| Record ID | harvard_bibliographic_metadata/ab.bib.14.20150123.full.mrc:138953255:1681 |
| Source | harvard_bibliographic_metadata |
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LEADER: 01681nam a22003131i 4500
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005 20140621020212.0
006 m|||||o||d| ||||||
008 140621s2014 mau| om 00||||eng|d
035 0 $aocn882196519
035 $a(DASH)12269877
040 $aMH$beng$cMH$erda
100 1 $aZhu, Wenqi.
245 10 $aPlasmonics for surface-enhanced Raman scattering: from classical to quantum.
264 0 $c2014.
336 $atext$2rdacontent
337 $acomputer$2rdamedia
338 $aonline resource$2rdacarrier
502 $gThesis$bPh.D.$cHarvard University$d2014
500 $aKeywords: Nano-optics, Plasmonics, Quantum optics, Sruface-enhanced Raman scattering.
520 3 $aMetallic nanostructures that employ localized surface plasmon resonances to capture or radiate electromagnetic waves at optical frequencies are termed "plasmonic optical antennas". These structures enhance light-matter interactions in an efficient manner, enabling unique linear and nonlinear optical applications. One such application is surface-enhanced Raman scattering (SERS), which employs plasmonic antennas to enhance Raman cross-section of molecules by orders of magnitude. SERS has attracted a significant amount of research attention since it enables molecules to be identified through their characteristic vibrational spectra, even at the single molecule level.
653 00 $aEngineering
653 00 $aNanotechnology
653 00 $aOptics
720 1 $aCrozier, Kenneth B.,$edissertation advisor.
720 1 $aCapasso, Federico,$edissertation committee member.
720 1 $aGolovchenko, Jene A.,$edissertation committee member.
988 $a20140621
906 $0MH