LEADER 01447nam a2200301 i 4500
001 991002377919707536
008 131121s2004    it a          001 0 ita d
020   $a8850321538
035   $ab14164565-39ule_inst
040   $aBibl. Dip.le Aggr. Ingegneria Innovazione - Sez. Ingegneria Innovazione$beng
082 00$a620.0042
100 1 $aGrabowski, Ralph$030415
245 10$aAutoCAD 2004 :$bi fondamenti /$cRalph Grabowski
260   $aMilano :$bApogeo,$cc2004
300   $axxxvi, 921 p. :$bill. ;$c24 cm +$e1 CD-ROM
500   $aOrig. Title: AutoCAD 2004 : basics
500   $aIncludes index
630 00$aAutoCAD
650  0$aComputer graphics
907   $a.b14164565$b19-04-22$c21-11-13
912   $a991002377919707536
945   $aLE026 620.0042 GRA 01.01 2004$cC.1$g1$i2026000021515$lle026$nFondo GISI$og$pE0.00$q-$rl$s-  $t0$u1$v0$w1$x0$y.i15557005$z21-11-13
945   $aLE026 620.0042 GRA 01.01 C.2 2004$cC.2$g1$i2026000134901$lle026$mTesto collocato sul pavimento.$nFondo GISI$og$pE0.00$q-$rl$st  $t0$u0$v0$w0$x0$y.i16007451$z19-04-22
945   $aLE026 cd-rom n. 105$cC.1 cd$g1$i2026000035253$lle026$nFondo GISI$og$pE0.00$q-$rl$s-  $t0$u0$v0$w0$x0$y.i15557029$z21-11-13
945   $aLE026 cd-rom n. 450$cC.2 cd$g1$i2026000134918$lle026$nFondo GISI$og$pE0.00$q-$rl$s-  $t0$u0$v0$w0$x0$y.i16007463$z19-04-22
996   $aAutoCAD 2004$9261079
997   $aUNISALENTO
998   $ale026$b21-11-13$cm$da  $e-$fita$git $h0$i0

LEADER 04405nam  2200637Ia 450 
001 9910830028803321
005 20170815165611.0
010   $a1-283-64508-4
010   $a1-118-34318-2
010   $a1-118-34321-2
010   $a1-118-34319-0
035   $a(CKB)2560000000090073
035   $a(EBL)989209
035   $a(OCoLC)821889223
035   $a(SSID)ssj0000704799
035   $a(PQKBManifestationID)11419960
035   $a(PQKBTitleCode)TC0000704799
035   $a(PQKBWorkID)10719562
035   $a(PQKB)11087907
035   $a(MiAaPQ)EBC989209
035   $a(PPN)187227306
035   $a(EXLCZ)992560000000090073
100   $a20120427d2012      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aDiscovering superconductivity$b[electronic resource] $ean investigative approach /$fGren Ireson
210   $aChichester, West Sussex $cWiley$d2012
215   $a1 online resource (187 p.)
300   $aDescription based upon print version of record.
311   $a1-119-99141-2 
311   $a1-119-99140-4 
320   $aIncludes bibliographical references and index.
327   $aDiscovering Superconductivity; Contents; List of Figures; List of Tables; Preface; Acknowledgements; To the Teacher; To the Student; SECTION I Introduction; 1 Resistivity and Conduction in Metals; 1.1 Introduction; 1.2 Resistivity; 1.3 Conduction in Metals; 1.4 Revisiting Ohm's Law; References; 2 A Brief History of Superconductivity; 2.1 Introduction; 2.2 The Beginning: Kwik Nagenoeg Nul; 2.3 1933 - Perfect Diamagnetism?; 2.4 The London Brothers; 2.5 1957 - The BCS Theory; 2.6 1962 - The Josephson Effect; 2.7 1986 - Bednorz and Mu?ller and Oxide Superconductors
327   $a2.8 2003 - Abrikosov, Ginzburg and Leggett - and the Future2.9 Getting Cold Enough; References; SECTION II Superconductivity; 3 An Explanation of Superconductivity?; 3.1 Transition Temperature; 3.2 Two-Fluid Model; 3.3 Critical Field, Critical Current; 3.4 Schawlow and Devlin; 3.5 The London Equation; 3.6 BCS Theory; 3.6.1 The Isotope Effect; 3.6.2 The Energy Gap; 3.7 An Alternative Approach to the Energy Gap; 3.7.1 Electron-Electron Attraction; References; 4 The Meissner-Ochsenfeld Effect; References; 5 Diamagnetic Effects; 5.1 Diamagnetism, Paramagnetism and Ferromagnetism; References
327   $a6 Persistence of Current6.1 Quinn and Ittner; References; 7 Type I and Type II Superconductors; 7.1 Critical Magnetic Field; References; 8 Flux Pinning; 8.1 Vortex and Flux Lines; 8.2 The Original Abrikosov; References; SECTION III Superconducting Materials; 9 Low-Temperature Superconductors; 10 Organic Superconductors; References; 11 High-Temperature Superconductors; 11.1 Magnesium Diboride; 11.2 Transition Temperature of High-Tc Superconductors; References; SECTION IV Applications; 12 Superconducting Wire; 13 Medical Imaging; 13.1 Magnetic Resonance Imaging (MRI)
327   $a13.2 Magnetoencephalography13.2.1 The Josephson Junction Revisited; 13.2.2 Neuronal Currents; References; 14 CERN and the LHC; References; 15 Maglev Trains; Appendices; A The BCS Theory; B Flux Penetration; C The Josephson Junction and the SQUID; D MRI; Generating the MRI Signal; References; E A Note on Superfluidity; F A Note on Safety; Index
330   $a Superconductivity is a quantum phenomenon that manifests itself in materials showing zero electrical resistance below a characteristic temperature resulting in the potential for an electric current to run continually through such a material without the need for a power source. Such materials are used extensively in medical and power applications, e.g. MRI and NMR machines.   Discovering Superconductivity uses a series of practical and investigative activities, which can be used as tutor demonst
606   $aSuperconductivity$xStudy and teaching (Higher)$xActivity programs
606   $aSuperconductors
615  0$aSuperconductivity$xStudy and teaching (Higher)$xActivity programs.
615  0$aSuperconductors.
676   $a537.6/23076
676   $a537.623076
676   $a621.35
686   $aTEC039000$2bisacsh
700   $aIreson$b Gren$01650536
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910830028803321
996   $aDiscovering superconductivity$94124810
997   $aUNINA