A combined Raman, Fourier transform infrared, and X‐ray diffraction study of thermally treated nesquehonite

Nesquehonite synthesized by mixing MgCl2·6H2O and Na2CO3 at T 25°C, was thermally treated at various temperatures (170°C, 200°C, 295°C, 350°C, and 390°C), based on thermal analysis study of raw nesquehonite. The mineral phases formed at each temperature were studied by means of Raman microspectrosco...

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Published in	Journal of Raman spectroscopy Vol. 51; no. 9; pp. 1445 - 1453
Main Authors	Skliros, Vasilios, Tsakiridis, Petros, Perraki, Maria
Format	Journal Article
Language	English
Published	Bognor Regis Wiley Subscription Services, Inc 01.09.2020
Subjects	bicarbonate ion Crystallization Differential thermal analysis Fourier analysis Fourier transforms FT‐IR Heat treatment Infrared analysis Infrared spectroscopy Magnesium carbonate Magnesium chloride nesquehonite Raman spectroscopy Sodium carbonate Spectrum analysis Temperature Thermal analysis Vibrations X-ray diffraction
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Abstract	Nesquehonite synthesized by mixing MgCl2·6H2O and Na2CO3 at T 25°C, was thermally treated at various temperatures (170°C, 200°C, 295°C, 350°C, and 390°C), based on thermal analysis study of raw nesquehonite. The mineral phases formed at each temperature were studied by means of Raman microspectroscopy, Fourier transform infrared spectroscopy, and X‐ray diffraction. After thermal treatment of raw nesquehonite above 295°C, its dominant Raman peak at 1,100 cm−1, which corresponds to the v1 CO32− antisymmetric stretching vibrations, exhibits broadening and upshift of up to 10 cm−1, whereas the Raman peaks at 707 cm−1, at 770 cm−1, at 1,425 cm−1, and at 1,710 cm−1 disappear, and new Raman peaks arise at 1,282 cm−1 and at 1,386 cm−1. The latter have been attributed to the decomposition of HCO3−, in accordance with the Fourier transform infrared spectroscopy study. According to the differential thermal analysis study, water of crystallization is lost in two steps until 295°C; therefore, the phase studied above this temperature corresponds to Mg (HCO3)(OH). The Raman peak at 3,550 cm−1 assigned to the existence of OH−, exhibits weakening after thermal treatment. Our results corroborate a Mg (HCO3)OH·2H2O nesquehonite formula. Synthetic nesquehonite was thermally treated at different temperatures (170°C, 200°C, 295°C, 350°C and 390°C), based on thermal analysis study. The phases formed at each temperature were studied by means of Raman micro‐spectroscopy combined with Fourier‐Transform Infrared spectroscopy and X‐Ray Diffraction.
AbstractList	Nesquehonite synthesized by mixing MgCl2·6H2O and Na2CO3 at T 25°C, was thermally treated at various temperatures (170°C, 200°C, 295°C, 350°C, and 390°C), based on thermal analysis study of raw nesquehonite. The mineral phases formed at each temperature were studied by means of Raman microspectroscopy, Fourier transform infrared spectroscopy, and X‐ray diffraction. After thermal treatment of raw nesquehonite above 295°C, its dominant Raman peak at 1,100 cm−1, which corresponds to the v1 CO32− antisymmetric stretching vibrations, exhibits broadening and upshift of up to 10 cm−1, whereas the Raman peaks at 707 cm−1, at 770 cm−1, at 1,425 cm−1, and at 1,710 cm−1 disappear, and new Raman peaks arise at 1,282 cm−1 and at 1,386 cm−1. The latter have been attributed to the decomposition of HCO3−, in accordance with the Fourier transform infrared spectroscopy study. According to the differential thermal analysis study, water of crystallization is lost in two steps until 295°C; therefore, the phase studied above this temperature corresponds to Mg (HCO3)(OH). The Raman peak at 3,550 cm−1 assigned to the existence of OH−, exhibits weakening after thermal treatment. Our results corroborate a Mg (HCO3)OH·2H2O nesquehonite formula. Synthetic nesquehonite was thermally treated at different temperatures (170°C, 200°C, 295°C, 350°C and 390°C), based on thermal analysis study. The phases formed at each temperature were studied by means of Raman micro‐spectroscopy combined with Fourier‐Transform Infrared spectroscopy and X‐Ray Diffraction. Nesquehonite synthesized by mixing MgCl2·6H2O and Na2CO3 at T 25°C, was thermally treated at various temperatures (170°C, 200°C, 295°C, 350°C, and 390°C), based on thermal analysis study of raw nesquehonite. The mineral phases formed at each temperature were studied by means of Raman microspectroscopy, Fourier transform infrared spectroscopy, and X‐ray diffraction. After thermal treatment of raw nesquehonite above 295°C, its dominant Raman peak at 1,100 cm−1, which corresponds to the v1 CO32− antisymmetric stretching vibrations, exhibits broadening and upshift of up to 10 cm−1, whereas the Raman peaks at 707 cm−1, at 770 cm−1, at 1,425 cm−1, and at 1,710 cm−1 disappear, and new Raman peaks arise at 1,282 cm−1 and at 1,386 cm−1. The latter have been attributed to the decomposition of HCO3−, in accordance with the Fourier transform infrared spectroscopy study. According to the differential thermal analysis study, water of crystallization is lost in two steps until 295°C; therefore, the phase studied above this temperature corresponds to Mg (HCO3)(OH). The Raman peak at 3,550 cm−1 assigned to the existence of OH−, exhibits weakening after thermal treatment. Our results corroborate a Mg (HCO3)OH·2H2O nesquehonite formula. Abstract Nesquehonite synthesized by mixing MgCl 2 ·6H 2 O and Na 2 CO 3 at T 25°C, was thermally treated at various temperatures (170°C, 200°C, 295°C, 350°C, and 390°C), based on thermal analysis study of raw nesquehonite. The mineral phases formed at each temperature were studied by means of Raman microspectroscopy, Fourier transform infrared spectroscopy, and X‐ray diffraction. After thermal treatment of raw nesquehonite above 295°C, its dominant Raman peak at 1,100 cm −1 , which corresponds to the v 1 CO 3 2− antisymmetric stretching vibrations, exhibits broadening and upshift of up to 10 cm −1 , whereas the Raman peaks at 707 cm −1 , at 770 cm −1 , at 1,425 cm −1 , and at 1,710 cm −1 disappear, and new Raman peaks arise at 1,282 cm −1 and at 1,386 cm −1 . The latter have been attributed to the decomposition of HCO 3 − , in accordance with the Fourier transform infrared spectroscopy study. According to the differential thermal analysis study, water of crystallization is lost in two steps until 295°C; therefore, the phase studied above this temperature corresponds to Mg (HCO 3 )(OH). The Raman peak at 3,550 cm −1 assigned to the existence of OH − , exhibits weakening after thermal treatment. Our results corroborate a Mg (HCO 3 )OH·2H 2 O nesquehonite formula.
Author	Perraki, Maria Skliros, Vasilios Tsakiridis, Petros
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Snippet	Nesquehonite synthesized by mixing MgCl2·6H2O and Na2CO3 at T 25°C, was thermally treated at various temperatures (170°C, 200°C, 295°C, 350°C, and 390°C),... Abstract Nesquehonite synthesized by mixing MgCl 2 ·6H 2 O and Na 2 CO 3 at T 25°C, was thermally treated at various temperatures (170°C, 200°C, 295°C, 350°C,...
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SubjectTerms	bicarbonate ion Crystallization Differential thermal analysis Fourier analysis Fourier transforms FT‐IR Heat treatment Infrared analysis Infrared spectroscopy Magnesium carbonate Magnesium chloride nesquehonite Raman spectroscopy Sodium carbonate Spectrum analysis Temperature Thermal analysis Vibrations X-ray diffraction
Title	A combined Raman, Fourier transform infrared, and X‐ray diffraction study of thermally treated nesquehonite
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