ライフサイエンスコーパス: Raman

1 Raman and transmission FTIR spectroscopic techniques hav

2 Raman and X-Ray photoelectron spectroscopy (XPS) reveale

3 Raman has been highlighted as a technique to suit this a

4 Raman mapping has been used here to track "dynamic dopin

5 Raman or Brillouin amplification of a laser beam in plas

6 Raman spectra exhibit clear changes with pH due to chang

7 Raman spectra of each cell type were then analyzed to re

8 Raman spectra relate the electronic transition of this p

9 Raman spectra show lattice softening with increasing siz

10 Raman spectral analysis determined I(D)/I(G) values of 0

11 Raman spectral signatures in the amide I region revealed

12 Raman spectroscopic mapping of the distribution of the c

13 Raman spectroscopy (RS) is an emerging analytical techni

14 Raman spectroscopy analysis shows a low-intensity or abs

15 Raman spectroscopy coupled chemometrics was employed eff

16 Raman spectroscopy data shows two distinct MoS(2) vibrat

17 Raman spectroscopy using aluminum nitride (AlN) optical

18 Raman sulfate peak (~980 cm(-1)) intensity measurements

19 nitoring the change of the OH (~3390 cm(-1)) Raman band area (3350-3550 cm(-1) spectral region) after

20 mple is illustrated on the fusion of real 3D Raman and 4D fluorescence images recorded on cross secti

21 We identified a Raman biomarker from glycogen to distinguish iPSCs from

22 cattering (SRS) microscopy associated with a Raman tag synthesized for real-time visualization and qu

23 rts the measurement and analysis of absolute Raman scattering cross sections spanning the frequency r

24 acetylenes with intrinsic ultrastrong alkyne Raman signals that locate in this region for organelle-t

25 ronment by means of transient absorption and Raman spectroscopies synergistically performed in situ t

26 , particularly operando X-ray absorption and Raman spectroscopy, to study the mechanism of OER on cob

27 Liquid chromatography and Raman spectroscopy (LC-Raman system) were combined and d

28 ystem response for different time delays and Raman pump resonances, we show how detailed properties o

29 by in situ synchrotron X-ray diffraction and Raman studies.

30 asive spectroscopic analyses (i.e., FTIR and Raman spectroscopy) and complimented with pyrolysis-GC-M

31 Infrared and Raman spectroscopies, (31)P and (13)C MAS NMR, N(2) adso

32 catalyst under the same conditions by IR and Raman confirms that the V=O mode has the same frequency

33 The simultaneous IR and Raman microscopy with submicrometer spatial resolution d

34 examine the reported applications of IR and Raman spectroscopies as powerful tools for initial chara

35 among which vibrational spectroscopy (IR and Raman) plays an important role and is indispensable in m

36 , Fourier transform mid-infrared (FT-IR) and Raman spectroscopy combined with chemometrics were inves

37 al spectroscopies, such as infrared (IR) and Raman, have great potential for probing functional group

38 racterized using atomic force microscopy and Raman microspectroscopy.

39 rmed by transmission electron microscopy and Raman signatures.

40 They were characterized by NMR and Raman spectroscopy.

41 Proteomic and Raman spectroscopy analyses reveal highly analogous bioc

42 ystem integrated with an aerosol sampler and Raman spectrometer.

43 ZrC(1-x) structure is analysed using SEM and Raman spectroscopy.

44 as dry powders by ATR-FTIR spectroscopy and Raman spectroscopy.

45 fraction, X-ray absorption spectroscopy, and Raman techniques, we found that the Cu(68)Ag(32) nanowir

46 , on the basis of their X-ray structures and Raman signatures.

47 ransmission electron microscopy (S/TEM), and Raman spectroscopy were combined with first principle ca

48 ded by 3D optical diffraction tomography and Raman spectroscopy, respectively, to propose a label-fre

49 ents in the Raman-silent region (without any Raman enhancer), and the flexible functionalization of t

50 entation of conventional techniques, such as Raman spectroscopy, atomic force microscopy (AFM), and t

51 ts offered by a synthesized aryl-diyne-based Raman tag such as excellent photostability, negligible b

52 However, no significant plasma-based Raman amplification of a laser pulse beyond 0.1 TW has b

53 We also analyze the plasma-based Raman and Brillouin amplification experiments to date, a

54 The polydiacetylene-based Raman probes represent ultrastrong intrinsic Raman imagi

55 nsistent with those obtained with a benchtop Raman spectrometer measurements on leaf-sections under l

56 urrounding native dentine and alveolar bone, Raman microspectroscopy analysis is used.

57 The same object was analysed by Raman and Fourier-transform infrared spectroscopy.

58 Analysis by Raman spectroscopy shows that the tyrosines are pre-orga

59 ions of interest which were then assessed by Raman spectroscopy.

60 Extensive characterization by Raman and X-ray spectroscopy and transmission electron m

61 ectrochemically reduced and characterized by Raman and X-ray photoelectron spectroscopies in addition

62 he modified electrodes were characterized by Raman spectroscopy, attenuated total reflectance Fourier

63 e characterizations and were complemented by Raman spectroscopy and theoretical calculations.

64 ures at programmed positions as confirmed by Raman mapping and hyperspectral photoluminescence imagin

65 m 56 patients were characterized entirely by Raman mapping and confirmed by X-ray scattering.

66 gen containing surface species identified by Raman spectroscopy are unlikely to be active in facilita

67 ndividual BGC823 cancer cell was measured by Raman spectroscopy, then nondestructively isolated out b

68 idation of the graphene layer as observed by Raman.

69 her than the transition pressure obtained by Raman measurements, owing to slow kinetics.

70 ilar beta-sheet structured core, revealed by Raman spectroscopy, limited-proteolysis, and fibril disa

71 entified in the leachate and tire samples by Raman/surface-enhanced Raman spectroscopy and gas chroma

72 his region for organelle-targeting live-cell Raman imaging.

73 synthesis method to correlate characteristic Raman spectroscopy response of MoSe(2) at ca. 242 cm(-1)

74 AD was performed based on the characteristic Raman spectral features of each reporter used in differe

75 We use the leaf-clip Raman sensor for early diagnosis of nitrogen deficiency

76 The portable leaf-clip Raman sensor offers farmers and plant scientists a new p

77 vo measurements using the portable leaf-clip Raman sensor under full-light growth conditions were con

78 dy provides a rationale for employing coarse Raman mapping to substantially reduce measurement time t

79 In this study, coherent Raman scattering microscopy was used to probe de novo in

80 vel method for diagnosing DMD which combines Raman hyperspectroscopic analysis of blood serum with ad

81 By combining Raman spectroscopy with two-dimensional (2D) perturbatio

82 ce Microscopy Infrared (AFM-IR) and confocal Raman microscopy to discover new biomarkers for B. bovis

83 nation of histological staining and confocal Raman spectroscopy on native tissues, as well as peptide

84 ingle infected RBC using AFM-IR and confocal Raman to the detection of the parasite in a cell populat

85 aser scanning microscopy as well as confocal Raman microspectroscopy.

86 tion was unambiguously supported by confocal Raman, fluorescence, and analytical transmission electro

87 udy demonstrates the application of confocal Raman spectroscopic imaging for the comparative bimolecu

88 Here, we report the use of confocal Raman spectroscopic imaging for the visualization and mu

89 ed to what can be achieved with conventional Raman methods.

90 To this end, we coupled Raman spectroscopy and paper spray ionization mass spect

91 first conceptual demonstration using a deep Raman-based architecture, which can be used noninvasivel

92 discusses SORS and related variants of deep Raman spectroscopy such as transmission Raman spectrosco

93 ceptually demonstrate the capability of deep Raman spectroscopy to noninvasively monitor changes in t

94 Here we demonstrate Raman image-activated cell sorting by directly probing c

95 that will finally open the door to efficient Raman and Brillouin amplification to petawatt powers and

96 We employed Raman tweezers to analyze the phage-host interaction of

97 vantages of real-time detection and enhanced Raman signal intensity, the AlN waveguides provided a se

98 odes (WGMs) contained in the cavity-enhanced Raman spectra.

99 M analysis of the stimulated cavity-enhanced Raman spectra.

100 Here, we present fiber-enhanced Raman spectroscopy (FERS) of headspace gases as an alter

101 we observe surface polariton field enhanced Raman responses at the interface of ZnO microspheres.

102 trochemical (EC) biosensor, surface enhanced Raman scattering (SERS)-based biosensor, field-effect tr

103 A rapid Surface Enhanced Raman Spectroscopy (SERS) method to detect SO(2) in wine

104 cations, plasmonic devices, Surface-Enhanced Raman Scattering (SERS) and biological applications.

105 d-wide by researchers using surface-enhanced Raman scattering (SERS) can differ significantly.

106 and chemical specificity of surface-enhanced Raman scattering (SERS) for online detection of metaboli

107 have been developed as the surface-enhanced Raman scattering (SERS) probes for sensing transduction;

108 Surface-enhanced Raman scattering (SERS) spectroscopy offers the unique p

109 d label-free detection, via surface-enhanced Raman scattering (SERS), of picomolar concentrations of

110 is study, we fabricated the surface-enhanced Raman scattering (SERS)-based molecular sensors for dete

111 A surface-enhanced Raman scattering-chiral anisotropy (SERS-ChA) effect is

112 i-/ferrocyanide ions inside surface-enhanced Raman spectroscopy (SERS) active hot spots associated wi

113 Surface-enhanced Raman spectroscopy (SERS) is a powerful tool for vibrati

114 An optofluidic, surface-enhanced Raman spectroscopy (SERS) platform was developed to dete

115 electrochemically assisted surface-enhanced Raman spectroscopy (SERS) platform with the capability t

116 The use of surface-enhanced Raman spectroscopy (SERS) to determine spectral markers

117 e plasmonic nanostructures, surface-enhanced Raman spectroscopy (SERS), and polymerase chain reaction

118 ied using pH nanoprobes and surface-enhanced Raman spectroscopy (SERS).

119 RF) with minimally invasive surface-enhanced Raman spectroscopy (SERS).

120 e and tire samples by Raman/surface-enhanced Raman spectroscopy and gas chromatography with mass spec

121 emical reactions by in situ surface-enhanced Raman spectroscopy.

122 ore the utility of surface- and tip-enhanced Raman scattering to monitor individual bond-dissociation

123 We also showed that tip-enhanced Raman spectroscopy (TERS) could be used to reveal protei

124 ive biospectroscopic technique, for example, Raman spectroscopy, for assessing endoscopic disease sev

125 ion for these problems is Shifted Excitation Raman Difference Spectroscopy (SERDS), in which a tunabl

126 In earlier TERS experiments, Raman modes with components parallel to the tip were stu

127 We develop a continuous-flow Raman electrochemical cell that enables the first experi

128 We therefore demonstrate the capability for Raman spectroscopy to be used as an analytical tool to m

129 inelastically scattered visible photons for Raman spectra.

130 fiber optic reflectance spectroscopy (FORS), Raman spectroscopy, multispectral imaging (MSI), and mac

131 s of individual neutrophils using label-free Raman spectroscopic imaging.

132 Se(2) crystals is confirmed by low-frequency Raman spectroscopy, scanning transmission electron micro

133 The FT-IR and FT-Raman band characteristics for guar gum, lecithin, and m

134 ysis of vibrational spectroscopy data (FTIR, Raman and near-IR) highlighting a series of critical ste

135 Furthermore, Raman spectroscopy results revealed that the 9th-week GB

136 Indeed, most imaging systems, e.g., Raman, IR, MS, etc., allow acquisition of 3D images, wit

137 FLIm-guided Raman imaging could rapidly identify degrees of cross-li

138 In this work, a handheld Raman spectrometer was used to detect chocolate bloom.

139 The 1064 nm laser beam of the handheld Raman instrument was used to partially remove the fat bl

140 Here, Raman spectroscopy as a nondestructive technique providi

141 clear based on the evidence provided herein Raman spectroscopy in combination with machine learning

142 We provide a proof-of-concept to show how Raman spectroscopy can be used to identify the types of

143 ay diffraction, X-ray tomographical imaging, Raman and infrared spectroscopies, confocal microscopy,

144 ribution function), spectroscopy (impedance, Raman, NMR and INS), and ab initio simulations aimed at

145 There were significant differences in Raman features corresponding to the phosphate and carbon

146 Drastic improvements in Raman efficiencies are consistently achieved, with (sing

147 to absorption spectroscopy but also includes Raman, photoluminescence, or fluorescence spectroscopy.

148 d) for lab-on-chip applications of Infrared, Raman and fluorescence spectroscopic analysis.

149 endogenous reporter for pDNA intercalation, Raman imaging revealed that proteins inside cells facili

150 Raman probes represent ultrastrong intrinsic Raman imaging agents in the Raman-silent region (without

151 (D(2)O) with Raman-stable isotope labeling (Raman-D(2)O), we evaluated the reliability of the quanti

152 id chromatography and Raman spectroscopy (LC-Raman system) were combined and developed with the aid o

153 The LC-Raman system enabled the online acquisition of the nonre

154 The problem of low Raman scattering was overcome by trapping particles with

155 hermal decomposition temperature and a lower Raman peak intensity.

156 Here, we report a magneto-Raman spectroscopy study on multilayered CrI(3), focusin

157 Here, we introduce time-resolved two-magnon Raman scattering as a real time probe of magnetic correl

158 pression, nano-computed tomography and micro-Raman spectroscopy.

159 Both micro-Raman and micro-UV-vis spectroscopy can be used to deter

160 representative areas of the filter by micro-Raman spectroscopy will allow proper quantification of m

161 an atomic force microscope, conducted micro-Raman analysis, and performed leakage tests and in situ

162 ly designed single-whole-cell confocal micro-Raman spectroscopy, quantitative measurement of lipid an

163 Finally, micro-Raman spectroscopy was used for the first time in comple

164 on, confocal), spectroscopy (infrared, micro-Raman), mass spectrometry and elemental analysis techniq

165 Longitudinal acoustic mode Raman spectroscopy provides a complementary measurement

166 By monitoring Raman-scattered light from a single-trapped liposome, th

167 lytical way including morphology monitoring, Raman identification, and transcriptomic profiling.

168 n the polymer structure, as determined by mu-Raman spectroscopy.

169 Therefore, mu-Raman, mu-FTIR, and pyr-GC/MS were further tested for th

170 This contribution utilizes multidimensional Raman spectroscopic data to generate a predictive model

171 To solve this problem, gold nanostar@Raman reporter@silica-sandwiched nanoparticles have been

172 signments are confirmed by CP/MAS (13)C NMR, Raman, and XPS spectroscopy.

173 eworks is confirmed by a combination of NMR, Raman, and energy-dispersive X-ray (EDX) spectroscopies.

174 The nonresonance Raman experiment provides the molecular specificity to L

175 d the online acquisition of the nonresonance Raman spectrum of LC eluates.

176 ured Au films (CNAFs) equipped in the normal Raman scattering Spectrometer.

177 The observed Raman spectra reveal anisotropic lattice vibrations unde

178 It was not possible to obtain Raman spectra of dark chocolate due to the presence of f

179 ls in serum based on the previously obtained Raman spectral data.

180 These analyses establish the ability of Raman spectroscopy to estimate the ensemble of secondary

181 tivariate curve resolution (MCR) analysis of Raman spectra can be utilized to determine speciation as

182 This study investigates the applicability of Raman to detect Post-Translational Modifications (PTMs)

183 Our results support the application of Raman spectroscopy in discerning intramolecular (ssRNA a

184 odels that developed based on data fusion of Raman and FT-IR spectral features obtained the second be

185 ular mutations through the interpretation of Raman fingerprints.

186 , we created an application-based library of Raman spectroscopy parameters specific to microplastics

187 Thus, the potential of Raman spectroscopy as a technique for determining adulte

188 Our results demonstrate the potential of Raman spectroscopy for the development of characterizati

189 inciples simulations, to determine ratios of Raman scattering cross-sections of aqueous species under

190 The overall results of Raman spectroscopy with 1D-CNN as a classification and r

191 By exploiting the sensitivity of Raman spectra to the structural configuration, we invest

192 These results demonstrate the sensitivity of Raman spectroscopy using LDA to characterize and disting

193 the inherently high molecular specificity of Raman spectroscopy, this has therefore opened up entirel

194 s study, we investigate the potential use of Raman spectroscopy (RS) as a label-free, non-invasive an

195 We investigated the use of Raman spectroscopy, a nondestructive analytical method t

196 The versatility of Raman gas spectroscopy could moreover help us to elucida

197 o-SORS and surface enhanced spatially offset Raman spectroscopy (SESORS), and reviews the progress ma

198 alysis based on fluorescence lifetime and on Raman spectra discriminated between GA-ARBP and untreate

199 o develop a noninvasive technology, based on Raman spectroscopy, for continuous monitoring of pH and

200 The trained models were then tested on Raman spectra from 2 independent institutions, reaching

201 subsequent chemical identification by online Raman microspectroscopy (RM).

202 und an extraordinarily large magneto-optical Raman effect from an A(1g) phonon mode due to the emerge

203 This study aims to optimize Raman spectral imaging for the identification of micropl

204 e device functioning and (2) by carrying out Raman mapping from a device in custom-designed thin-film

205 We performed Raman spectroscopy under pressure on this porous composi

206 roadband SRS with femtosecond and picosecond Raman pump pulses at 488 nm.

207 Polarized Raman measurements of single Si(2)Te(3) nanoplates at di

208 cal anisotropy is demonstrated via polarized Raman spectroscopy and second-harmonic generation maps o

209 We envision that a portable Raman instrument could be combined with the capillary-tu

210 hole blood with the assistance of a portable Raman reader, achieving a limit of detection of 1.0 ng m

211 This proof-of-concept study presents Raman hyperspectroscopic analysis of blood serum as an e

212 es using single-cell stable isotope probing, Raman-activated cell sorting and mini-metagenomics.

213 r different methods are evaluated using PSI, Raman spectroscopy, and AFM.

214 s, is proven through D/H NMR quantification, Raman spectroscopy, and elastic recoil detection analysi

215 Quantitative Raman susceptibility spectra of the domains are provided

216 ssion electron microscopy and angle-resolved Raman spectroscopy.

217 EPR and resonance Raman spectroscopy did not detect the proposed [Ru(V)=O]

218 immobilized state are addressed by resonance Raman (RR) and surface enhanced RR (SERR) spectroscopy,

219 mined by UV-visible absorption/CD, resonance Raman and EPR spectroscopy, and analytical studies.

220 donor retinas mapped with confocal resonance Raman microscopy.

221 e vibrational spectroscopy (NRVS), resonance Raman (RR) spectroscopy and infrared (IR) spectroscopy,

222 ircular dichroism, and ultraviolet resonance Raman spectroscopy to confirm the spontaneous folding of

223 ution is unequivocally evidenced by scanning Raman spectroscopy (SRS) and scanning electron microscop

224 In situ Raman spectroscopy and molecular dynamics simulations re

225 ay absorption spectroscopy (XAS) and in situ Raman spectroscopy, we reveal that the MOFs are stable u

226 ffects on select architectures using in-situ Raman spectroscopy.

227 annel distortions resulting from the soliton Raman self-frequency shift.

228 These changes correlated with specific Raman signals from the walls, indicating changes in lign

229 Specifically, Raman spectroscopy combined with chemometric analysis ca

230 udy, we have utilized label-free spontaneous Raman spectroscopy to understand the structural differen

231 ion concentration ratio from the spontaneous Raman spectra, and the total solute concentration from t

232 solvents and were measured using spontaneous Raman scattering with narrowband continuous wave or nano

233 sensitivity than inherently weak spontaneous Raman scattering by exciting localized surface plasmon r

234 which is best suited for in situ solid-state Raman spectroelectrochemistry.

235 In a first step, Raman spectra of aqueous solutions are evaluated for the

236 anti-Stokes Raman scattering and stimulated Raman scattering modalities.

237 nted time-resolved electronic and stimulated Raman spectroscopies to reveal two hidden species of an

238 h Raman spectroscopy, followed by stimulated Raman scattering (SRS) microscopy and transcriptomics an

239 We achieve high quality live-cell stimulated Raman scattering imaging on the basis of modified PDDA.

240 essful application of femtosecond stimulated Raman spectroscopy (FSRS) to a multichromophoric biologi

241 nique vibrational signatures from stimulated Raman spectroscopy.

242 port the utility of hyperspectral stimulated Raman scattering (SRS) microscopy associated with a Rama

243 brations via ultrafast multicolor stimulated Raman scattering (SRS) microscopy for cellular phenotypi

244 A new application of stimulated Raman scattering (SRS) uses the benefit of a label-free

245 imaging toolkit that makes use of stimulated Raman scattering microscopy and deep learning-based comp

246 at allows us to excite water with stimulated Raman scattering and hemoglobin with transient absorptio

247 scent reporter mice and coherent anti-Stokes Raman scattering (CARS) imaging of the sciatic nerve, we

248 enhanced resolution via coherent anti-Stokes Raman scattering (FASTER CARS) using tip-enhanced techni

249 ere utilized, featuring coherent anti-Stokes Raman scattering and stimulated Raman scattering modalit

250 Coherent anti-Stokes Raman scattering microscopy was used to statistically qu

251 In this study, Raman spectroscopy was used to determine origins of fats

252 The integration of subcellular Raman spectro-microscopy with lipidomics and transcripto

253 enhancement factor (EF), including suitable Raman reporter/probe molecules, and finally on c) good a

254 selection rules by activating or suppressing Raman activity for the odd-parity phonon mode and the ma

255 t combines chiral discrimination and surface Raman scattering enhancement on chiral nanostructured Au

256 aluated by several spectroscopic techniques (Raman, UV-Vis) and transmission electron microscopy (TEM

257 The Raman spectra for the compounds are diffuse, with a broa

258 the relevant features that differentiate the Raman spectra regarding their pH and concentration of la

259 f the vertical flow method that enhances the Raman signal intensity.

260 guide evanescent wave was used to excite the Raman signals of the test analytes.

261 t-order Taylor expansion, which extracts the Raman bands important for classification.

262 see text] and seed pulse amplitude a for the Raman seed pulse (or [Formula: see text] for Brillouin)

263 strong intrinsic Raman imaging agents in the Raman-silent region (without any Raman enhancer), and th

264 fined environment provides insights into the Raman process at the plasmonic nanocavity, which may be

265 determination of the molecular origin of the Raman response as well as its separation from the backgr

266 mutant populations and demonstrate that the Raman signal from Aspergillus nidulans conidia originate

267 obtained components were consistent with the Raman spectra and elution patterns of the samples, indic

268 Therefore, Raman spectroscopy enables reliable neutrophil phenotypi

269 isolated in time-consuming cultivation, this Raman-based method could potentially be blood-culture in

270 characterization of fungal specimens through Raman spectroscopy may require the determination of the

271 Real-time Raman measurements show these electronic device characte

272 Applied to Raman spectroscopy, this technique was used to collect i

273 g on microplastics and associated changes to Raman spectra, we present a spectral library of plastic

274 This enrichment method coupled to Raman virus identification constitutes an innovative sys

275 deep Raman spectroscopy such as transmission Raman spectroscopy (TRS), micro-SORS and surface enhance

276 ent located in its center using transmission Raman spectroscopy (TRS) by monitoring the change of the

277 ifference between the intensities of the two Raman bands of molybdenum disulfide and graphene oxide,

278 The frequency of the unique, Raman-active stretching vibration of this C2-D probe is

279 Our group recently proposed to use Raman spectroscopy (RS) for confirmatory, noninvasive, a

280 Using Raman microspectroscopy, amorphous calcium carbonate (AC

281 lacolloite (KPb(2)Cl(5)) was confirmed using Raman spectroscopy and electron backscatter diffraction.

282 chloride (GuHCl) has been investigated using Raman spectroscopy in the amide I and III regions.

283 intact red meat samples were measured using Raman spectroscopy, with the acquired spectral data prep

284 complished since 2018 which focuses on using Raman spectroscopy and machine learning to address the n

285 compatible with stable isotope probing using Raman.

286 Here we utilize Raman spectro-microscopy for spatial mapping of metaboli

287 ethods for characterizing microparticles via Raman spectroscopy, we created an application-based libr

288 The whole Raman signature of each microcalcification was then used

289 chemical experiments were in accordance with Raman spectra and surface roughness obtained by atomic f

290 ed engineered cartilage can be assessed with Raman spectroscopy for the development of potency assays

291 antity that can be used, in conjunction with Raman measurements, to predict chemical speciation in aq

292 First, with Raman spectroscopy, followed by stimulated Raman scatter

293 Here, using heavy water (D(2)O) with Raman-stable isotope labeling (Raman-D(2)O), we evaluate

294 Our aim was to identify IDC-P with Raman micro-spectroscopy (RmuS) and machine learning tec

295 ning principal component analysis (PCA) with Raman spectroscopy and circular dichroism (CD) spectrosc

296 single-cell RNA sequencing (scRNA-seq) with Raman optical tweezers (ROT), a label-free single-cell i

297 e simultaneously collect O-PTIR spectra with Raman spectra at a single point for individual particles

298 series of synchrotron-based techniques with Raman spectroscopy and scanning electron microscopy, we

299 n microscopy (TEM), X-ray diffraction (XRD), Raman spectroscopy, Ultraviolet-visible-near infrared (U

300 In recent years, Raman spectroscopy has undergone major advancements in i