations -- 2. Monoanions -- C. B, N-Substituted Polyacenes -- 1. Monocations -- 2. Monoanions -- D. Polycyanodienes -- 1. Monocations -- 2. Monoanions -- E. Summary -- TOTAL ELECTRON-PHONON COUPLINGCONSTANTS -- A. Polyacenes and Polyfluoroacenes -- 1. Monocations -- 2. Monoanions -- B. B, N-Substituted Polyacenes -- C. Polycyanodienes -- 1. Monocations -- 2. Monoanions -- D. Summary -- THE LOGARITHMICALLY AVERAGED PHONONFREQUENCIES -- A. Polyacenes and Polyfluoroacenes -- 1. Monocations -- 2. Monoanions -- B. B, N-Substituted Polyacenes -- C. Polycyanodienes -- D. Summary -- CONCLUDING REMARKS.ACKNOWLEDGMENT -- REFERENCES -- INDEX.In this book, the electron-phonon interactions in the charged molecular systems such as polyacenes, polyfluoroacenes, B, N-substituted polyacenes, and polycyanodienes are discussed. They estimated the electron-phonon coupling constants and the frequencies of the vibronic active modes playing an essential role in the electron-phonon interactions in order to discuss how CH-CF, CC-BN, and CC-CN substitutions are closely related to the essential characteristics of the electron-phonon interactions in these molecules by comparing the calculated results for charged polyacenes with those for charged B, N-substituted polyacenes and polycyanodienes, respectively. The C-C stretching modes around 1500 cm-1strongly couple to the highest occupied molecular orbitals (HOMO), and the lowest frequency modes and the C-C stretching modes around 1500 cm-1 strongly couple to the lowest unoccupied molecular orbitals (LUMO) in polyacenes. The C-C stretching modes around 1500 cm -1strongly couple to the HOMO and LUMO in polyfluoroacenes. The B-N stretching modes around 1500 cm -1 strongly couple to the HOMO and LUMO in B, N-substituted polyacenes. The C-C and C-N stretching modes around 1500 cm-1 strongly couple to the HOMO and LUMO in polycyanodienes. The total electron-phonon coupling constants for the monocations ( ) and monoanions ( ) decrease with an increase in molecular size in polyacenes, polyfluoroacenes, B, N-substituted polyacenes, and polycyanodienes. In general, we can expect that monocations and monoanions, in which number of carriers per atom is larger, affords larger value. The CH-CF, CC-BN, and CC-CN atomic substitutions are effective way to seek for larger values, and the CH-CF and CC-CN atomic substitutions are effective way to seek for larger values in polyacenes. The logarithmically averaged phonon frequencies ( ) which measure the frequencies of the vibronic active modes playing an essential role in the electron-phonon interactions for the monocations ( ) and monoanions ( ) in polyacenes, polyfluoroacenes, B, N-substituted polyacenes, and polycyanodienes are investigated. The values decrease with an increase in molecular size in polyacenes, polyfluoroacenes, and polycyanodienes, and the values decrease with an increase in molecular size in polyacenes, polyfluoroacenes, B, N-substituted polyacenes, and polycyanodienes. The authors can expect that in the hydrocarbon molecular systems, the values would basically decrease by substituting hydrogen atoms by heavier atoms. This can be understood from the fact that the frequencies of all vibronic active modes in polyacenes downshift by H-F substitution. However, considering that the value for the LUMO rather localized on carbon atoms in large sized polyfluoroacenes becomes larger by H-F substitution, the authors can expect that the value for a molecular orbital localized on carbon atoms has a possibility to increase by substituting hydrogen atoms by heavier atoms if the phase patterns of the molecular orbital do not significantly change by such atomic substitution. Therefore, the detailed properties of the vibrational modes and the electronic structures as well as the molecular weights are closely related to the frequencies of the vibronic active modes playing an important role in the electron-phonon interactions in the monoanions of polyfluoroacenes.Electron-phonon interactionsNanoelectronicsElectron-phonon interactions.Nanoelectronics.Kato Takashi1866471MiAaPQMiAaPQMiAaPQBOOK9910953235203321Electron-phonon interactions in novel nanoelectronics4473879UNINA