Statistical approaches in the analysis of in situ thermo‐Raman spectroscopic data for gypsum as a basis for studying dehydration and phase transformations in crystalline hydrates

Pankrushina, Elizaveta A.; Votyakov, S. L.; Shchapova, Yu. V.

doi:10.1002/jrs.6069

Cited by 1 publication

(4 citation statements)

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“…The phenomenon of the vibrational mode shift to the higher wavenumbers during heating is well‐known for crystallohydrates and has been demonstrated by the example of the H 2 O molecule in gypsum 35,88–91 . The shift of the vibrational mode corresponding to the shorter OH bond (0.944 Å) in the H 2 O molecule of gypsum to the higher wavenumbers is due to the weakening of the hydrоgen bond and the strengthening of the OH bond at higher temperatures.…”

Section: Discussionmentioning

confidence: 84%

“…The phenomenon of the vibrational mode shift to the higher wavenumbers during heating is well-known for crystallohydrates and has been demonstrated by the example of the H 2 O molecule in gypsum. 35,[88][89][90][91] The shift of the vibrational mode corresponding to the shorter O H bond (0.944 Å) in the H 2 O molecule of gypsum to the higher wavenumbers is due to the weakening of the hydrоgen bond and the strengthening of the O H bond at higher temperatures. The ν 1 (SO 4 ) vibrational mode in γ-CaSO 4 , which, in contrast to gypsum, lacks of molecular H 2 O and, correspondingly, hydrogen bond, shifts to high wavenumbers (1026 cm À1 ) during heating…”

Section: àmentioning

confidence: 99%

“…is preferable for analyzing the variations of the full spectral profile of Raman-active modes without its peak fitting, providing more accurate diagnosis of spectral changes under the influence of temperature and the determination of critical values. 34,35 The present study is devoted to the investigation of the thermal behavior of modern and archeological human enamel and dentin using in situ temperaturedependent Raman spectroscopy in temperature range 83-873 K in order to assess structural changes both in organic and mineral components of a tooth and their interrelationship. Additionally, the extent of diagenetic alteration of archeological tooth tissues as well as the impact of heat treatment on their morphology and composition was estimated using the scanning electron microscopy (SEM) and energy dispersive X-ray spectrometry (EDS).…”

Section: Introductionmentioning

confidence: 99%

“…In this case, the use of statistical methods of spectral parametrization (such as Pearson's correlation coefficient, autocorrelation function, skewness, kurtosis, etc.) is preferable for analyzing the variations of the full spectral profile of Raman‐active modes without its peak fitting, providing more accurate diagnosis of spectral changes under the influence of temperature and the determination of critical values 34,35 …”

Section: Introductionmentioning

confidence: 99%

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Thermal behavior of modern and archeological enamel and dentin by in situ temperature‐dependent Raman spectroscopy

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Pankrushina

2023

J Raman Spectroscopy

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Teeth and bones are important bioarchives, which can be altered because of diagenesis or burning (cooking, funerary cremations, and fires). Though heating and diagenesis are different processes, an experimental heating of modern bioapatite reproduces in a short time effects similar to diagenetic processes occurring over geological time. The thermal behavior of modern and archeological human enamel and dentin using the in situ thermo-Raman spectroscopy at 83-873 K was investigated to assess the structural changes in organic and mineral components of a tooth and their interrelationship. The ν 1 (PO 4 ) vibrational mode in apatite is the most anharmonic and responsible for the reaction of the structure to external influences. The γiP isobaric Grüneisen parameters for archeological (0.41) and modern (0.24) enamel are different from those for fluor-(0.17) and chlorapatite (0.17), which indicates a stronger reaction of P O bonds in bioapatite PO4 tetrahedra to temperature changes as compared with geologic samples. The anomalies of the thermal dependences of the ν 1 (PO 4 ) peak position and Δcorr PO 4 (T) autocorrelation function are caused by the combined effect of different factors such as breaking of hydroxyl and hydrogen bonds, the loss of adsorbed and structural water, collagen denaturation, organic phase combustion, and removal and relocation of B-and A-type carbonate ions. The thermal (273, 313, 341, and 363 K) and cold ($160 K) denaturation of collagen is reflected in the ν 1 (PO 4 ) and Δcorr PO 4 (T) dependences. The Δcorr PO 4 (T) differences between modern and archeological dentin and enamel are contingent on bioapatite composition (proportions of adsorbed and structural water, hydroxyl and carbonate ions, and trace elements as well as different types of organic matterlowmolecular noncollagen compounds and high-molecular collagen). The results obtained contribute to the knowledge about the thermal transformations of the mineral and organic phases of modern and archeological tooth tissues and allow their structural alterations to be evaluated.

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Section: Discussionmentioning

confidence: 84%