Ellipsometric Raman Spectroscopy

被引：15

作者：

Basilio, Fernando C. ^{[1
]}

Campana, Patricia T. ^{[2
]}

Therezio, Eralci M. ^{[3
]}

Barbosa Neto, Newton M. ^{[4
]}

Serein-Spirau, Francoise ^{[5
]}

Silva, Raigna A. ^{[1
]}

Oliveira, Osvaldo N., Jr. ^{[6
]}

Marletta, Alexandre ^{[1
]}

机构：

[1] Univ Fed Uberlandia, Inst Phys, BR-38400902 Uberlandia, MG, Brazil

[2] Univ Sao Paulo, Sch Art Sci & Humanities, BR-03828000 Sao Paulo, SP, Brazil

[3] Univ Fed Mato Grosso, Math Dept, BR-78735901 Rondonopolis, MT, Brazil

[4] Fed Univ Para, Inst Exact & Nat Sci, BR-66075110 Belem, Para, Brazil

[5] Ecole Natl Super Chim Montpellier, Inst Charles Gerhardt, F-34296 Montpellier, France

[6] Univ Sao Paulo, Sao Carlos Inst Phys, CP 369, BR-13560970 Sao Carlos, SP, Brazil

来源：

JOURNAL OF PHYSICAL CHEMISTRY C | 2016年 / 120卷 / 43期

基金：

巴西圣保罗研究基金会;

关键词：

OPTICAL-ACTIVITY; CIRCULAR-DICHROISM; BIOMOLECULES; FILMS; TOOL;

D O I：

10.1021/acs.jpcc.6b08809

中图分类号：

O64 [物理化学（理论化学）、化学物理学];

学科分类号：

070304 ; 081704 ;

摘要：

We introduce a new experimental technique referred to as ellipsometric Raman spectroscopy (ERS) to quantify the Raman optical activity (ROA) where ellipsometry is combined with Raman spectroscopy. The Stokes parameters were determined for Raman scattered light using Fourier decomposition in measurements with achromatic optical components in a nine-point method. We tested the methodology with ultrapure water, a well-known chiral alcohol, and a chiral polymer, and we show that ERS allows for studying not only the vicinities of chiral carbons but also molecular species coupled to form chiral structures. Furthermore, in ERS, isotropic and anisotropic scattering contribute equally, thus making it possible to analyze the low-wavenumber region in samples such as the chiral polymer studied here, for which the ROA signal probably arises mainly from isotropic scattering.

引用

页码：25101 / 25109

页数：9

共 50 条

[21] Using Raman spectroscopy to characterize biological materials
Butler, Holly J.
Ashton, Lorna
Bird, Benjamin
Cinque, Gianfelice
Curtis, Kelly
Dorney, Jennifer
Esmonde-White, Karen
Fullwood, Nigel J.
Gardner, Benjamin
Martin-Hirsch, Pierre L.
Walsh, Michael J.
McAinsh, Martin R.
Stone, Nicholas
Martin, Francis L.
NATURE PROTOCOLS, 2016, 11 (04) : 664 - 687
[22] Applications of Raman spectroscopy in ocular biofluid detection
Guo, Zhijun
Ma, Miaoli
Lu, Sichao
Ma, Ying
Yu, Yansuo
Guo, Qianjin
FRONTIERS IN CHEMISTRY, 2024, 12
[23] In situ identification of environmental microorganisms with Raman spectroscopy
Cui, Dongyu
Kong, Lingchao
Wang, Yi
Zhu, Yuanqing
Zhang, Chuanlun
ENVIRONMENTAL SCIENCE AND ECOTECHNOLOGY, 2022, 11
[24] Raman Spectroscopy for the Diagnosis of Intratubular Triamterene Crystallization
Sperati, C. John
Zhang, Chi
Delsante, Marco
Gupta, Rajib
Bagnasco, Serena
Barman, Ishan
KIDNEY INTERNATIONAL REPORTS, 2018, 3 (04): : 997 - 1003
[25] Raman and photoluminescence spectroscopy of zinc tungstate powders
Kalinko, A.
Kuzmin, A.
JOURNAL OF LUMINESCENCE, 2009, 129 (10) : 1144 - 1147
[26] Infrared and Raman chemical imaging and spectroscopy at the nanoscale
Kurouski, Dmitry
Dazzi, Alexandre
Zenobi, Renato
Centrone, Andrea
CHEMICAL SOCIETY REVIEWS, 2020, 49 (11) : 3315 - 3347
[27] Raman spectroscopy characterization of antibody phases in serum
Baker, Audrey E.
Mantz, Amber R.
Chiu, Mark L.
MABS, 2014, 6 (06) : 1509 - 1517
[28] Advances in tissues and cells characterization by Raman micro-spectroscopy, atomic force microscopy, and tip-enhanced Raman spectroscopy
Batista, Andre M.
Foiani, Leticia
Champeau, Mathilde
Martinho, Herculano
JOURNAL OF RAMAN SPECTROSCOPY, 2022, 53 (11) : 1848 - 1860
[29] Probing "microwave effects" using Raman spectroscopy
Schmink, Jason R.
Leadbeater, Nicholas E.
ORGANIC & BIOMOLECULAR CHEMISTRY, 2009, 7 (18) : 3842 - 3846
[30] Assessment of growth phases of the diatom Ditylum brightwellii by FT-IR and Raman spectroscopy
Rueger, Jan
Unger, Nancy
Schie, Iwanw.
Brunner, Eike
Poppa, Juergen
Krafft, Christoph
ALGAL RESEARCH-BIOMASS BIOFUELS AND BIOPRODUCTS, 2016, 19 : 246 - 252

← 1 2 3 4 5 →