Raman vibrational spectral characteristics and quantitative analysis of H 2 up to 400°C and 40 MPa

Self Cite

Raman spectroscopy is an ideal approach for measuring methane concentrations in deep‐sea high‐temperature hydrothermal vent fluids due to its advantages of being nondestructive and noninvasive and not requiring sample pretreatment. However, no application of Raman spectroscopy in the measurement of hydrothermal methane has yet been reported because of the lack of Raman quantitative calibration models for CH4 suitable for hydrothermal fluid detection and available for deep‐sea in situ Raman experiments. In this study, a new Raman quantitative calibration model suitable for hydrothermal fluid detection was established with the linear equation ACH4/AH2normalO = (2.61E‐3 ± 8.52E‐6) × CCH4, where ACH4/AH2normalO is the peak area ratio of CH4 and H2O and CCH4 is the concentration of dissolved CH4 in mmol/kg. In situ Raman spectra of deep‐sea hydrothermal fluids were acquired using an adapted deep‐sea in situ Raman spectrometer, Raman insertion probe (RiP) system, and then the methane concentrations were determined based on the quantitative calibration model for CH4. The concentrations of methane measured by RiP are approximately 1.5–4.0 times higher than those derived from the gas‐tight samples collected simultaneously at the same vents, which indicates that the amount of methane released from the hydrothermal system has probably been underestimated.

Section: Devices and Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

In situ Raman quantitative detection of methane concentrations in deep‐sea high‐temperature hydrothermal vent fluids

Zhang

Luan

et al. 2020

Self Cite

“…Lamadrid and colleagues described a relationship between Raman spectral features and fugacity in mixtures of gases . Li et al reported vibrational Raman spectral characteristics and quantitative analysis of H 2 up to 400°C and 40 MPa . Liu et al studied the unravelling of the decomposition products of phosphine under high pressure where it shows superconducting behaviour .…”

Section: High Pressure Temperature Studies Phase Transitions and Gmentioning

confidence: 99%

“…[189] Li et al reported vibrational Raman spectral characteristics and quantitative analysis of H 2 up to 400°C and 40 MPa. [190] Liu et al studied the unravelling of the decomposition products of phosphine under high pressure where it shows superconducting behaviour. [191] Maczka and co-workers described Raman scattering of pressureinduced phase transitions in perovskite-like acetamidninium manganese formate.…”

Section: Metals Carbons and Other Crystalline Materialsmentioning

confidence: 99%

Recent advances in linear and nonlinear Raman spectroscopy. Part XIII

Nafie

2019

This article is an overview of advances in Raman spectroscopy published in 2018 in the Journal of Raman Spectroscopy (JRS) and, in addition, trends over the past decade across journals that have published papers important to the field of Raman spectroscopy. The trends are based on statistical data of article counts obtained from Clarivate Analytic's Web of Science Core Collection byyear and by subfield of Raman spectroscopy. Coverage is provided for presentations involving Raman spectroscopy at four international conferences this published in JRS in 2018 are highlighted and arragned by topics at the frontier of Raman spectroscopy. Based on these data, presentations, and publications, it is clear that Raman spectroscopy continues as an expanding field of research across a wide range of novel disciplines and applications that provide sensitive photonic information at the molecular level.KEYWORDS advances in Raman spectroscopy, applications of Raman spectroscopy, developments in Raman spectroscopy, review

“…Therefore, the characteristic peak assignment, including peaks locating and peak's intensity measuring, is a simple and effective characteristic‐variables‐extracting method . For a longtime study, peaks assignment derives some other feature extraction methods such as half‐spectrum peak width measurement, peak area measurement, peak‐to‐peak line slope measurement, and peak‐to‐peak height ratio measurement . However, compared with mass spectrometry and infrared spectroscopy, Raman spectroscopy has a shorter history.…”

Section: Introductionmentioning

confidence: 99%

Method for extracting Raman spectra characteristic variables of biological sample based on Hilbert–Huang transform

Zhao

Liu

et al. 2020

Because Raman peaks of the biological sample are superimposed on each other, the use of characteristic peak attribution is limited to some extent. In this study, we show that Hilbert–Huang transform (HHT) provides a Raman spectral feature extracting method, especially for biological samples. First, the empirical mode decomposition algorithm was used to decompose Raman spectra into intrinsic mode functions (IMFs). It is worth noticing that the IMF frequency is single or nearly single, so its further transformation (instantaneous amplitude, instantaneous angle, instantaneous angular frequency, Hilbert spectrum, and Hilbert marginal spectrum) from Hilbert processing is monotonous instead of the raw overlapping. Then, the Hilbert marginal spectrum was selected by one‐way analysis of variance and related with the rice type to establish a partial least squares regression (PLS) model with a 95.00% accuracy. This result is better than those based on characteristic variables screened by PLS, interval PLS, principal component analysis, independent component analysis, successive projections algorithm, haar, db, and coif (85.00%, 90.00%, 82.50%, 77.50%, 90.00%, 92.50%, 80.00%, and 85.00%). These results illustrate that HHT can accurately extract the characteristic variables from biological Raman spectra. The classification accuracy based on HHT is slightly lower than those based on bior 2.4, three‐layer decomposition (97.50%) and sym 5, five‐layer decomposition (97.50%). Significantly, no parameters need to be set such as the wavelet mother function and the decomposition layer in the HHT feature extraction process. This paper provides a HHT method for Raman spectral feature extraction, which is simple and effective.