Amplification or cancellation of Fano resonance and quantum confinement induced asymmetries in Raman line-shapes

Saxena, Shailendra K.; Yogi, Priyanka; Mishra, Suryakant; Mohan, Hari; Mishra, Vikash; Warshi, M. Kamal; Roy, Swarup; Mondal, Puspen; Sagdeo, Pankaj R.; Kumar, Rajesh

doi:10.1039/c7cp04836j

Cited by 42 publications

(52 citation statements)

References 53 publications

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“…MACE formation of SiNW arrays on highly boron‐doped c‐Si substrates leads to the narrowing of nanowire diameter and additional nanowire porosity that results in a distortion of the lower wavenumber side of Fano‐resonance line. [ 32,33,35,36 ] Note that in this case, the observed distortions in Raman spectra correspond to theoretical considerations that phonon confinement reveals itself in the structures with a diameter less that 10–20 nm. [ 23–29,31–34 ] We do not observe any maximum red shift within the chosen spectral resolution or a broader half‐width at the lower wavenumber side of the Raman spectra of as‐prepared and thermally annealed SiNWs (Figure 2a) as could be expected for small‐diameter nanowires.…”

Section: Resultssupporting

confidence: 66%

“…Because the Raman line shape can be modified by phonon confinement, [ 22–36 ] one should be scrupulous about the possible impact of phonon confinement to the estimations of the FCC concentration in SiNWs. MACE formation of SiNW arrays on highly boron‐doped c‐Si substrates leads to the narrowing of nanowire diameter and additional nanowire porosity that results in a distortion of the lower wavenumber side of Fano‐resonance line.…”

Section: Resultsmentioning

confidence: 99%

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Effect of annealing temperature on thermo‐diffusional boron doping of silicon nanowire arrays probed by Raman spectroscopy

Efimova

Lipkova

Gonchar

et al. 2020

J Raman Spectroscopy

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Arrays of silicon nanowires (SiNWs) with characteristic transverse nanowire size of the order of 100 nm were fabricated by metal‐assisted chemical etching of monocrystalline silicon wafers followed by thermo‐diffusional doping with boron and studied by means of Raman spectroscopy considering the Fano effect related to the free charge carriers (holes) in SiNWs. The hole concentration of the order of 1020 cm−3 was shown to be achieved for SiNWs annealed at 950–1000°C and the peak intensity of Raman scattering of SiNWs dropped exponentially with the increasing free‐hole concentration. The obtained results can be used for the express diagnostics of the electrical properties of silicon nanostructures for applications in optoelectronics, sensorics, and thermoelectric devices.

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Section: Resultssupporting

confidence: 66%

Section: Resultsmentioning

confidence: 99%

Effect of annealing temperature on thermo‐diffusional boron doping of silicon nanowire arrays probed by Raman spectroscopy

Efimova

Lipkova

Gonchar

et al. 2020

J Raman Spectroscopy

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“…Raman line-shape analysis has been done from a very well-known semiconductor system, Si, where quantum confinement effect and electron-phonon (Fano) interaction have been used as known control perturbations and will be discussed one-by-one for validation. For this purpose, the theoretical Raman line shapes have been generated using the universal perturbation dependent Raman line-shape function developed earlier by Richter et al [43] and later modified by Campbell et al [44,45] and several others [5,6,10,15,[46][47][48][49][50]. The simplified general equation for universal Raman line shape can be represented by Eq.…”

Section: Resultsmentioning

confidence: 99%

“…Mode identification can be done by indexing the Raman peak positions but it may contain lot more information than simple chemical bonds energies which may also be investigated using IR spectroscopy, of course with certain limitations. Beyond the peak position of a Raman peak, the overall line shape of the spectrum is equally important as it may reveal several important physical phenomena taking place at microscopic level like quantum confinement or size effect, electron-phonon effect, fantum effect etc [9][10][11][12][13][14][15][16][17]. Apart from direct evidences, as a consequence of Raman line-shape's sensitivity towards external conditions, perturbations induced by temperature, pressure etc also can be investigated using classical and advanced Raman techniques [18][19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

Brain Tumour Detection and Grading Using Raman Scattering: Analogy from Semiconductors for Solving Biological Problem

Kaushik

Rani

Neeshu

et al. 2020

Advances in Materials and Processing Technologies

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Subtle changes in Raman spectral line shape have been observed from malignant human brain cells and its possibility for being used in detection and grading of Glioma has been explored here. The latter has been developed as a result of the fact that the width of the Raman spectra is more sensitive, as compared to the peak position, to the brain tumours. The perturbations induced by the cell modification, as a consequence of the cancerous growth, may be responsible for the width's variation in the Raman spectrum due to vibrational lifetime alteration enforced at the molecular levels. A consistent cancer-induced effect on the spectral width has been observed for three different brain cells' Raman modes. Raman spectral analysis reveals that for cancerous cells, the FWHM varies up to 35% in comparison with the healthy cells. It has been established how a careful analysis of Raman spectra can help in easy detection of brain tumours. The methodology has been appropriately validated. The proposed model for malignancy detection is based on analogous behaviour of Raman spectral width variation in biological samples with semiconductor nanoparticles.

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“…The peak can change in terms of a shift in its peak position (red-or blue-shift), its spectral width (characterized by FWHM), its symmetry, presence of antiresonance etc. [12][13][14][15] . All such changes provide information about, pressure, stress (or strain), quantum confinement effect, Fano resonance, heating etc [16].…”

Section: Why "Rapid"mentioning

confidence: 99%

Expressing Raman Spectral Details Through Raman Parameter Information Diagram (RAPID)

Kumar¹

2018

Preprint

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A handy diagram with name RAPID (Raman parameter information diagram) is proposed here which can be used for listing spectral parameters associated with a Raman spectrum. It is demonstrated how by drawing simple shapes like lines, triangles etc, it becomes easy to express various nding in a Raman spectrum like red- (or blue-) shift, asymmetry, broadening, antiresonance etc. It will also be explained how by following certain protocols, conveying Raman spectral features becomes easier unambiguously in a pictorial form, proposed to be called as \RAPID" diagram. The proposed diagram will certainly prove to be a good tool in the eld of Raman spectroscopy. It will be noticed that, though it is proposed for Raman spectra, RAPID diagram can be used for representing features of any spectra.

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Amplification or cancellation of Fano resonance and quantum confinement induced asymmetries in Raman line-shapes

Cited by 42 publications

References 53 publications

Effect of annealing temperature on thermo‐diffusional boron doping of silicon nanowire arrays probed by Raman spectroscopy

Effect of annealing temperature on thermo‐diffusional boron doping of silicon nanowire arrays probed by Raman spectroscopy

Brain Tumour Detection and Grading Using Raman Scattering: Analogy from Semiconductors for Solving Biological Problem

Expressing Raman Spectral Details Through Raman Parameter Information Diagram (RAPID)

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