Fmoc-D-proline hydrate
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Fmoc-D-proline hydrate

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Category
Cyclic Amino Acids
Catalog number
BAT-002064
CAS number
2301169-21-9
Molecular Formula
C20H21NO5
Molecular Weight
355.38
IUPAC Name
(2R)-1-(9H-fluoren-9-ylmethoxycarbonyl)pyrrolidine-2-carboxylic acid;hydrate
Alternative CAS
101555-62-8
Synonyms
Fmoc-D-Pro-OH.H2O; N-(fluorenylmethoxycarbonyl)-D-proline hydrate; (R)-1-(((9H-Fluoren-9-yl)methoxy)carbonyl)pyrrolidine-2-carboxylic acid hydrate; N-[(9H-Fluoren-9-ylmethoxy)carbonyl]-D-proline hydrate; N-Fmoc-D-proline hydrate; 1-[(9H-Fluoren-9-ylmethoxy)carbonyl]-D-proline hydrate; 1,2-Pyrrolidinedicarboxylic acid, 1-(9H-fluoren-9-ylmethyl) ester, (2R)-, hydrate (1:1); (R)-Fmoc-pyrrolidine-2-carboxylic acid hydrate
Related CAS
101555-62-8 (anhydrous)
Appearance
White powder
Purity
≥95%
Storage
Store at 2-8°C
InChI
InChI=1S/C20H19NO4.H2O/c22-19(23)18-10-5-11-21(18)20(24)25-12-17-15-8-3-1-6-13(15)14-7-2-4-9-16(14)17;/h1-4,6-9,17-18H,5,10-12H2,(H,22,23);1H2/t18-;/m1./s1
InChI Key
DJWXUTMZCBWVAA-GMUIIQOCSA-N
Canonical SMILES
C1CC(N(C1)C(=O)OCC2C3=CC=CC=C3C4=CC=CC=C24)C(=O)O.O
1. A Review of the Effect of Porous Media on Gas Hydrate Formation
Lanyun Wang, Mengyue Dou, Yan Wang, Yongliang Xu, Yao Li, Yu Chen, Lingshuang Li ACS Omega. 2022 Sep 19;7(38):33666-33679. doi: 10.1021/acsomega.2c03048. eCollection 2022 Sep 27.
Most gas hydrates on the earth are in sediments and permafrost areas, and porous media are often used industrially as additives to improve gas hydrate formation. For further understanding its exploration and exploitation under natural conditions and its application in industry, it is necessary to study the effect of porous media on hydrate formation. The results show that the stacked porous media affects the phase equilibrium of hydrate formation depending on the competition water activity and large specific surface areas, while integrated porous media, such as metal foam, can transfer the hydration heat rapidly and moderate the hydrate phase equilibrium. A supersaturated metal-organic framework is able to significantly improve gas storage performance and can be used as a new material to promote hydrate formation. However, the critical particle size should be studied further for approaching the best promotion effect. In addition, together with the kinetic accelerators, porous media has a synergistic effect on gas hydrate formation. The carboxyl and hydroxyl groups on the surface of porous media can stabilize hydrate crystals through hydrogen bonding. However, the hydroxyl radicals on the silica surface inhibit the combination of CH4 and free water, making the phase equilibrium conditions more demanding.
2. Clathrate hydrates in nature
Keith C Hester, Peter G Brewer Ann Rev Mar Sci. 2009;1:303-27. doi: 10.1146/annurev.marine.010908.163824.
Scientific knowledge of natural clathrate hydrates has grown enormously over the past decade, with spectacular new findings of large exposures of complex hydrates on the sea floor, the development of new tools for examining the solid phase in situ, significant progress in modeling natural hydrate systems, and the discovery of exotic hydrates associated with sea floor venting of liquid CO2. Major unresolved questions remain about the role of hydrates in response to climate change today, and correlations between the hydrate reservoir of Earth and the stable isotopic evidence of massive hydrate dissociation in the geologic past. The examination of hydrates as a possible energy resource is proceeding apace for the subpermafrost accumulations in the Arctic, but serious questions remain about the viability of marine hydrates as an economic resource. New and energetic explorations by nations such as India and China are quickly uncovering large hydrate findings on their continental shelves.
3. Hydration of Hofmeister ions
Chang Q Sun, Yongli Huang, Xi Zhang Adv Colloid Interface Sci. 2019 Jun;268:1-24. doi: 10.1016/j.cis.2019.03.003. Epub 2019 Mar 20.
Water dissolves salt into ions and then hydrates the ions to form an aqueous solution. Hydration of ions deforms the hydrogen bonding network and triggers the solution with what the pure water never shows such as conductivity, molecular diffusivity, thermal stability, surface stress, solubility, and viscosity, having enormous impact to many branches in biochemistry, chemistry, physics, and energy and environmental industry sectors. However, regulations for the solute-solute-solvent interactions are still open for exploration. From the perspective of the screened ionic polarization and O:H-O bond relaxation, this treatise features the recent progress and a perspective in understanding the hydration dynamics of Hofmeister ions in the typical YI, NaX, ZX2, and NaT salt solutions (Y = Li, Na, K, Rb, Cs; X = F, Cl, Br, I; Z = Mg, Ca, Ba, Sr; T = ClO4, NO3, HSO4, SCN). Phonon spectrometric analysis turned out the f(C) number fraction of bonds transition from the mode of deionized water to the hydrating. The linear f(C) ∝ C form features the invariant hydration volume of small cations that are fully-screened by their hydration H2O dipoles. The nonlinear f(C) ∝ 1 - exp.(-C/C0) form describes that the number insufficiency of the ordered hydrating H2O dipoles partially screens the anions. Molecular anions show stronger yet shorter electric field of dipoles. The screened ionic polarization, inter-solute interaction, and O:H-O bond transition unify the solution conductivity, surface stress, viscosity, and critical energies for phase transition.
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