Modification of montmorillonite with sodium sulfide for prebiotic chemistry studies: Characterization using spectroscopy methods and X-ray diffractometry

“…For the adenine samples adsorbed on unmodified and modified montmorillonite at pH (2.00, 7.00) the band at 1,603 cm −1 shifted to 1,630 cm −1 (broad band) and in the region 1,672 cm −1 the band shifted to 1,700 cm −1 . Benetoli et al (2008) also obtained similar results with Carneiro et al (2011) and the pH of the solution, NCNAB=net charge of nucleic acid base was based on the pKa as described by Dawson et al (1986) and pH of the solution adenine adsorption on clays and interpreted their results as the interaction of protonated NH 2 + with clays resulting in the weakness of the C=N bond. However, StrašáK (1991) studied the adsorption of adenine on Cu 2+ -montmorillonite and attributed the band at 1,700 cm −1 to C=O stretching due a reaction of Cu 2+ -montmorillonite with adenine forming hypoxanthine.…”

“…Thus, electrostatic forces between unmodified montmorillonite (negative) and nucleic acid bases (positive) increased adsorption at acidic pH. However, for modified montmorillonite the pH pzc was 5.26 (Carneiro et al 2011) and at pH 2.00 both montmorillonite and adenine and cytosine had positive net charge (Table 1). In this case electrostatic force could be not used to explain the higher adsorption of these nucleic acid bases in acidic pH.…”

“…Modification of clay minerals with Na 2 S is a surface phenomena (Carneiro et al 2011) and little effect was observed on the expansion of montmorillonite (Table 2). Average values for d 001 expansion after adsorption of the bases was very small at pH 2.00 and it was not possible to differentiate the adsorption behavior among the bases, at this pH value, from the untreated mineral (Table 2, Fig.…”

“…For all samples 50 mg of M or MM plus 5.0 mL of seawater with nucleic acid bases (720 μg mL −1 ) were mixed for 3 h, after the samples were spun for 15 min at 4,000 rpm and the solids were dried overnight at 60°C line g≈2 obtained for unmodified and modified montmorillonite were 5.63 and 2.68, respectively (Carneiro et al 2011), and after these clays were mixed with artificial seawater in two different pHs, the intensities showed a variation from 2.04 to 3.36 Carneiro et al 2011). The decrease in the intensities of the line g≈2 was due to the extraction of Fe by artificial seawater or Na 2 S solution Carneiro et al 2011). In general, when nucleic acid bases were adsorbed on clays an increase on the intensity of this line was observed (Table 3).…”

“…Then the sample was spun for 15 min at 2,000 rpm and solid was dried in oven at 60°C for 24 h (Carneiro et al 2011).…”

Adsorption of Adenine, Cytosine, Thymine, and Uracil on Sulfide-Modified Montmorillonite: FT-IR, Mössbauer and EPR Spectroscopy and X-Ray Diffractometry Studies

“…For the adenine samples adsorbed on unmodified and modified montmorillonite at pH (2.00, 7.00) the band at 1,603 cm −1 shifted to 1,630 cm −1 (broad band) and in the region 1,672 cm −1 the band shifted to 1,700 cm −1 . Benetoli et al (2008) also obtained similar results with Carneiro et al (2011) and the pH of the solution, NCNAB=net charge of nucleic acid base was based on the pKa as described by Dawson et al (1986) and pH of the solution adenine adsorption on clays and interpreted their results as the interaction of protonated NH 2 + with clays resulting in the weakness of the C=N bond. However, StrašáK (1991) studied the adsorption of adenine on Cu 2+ -montmorillonite and attributed the band at 1,700 cm −1 to C=O stretching due a reaction of Cu 2+ -montmorillonite with adenine forming hypoxanthine.…”

“…Thus, electrostatic forces between unmodified montmorillonite (negative) and nucleic acid bases (positive) increased adsorption at acidic pH. However, for modified montmorillonite the pH pzc was 5.26 (Carneiro et al 2011) and at pH 2.00 both montmorillonite and adenine and cytosine had positive net charge (Table 1). In this case electrostatic force could be not used to explain the higher adsorption of these nucleic acid bases in acidic pH.…”

“…Modification of clay minerals with Na 2 S is a surface phenomena (Carneiro et al 2011) and little effect was observed on the expansion of montmorillonite (Table 2). Average values for d 001 expansion after adsorption of the bases was very small at pH 2.00 and it was not possible to differentiate the adsorption behavior among the bases, at this pH value, from the untreated mineral (Table 2, Fig.…”

“…For all samples 50 mg of M or MM plus 5.0 mL of seawater with nucleic acid bases (720 μg mL −1 ) were mixed for 3 h, after the samples were spun for 15 min at 4,000 rpm and the solids were dried overnight at 60°C line g≈2 obtained for unmodified and modified montmorillonite were 5.63 and 2.68, respectively (Carneiro et al 2011), and after these clays were mixed with artificial seawater in two different pHs, the intensities showed a variation from 2.04 to 3.36 Carneiro et al 2011). The decrease in the intensities of the line g≈2 was due to the extraction of Fe by artificial seawater or Na 2 S solution Carneiro et al 2011). In general, when nucleic acid bases were adsorbed on clays an increase on the intensity of this line was observed (Table 3).…”

“…Then the sample was spun for 15 min at 2,000 rpm and solid was dried in oven at 60°C for 24 h (Carneiro et al 2011).…”

Adsorption of Adenine, Cytosine, Thymine, and Uracil on Sulfide-Modified Montmorillonite: FT-IR, Mössbauer and EPR Spectroscopy and X-Ray Diffractometry Studies

A Prebiotic Chemistry Experiment on the Adsorption of Nucleic Acids Bases onto a Natural Zeolite

Salinity Effects on the Adsorption of Nucleic Acid Compounds on Na-Montmorillonite: a Prebiotic Chemistry Experiment