LEADER 00933nam0-22003251i-450- 001 990005487830403321 005 20080428122153.0 035 $a000548783 035 $aFED01000548783 035 $a(Aleph)000548783FED01 035 $a000548783 100 $a19990604d1967----km-y0itay50------ba 101 0 $aita 105 $aa---b---00--- 200 1 $a<>ville Genovesi,$fcatalogo curato da Emmina De Negri, Cesare Fera, Luciano Grossi Bianchi 210 $aGenova$cComune di Genova$d1967 215 $a489 p.$cill.$d27 cm 610 0 $aGenova$aVille 676 $a728 702 1$aDe Negri,$bEmmina 702 1$aFera,$bCesare 702 1$aGrossi Bianchi,$bLuciano 702 1$aPoleggi,$bEnnio$f<1927- > 801 0$aIT$bUNINA$gRICA$2UNIMARC 901 $aBK 912 $a990005487830403321 952 $a728 CATALOGHI 1$bST.ARTE 7497$fFLFBC 959 $aFLFBC 996 $aVille Genovesi$9589963 997 $aUNINA LEADER 05846nam 2200601Ia 450 001 9910780727803321 005 20230721024412.0 010 $a1-282-76063-7 010 $a9786612760631 010 $a1-61583-240-8 010 $a981-283-666-7 035 $a(CKB)2490000000001598 035 $a(StDuBDS)AH24686157 035 $a(SSID)ssj0000332050 035 $a(PQKBManifestationID)11226269 035 $a(PQKBTitleCode)TC0000332050 035 $a(PQKBWorkID)10331613 035 $a(PQKB)11593128 035 $a(MiAaPQ)EBC1681667 035 $a(WSP)00000523 035 $a(Au-PeEL)EBL1681667 035 $a(CaPaEBR)ebr10422055 035 $a(CaONFJC)MIL276063 035 $a(OCoLC)557377059 035 $a(EXLCZ)992490000000001598 100 $a20091228d2009 uy 0 101 0 $aeng 135 $aur||||||||||| 181 $ctxt 182 $cc 183 $acr 200 10$aOptical properties and spectroscopy of nanomaterials$b[electronic resource] /$fJin Zhong Zhang 210 $aHackensack, NJ $cWorld Scientific$dc2009 215 $a1 online resource (xvi, 383 p. ) $cill. (some col.) 300 $aBibliographic Level Mode of Issuance: Monograph 311 $a981-283-665-9 311 $a981-283-664-0 320 $aIncludes bibliographical references and index. 327 $a1. Introduction -- 2. Spectroscopic techniques for studying optical properties of nanomaterials. 2.1. UV-visible electronic absorption spectroscopy. 2.2. Photoluminescence and electroluminescence spectroscopy. 2.3. Infrared (IR) and Raman vibrational spectroscopy. 2.4. Time-resolved optical spectroscopy. 2.5. Nonlinear optical spectroscopy : harmonic generation and up-conversion. 2.6. Single nanoparticle and single molecule spectroscopy. 2.7. Dynamic light scattering (DLS). 2.8. Summary -- 3. Other experimental techniques : electron microscopy and X-ray. 3.1. Microscopy : AFM, STM, SEM and TEM. 3.2. X-ray : XRD, XPS, and XAFS, SAXS. 3.3. Electrochemistry and photoelectrochemistry. 3.4. Nuclear magnetic resonance (NMR) and electron spin resonance (ESR). 3.5. Summary -- 4. Synthesis and fabrication of nanomaterials. 4.1. Solution chemical methods. 4.2. Gas or vapor-based methods of synthesis : CVD, MOCVD and MBE. 4.3. Nanolithography techniques. 4.4. Bioconjugation. 4.5. Toxicity and green chemistry approaches for synthesis. 4.6. Summary -- Optical properties of semiconductor nanomaterials. 5.1. Some basic concepts about semiconductors. 5.2. Energy levels and density of states in reduced dimension systems. 5.3. Electronic structure and electronic properties. 5.4. Optical properties of semiconductor nanomaterials. 5.5. Doped semiconductors : absorption and luminescence. 5.6. Nonlinear optical properties. 5.7. Optical properties of single particles. 5.8. Summary -- 6. Optical properties of metal oxide nanomaterials. 6.1. Optical absorption. 6.2. Optical emission. 6.3. Other optical properties : doped and sensitized metal oxides. 6.4. Nonlinear optical properties : luminescence up-conversion (LUC). 6.5. Summary -- 7. Optical properties of metal nanomaterials. 7.1. Strong absorption and lack of photoemission. 7.2. Surface plasmon resonance (SPR). 7.3. Correlation between structure and SPR : a theoretical perspective. 7.4. Surface enhanced Raman scattering (SERS). 7.5. Summary -- 8. Optical properties of composite nanostructures. 8.1. Inorganic semiconductor-insulator and semiconductor-semiconductor. 8.2. Inorganic metal-insulator. 8.3. Inorganic semiconductor-metal. 8.4. Inorganic-organic (polymer). 8.5. Inorganic-biological materials. 8.6. Summary -- 9. Charge carrier dynamics in nanomaterials. 9.1. Experimental techniques for dynamics studies in nanomaterials. 9.2. Electron and photon relaxation dynamics in metal nanomaterials. 9.3. Charge carrier dynamics in semiconductor nanomaterials. 9.4. Charge carrier dynamics in metal oxide and insulator nanomaterials. 9.5. Photoinduced charge transfer dynamics. 9.6. Summary -- 10. Applications of optical properties of nanomaterials. 10.1. Chemical and biomedical detection, imaging and therapy. 10.2. Energy conversion : PV and PEC. 10.3. Environmental protection : photocatalytic and photochemical reactions. 10.4. Lasers, LEDs, and solid state lighting. 10.5. Optical filters : photonic bandgap materials or photonic crystals. 10.6. Summary. 330 $aOptical properties are among the most fascinating and useful properties of nanomaterials and have been extensively studied using a variety of optical spectroscopic techniques. A basic understanding of the optical properties and related spectroscopic techniques is essential for anyone who is interested in learning about nanomaterials of semiconductors, insulators or metal. This is partly because optical properties are intimately related to other properties and functionalities (e.g. electronic, magnetic, and thermal) that are of fundamental importance to many technological applications, such as energy conversion, chemical analysis, biomedicine, optoelectronics, communication, and radiation detection. Intentionally designed for upper-level undergraduate students and beginning graduate students with some basic knowledge of quantum mechanics, this book provides the first systematic coverage of optical properties and spectroscopic techniques of nanomaterials. 606 $aNanostructured materials$xOptical properties 606 $aNanostructured materials$xSpectra 615 0$aNanostructured materials$xOptical properties. 615 0$aNanostructured materials$xSpectra. 676 $a620.5 700 $aZhang$b Jin Z$01154992 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 906 $aBOOK 912 $a9910780727803321 996 $aOptical properties and spectroscopy of nanomaterials$93758156 997 $aUNINA