MAS NMR and EPR study of structural changes in talc and montmorillonite induced by grinding

Abstract: The milling process in the solid-state 2:1 clay minerals, montmorillonite and talc, which have different cation exchange capacities, is reported here. Several instrumental techniques were used to monitor systematically the products formed. The dehydroxylation/amorphization of the montmorillonite and talc structures occurs within 3 and 6 h of milling, respectively. Electron paramagnetic resonance spectra indicated that structural Mn2+ was oxidized more quickly in the montmorillonite structure than in talc, whil… Show more

“…The most intense peak at 1,031 cm −1 is related to the Si‐O stretch in the plane and the shoulder at 1,114 cm −1 shows the stretching vibration of the Si‐O outside the plane . The peaks at 912 and 881 cm −1 are related to Al‐Al‐OH and Al‐Fe‐OH stretching, respectively . The peaks at 790 and 694 cm −1 indicate the presence of impurities in the form of amorphous tridymite and quartz in the structure .…”

“…The FTIR analysis in Figure shows that the range smaller than 1,250 cm −1 is related to the internal and external bonds of the MMT nanoclay. Existing peaks of 536 and 464 cm −1 , respectively, represent the reactions of Al‐O‐Si and Si‐O‐Si decomposition and the peak in 418 cm −1 is due to the bending vibration of Si‐O . The most intense peak at 1,031 cm −1 is related to the Si‐O stretch in the plane and the shoulder at 1,114 cm −1 shows the stretching vibration of the Si‐O outside the plane .…”

“…Existing peaks of 536 and 464 cm −1 , respectively, represent the reactions of Al-O-Si and Si-O-Si decomposition and the peak in 418 cm −1 is due to the bending vibration of Si-O. [20] The most intense peak at 1,031 cm −1 is related to the Si-O stretch in the plane and the shoulder at 1,114 cm −1 shows the stretching vibration of the Si-O outside the plane. [19] The peaks at 912 and 881 cm −1 are related to Al-Al-OH and Al-Fe-OH stretching, respectively.…”

“…[19] The peaks at 912 and 881 cm −1 are related to Al-Al-OH and Al-Fe-OH stretching, respectively. [20,21] The peaks at 790 and 694 cm −1 indicate the presence of impurities in the form of amorphous tridymite and quartz in the structure. [21] In the sample without calcining, the peaks at 3,411 and 3,388 cm −1 demonstrate the hydration stretching -OH and is related to the presence of H 2 O in the structure and the peak available at 3,627 cm −1 is related to the stretching -OH in the structure.…”

“…[21] In the sample without calcining, the peaks at 3,411 and 3,388 cm −1 demonstrate the hydration stretching -OH and is related to the presence of H 2 O in the structure and the peak available at 3,627 cm −1 is related to the stretching -OH in the structure. [20][21][22] To identify the structural characteristics of MMT, Brunauer-Emmett-Teller (BET) analysis was used for nitrogen adsorption and desorption in particles. The volume and distribution of pore size were calculated using the Barrett-Joyner-Halenda (BJH) method.…”

Nanoclay montmorillonite as an adsorbent for CO₂ capture: Experimental and modeling

“…The most intense peak at 1,031 cm −1 is related to the Si‐O stretch in the plane and the shoulder at 1,114 cm −1 shows the stretching vibration of the Si‐O outside the plane . The peaks at 912 and 881 cm −1 are related to Al‐Al‐OH and Al‐Fe‐OH stretching, respectively . The peaks at 790 and 694 cm −1 indicate the presence of impurities in the form of amorphous tridymite and quartz in the structure .…”

“…The FTIR analysis in Figure shows that the range smaller than 1,250 cm −1 is related to the internal and external bonds of the MMT nanoclay. Existing peaks of 536 and 464 cm −1 , respectively, represent the reactions of Al‐O‐Si and Si‐O‐Si decomposition and the peak in 418 cm −1 is due to the bending vibration of Si‐O . The most intense peak at 1,031 cm −1 is related to the Si‐O stretch in the plane and the shoulder at 1,114 cm −1 shows the stretching vibration of the Si‐O outside the plane .…”

“…Existing peaks of 536 and 464 cm −1 , respectively, represent the reactions of Al-O-Si and Si-O-Si decomposition and the peak in 418 cm −1 is due to the bending vibration of Si-O. [20] The most intense peak at 1,031 cm −1 is related to the Si-O stretch in the plane and the shoulder at 1,114 cm −1 shows the stretching vibration of the Si-O outside the plane. [19] The peaks at 912 and 881 cm −1 are related to Al-Al-OH and Al-Fe-OH stretching, respectively.…”

“…[19] The peaks at 912 and 881 cm −1 are related to Al-Al-OH and Al-Fe-OH stretching, respectively. [20,21] The peaks at 790 and 694 cm −1 indicate the presence of impurities in the form of amorphous tridymite and quartz in the structure. [21] In the sample without calcining, the peaks at 3,411 and 3,388 cm −1 demonstrate the hydration stretching -OH and is related to the presence of H 2 O in the structure and the peak available at 3,627 cm −1 is related to the stretching -OH in the structure.…”

“…[21] In the sample without calcining, the peaks at 3,411 and 3,388 cm −1 demonstrate the hydration stretching -OH and is related to the presence of H 2 O in the structure and the peak available at 3,627 cm −1 is related to the stretching -OH in the structure. [20][21][22] To identify the structural characteristics of MMT, Brunauer-Emmett-Teller (BET) analysis was used for nitrogen adsorption and desorption in particles. The volume and distribution of pore size were calculated using the Barrett-Joyner-Halenda (BJH) method.…”

Nanoclay montmorillonite as an adsorbent for CO₂ capture: Experimental and modeling

Metabentonite and metakaolin-based geopolymers/zeolites: relation between kind of clay, calcination temperature and concentration of alkaline activator

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