02915nam 2200637Ia 450 991078372230332120230105005413.01-281-88085-X9786611880859981-256-781-X(CKB)1000000000247219(EBL)244547(OCoLC)299571792(SSID)ssj0000159553(PQKBManifestationID)11179264(PQKBTitleCode)TC0000159553(PQKBWorkID)10158464(PQKB)10584331(MiAaPQ)EBC244547(WSP)00000719(Au-PeEL)EBL244547(CaPaEBR)ebr10106553(CaONFJC)MIL188085(OCoLC)935228948(EXLCZ)99100000000024721920050607d2004 uy 0engur|n|---|||||txtccrFrustrated spin systems[electronic resource] /editor, H.T. DiepHackensack, NJ World Scientificc20041 online resource (625 p.)1st ed. published in 1994 as Magnetic systems with competing interactions.981-256-091-2 Includes bibliographical references and index.PREFACE; CONTENTS; CHAPTER 1 FRUSTRATION - EXACTLY SOLVED FRUSTRATED MODELS; CHAPTER 2 PROPERTIES AND PHASE TRANSITIONS IN FRUSTRATED ISING SYSTEMS; CHAPTER 3 RENORMALIZATION GROUP APPROACHES TO FRUSTRATED MAGNETS IN D=3; CHAPTER 4 PHASE TRANSITIONS IN FRUSTRATED VECTOR SPIN SYSTEMS: NUMERICAL STUDIES; CHAPTER 5 TWO-DIMENSIONAL QUANTUM ANTIFERROMAGNETS; CHAPTER 6 ONE-DIMENSIONAL SPIN LIQUIDS; CHAPTER 7 SPIN ICE; CHAPTER 8 EXPERIMENTAL STUDIES OF FRUSTRATED PYROCHLORE ANTIFERROMAGNETS; CHAPTER 9 RECENT PROGRESS IN SPIN GLASSES; INDEXFrustrated spin systems have been first investigated five decades ago. Well-known examples include the Ising model on the antiferromagnetic triangular lattice studied by G H Wannier in 1950 and the Heisenberg helical structure discovered independently by A Yoshimori, J Villain and T A Kaplan in 1959. However, many properties of frustrated systems are still not well understood at present. Recent studies reveal that established theories, numerical simulations as well as experimental techniques have encountered many difficulties in dealing with frustrated systems. This volume highlights the latesMagnetizationRotational motionSpin wavesFerromagnetismMagnetization.Rotational motion.Spin waves.Ferromagnetism.538/.3Diep H. T1529149MiAaPQMiAaPQMiAaPQBOOK9910783722303321Frustrated spin systems3773195UNINA