Edith Berger scite author profile

The mechanism of CO2 adsorption on primary, secondary, and bibasic aminosilanes synthetically functionalized in porous SiO2 was qualitatively and quantitatively investigated by a combination of IR spectroscopy, thermogravimetry, and quantum mechanical modeling. The mode of CO2 adsorption depends particularly on the nature of the amine group and the spacing between the aminosilanes. Primary amines bonded CO2 preferentially through the formation of intermolecular ammonium carbamates, whereas CO2 was predominantly stabilized as carbamic acid, when interacting with secondary amines. Ammonium carbamate formation requires the transfer of the carbamic acid proton to a second primary amine group to form the ammonium ion and hence two (primary) amine groups are required to bind one CO2 molecule. The higher base strength of secondary amines enables the stabilization of carbamic acid, which is thereby hindered to interact further with nearby amine functions, because their association with Si-OH groups (either protonation or hydrogen bonding) does not allow further stabilization of carbamic acid as carbamate. Steric hindrance of the formation of intermolecular ammonium carbamates leads to higher uptake capacities for secondary amines functionalized in porous SiO2 at higher amine densities. In aminosilanes possessing a primary and a secondary amine group, the secondary amine group tends to be protonated by Si-OH groups and therefore does not substantially interact with CO2.

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Conformational specificity of chymotrypsin toward proline-containing substrates

Fischer

Bang

Berger

et al. 1984

Biochimica et Biophysica Acta (BBA) - Protein Structure and Mol

153

111

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In Situ Monitoring the Uptake of Moisture into Hybrid Perovskite Thin Films

Schlipf

Bießmann

Oesinghaus

et al. 2018

J. Phys. Chem. Lett.

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Solution-processed hybrid perovskites are of great interest for use in photovoltaics. However, polycrystalline perovskite thin films show strong degradation in humid atmospheres, which poses an important challenge for large-scale market introduction. With in situ grazing incidence neutron scattering (GISANS) we analyzed water content, degradation products, and morphological changes during prolonged exposure to several humidity levels. In high humidity, the formation of metastable hydrate phases is accompanied by domain swelling, which transforms the faceted crystals to a round-washed, pebble-like form. The films incorporate much more water than is integrated into the hydrates, with smaller crystals being more affected, making the degradation strongly dependent on film morphology. Even at low humidity, water is adsorbed on the crystal surfaces without the formation of crystalline degradation products. Thus, although production in an ambient atmosphere is of interest for industrial production it might lead to long-term degradation without appropriate countermeasures like postproduction drying below 30% RH.

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Kinetic β‐deuterium isotope effects suggest a covalent mechanism for the protein folding enzyme peptidylprolyl cis/trans‐isomerase

1989

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The cis/trans interconversion of Glt‐Ala‐Ala‐Pro‐Phe‐4‐nitroanilide and Glt‐Ala‐Gly‐Pro‐Phe‐4‐nitroanilide was studied both enzymatically and nonenzymatically by measuring kinetic β‐deuterium isotope effects. The hydrogen atom at the α‐carbon atom of the Xaa residue within the Xaa‐Pro moiety was substituted by deuterium. In the nonenzymatic case the transition state of rotation is reflected by k H/k D > 1. When catalysed by 17 kDa PPIase the same bond rotation is characterized by k H/k D < 1. This suggests a covalent mechanism of catalysis which involves an approximately tetravalent carbon of the prolyl imidic bond for the transition state of reaction.

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Kutikuläre Transpiration und Trockenresistenz isolierter Blätter und Sprosse

Pisek¹,

Berger²

1938

Planta

102

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Edith Berger

Role of Amine Functionality for CO₂ Chemisorption on Silica

Conformational specificity of chymotrypsin toward proline-containing substrates

In Situ Monitoring the Uptake of Moisture into Hybrid Perovskite Thin Films

Kinetic β‐deuterium isotope effects suggest a covalent mechanism for the protein folding enzyme peptidylprolyl cis/trans‐isomerase

Kutikuläre Transpiration und Trockenresistenz isolierter Blätter und Sprosse

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Edith Berger

Role of Amine Functionality for CO2 Chemisorption on Silica

Conformational specificity of chymotrypsin toward proline-containing substrates

In Situ Monitoring the Uptake of Moisture into Hybrid Perovskite Thin Films

Kinetic β‐deuterium isotope effects suggest a covalent mechanism for the protein folding enzyme peptidylprolyl cis/trans‐isomerase

Kutikuläre Transpiration und Trockenresistenz isolierter Blätter und Sprosse

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Product

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Role of Amine Functionality for CO₂ Chemisorption on Silica