Thermodynamic control of asymmetric amplification in amino acid catalysis. - Wikidata - awgldk - TriplyDB

Thermodynamic control of asymmetric amplification in amino acid catalysis.

Thermodynamic control of asymmetric amplification in amino acid catalysis.

http://www.wikidata.org/entity/Q47843872

about

The origins of the RNA world Mineral surfaces, geochemical complexities, and the origins of life NMR spectroscopic detection of chirality and enantiopurity in referenced systems without formation of diastereomers On the origin of terrestrial homochirality for nucleosides and amino acids A route to enantiopure RNA precursors from nearly racemic starting materials.Enrichment of the amino acid L-isovaline by aqueous alteration on CI and CM meteorite parent bodies Spontaneous transfer of chirality in an atropisomerically enriched two-axis system.L-amino acids catalyze the formation of an excess of D-glyceraldehyde, and thus of other D sugars, under credible prebiotic conditions.Extended high circular polarization in the Orion massive star forming region: implications for the origin of homochirality in the solar system.Expanding roles for diverse physical phenomena during the origin of life.The origin of biological homochirality.Kinetic isotope effects in asymmetric reactions A cross-chiral RNA polymerase ribozyme Amplification of enantiomeric concentrations under credible prebiotic conditions Supernovae, neutrinos and the chirality of amino acids Quantum mechanical investigations of organocatalysis: mechanisms, reactivities, and selectivities.The direct catalytic asymmetric aldol reaction.Thermodynamic mechanism for solution phase chiral amplification via a lattice model.Solid-state-trapped reactive ammonium carbamate self-derivative salts of prolinamide.Kinetic trapping of metastable amino acid polymorphs.The role of natural selection in the origin of life.Exploring the role of chirality in nucleic acid recognition.Low-loading asymmetric organocatalysis.Processes to separate enantiomers.Enantioselective C-C bond formation as a result of the oriented prochirality of an achiral aldehyde at the single-crystal face upon treatment with a dialkyl zinc vapor.Chiral symmetry breaking in a microscopic model with asymmetric autocatalysis and inhibition.Caution in the Use of Nonlinear Effects as a Mechanistic Tool for Catalytic Enantioconvergent Reactions: Intrinsic Negative Nonlinear Effects in the Absence of Higher-Order Species.The basic reproductive ratio of life.Generation of absolute controlled crystal chirality by the removal of crystal water from achiral crystal of nucleobase cytosine.Chiral Sugars Drive Enantioenrichment in Prebiotic Amino Acid Synthesis.Inhabited or Uninhabited? Pitfalls in the Interpretation of Possible Chemical Signatures of Extraterrestrial Life.Emergence of single-molecular chirality from achiral reactants.Solution-phase racemization in the presence of an enantiopure solid phase.Propagation of biochirality: crossovers and nonclassical crystallization kinetics of aspartic acid in water.Catalysis of glyceraldehyde synthesis by primary or secondary amino acids under prebiotic conditions as a function of pH.Asymmetric amplification in the catalytic enantioselective 1,2-addition of Grignard reagents to enones.Selection of Amino Acid Chirality via Neutrino Interactions with (14)N in Crossed Electric and Magnetic Fields.Absolute asymmetric synthesis in enantioselective autocatalytic reaction networks: theoretical games, speculations on chemical evolution and perhaps a synthetic option."If pigs could fly" chemistry: a tutorial on the principle of microscopic reversibility.Prebiotic synthesis of 2-deoxy-d-ribose from interstellar building blocks promoted by amino esters or amino nitriles.

P2860

Q24634162-BFB55576-C5AE-417D-AD15-52CD888D495F Q28752520-0051842F-5403-4E3D-8C53-16C77A914141 Q30543897-8418B761-9F0F-4F06-BABE-DBA7200FE0CB Q33347176-134424B9-7E6F-4559-A9F1-C2807C40A5B9 Q33352017-11E05481-D3F5-43C9-A36F-7EAF8E3A442E Q33418556-CFDCC1E6-D609-421A-8DF2-3C726F4D474D Q33560825-9E0074B5-B4C1-4BCE-B3D1-1B283BDF4E92 Q33778528-2ED8A449-F2CE-4605-A0D6-40897C0A19DF Q33807115-E8624E74-5C54-4059-8EAC-4FEE9F4AC873 Q34101368-CC0F84AC-4887-4749-BE3A-F6F11221D57C Q34114225-500C7404-E60C-4AD5-BCB2-51069F738000 Q34374723-AAC2C0E3-70CE-466E-9BC8-E56AD03A07B1 Q34550737-0F25C102-7B44-473E-8BF9-0143A58FC6DF Q34561373-62FD37EA-74A8-45DE-B7FF-0E76F8BA3FBB Q35091741-A273ECC3-2E3B-487A-9032-C54C9F54AE70 Q35159601-7E20FB03-8C17-4135-9A4B-DB2678ACB5E0 Q37023350-98E269C7-0440-4389-814D-EACA73E1BAAE Q37340727-BC80532F-04D8-4EB8-8250-EC181ADCD1FF Q37480472-2717CE6C-1808-4542-BFF1-C1247137991B Q37679129-ACAFACA8-C762-4714-BF24-003F364D4168 Q37734958-B4D8FBB4-84AA-458F-A7E6-105CE809641A Q37853120-4B8E1ABF-BB37-4285-AB41-368FCEF27998 Q37968170-79404A59-E5EF-4573-9151-AA07AA11961B Q38180013-B1B373B4-250B-492A-9498-5564585C5772 Q38367566-2C42E61C-A7A5-47D2-8038-9C1A74DE3DBD Q38429363-9E56D874-1B0B-4FBB-8FA0-E0A94E7A638A Q38918773-CE028482-FAE7-4D29-9348-741FA529021B Q39244923-BC7E2B2C-D925-4347-AC3F-DAFDE62EC803 Q39379139-03934D62-F12C-4441-8146-2A9610B85592 Q42290282-F502A2C6-7247-41BA-BDBB-931FCCB713AC Q42362540-93F15FDA-F27B-4E28-8EA1-D77B31972806 Q42574195-C7800106-709C-49CE-BA3F-F5F3F228D220 Q43112394-A01C048D-50F9-4C38-A8B8-2E74BE3C6248 Q45857001-E06B05DF-761D-414B-BBA8-A45B47F9F304 Q45898674-AF844E8B-F0CC-4136-9B25-AF8FFCB79D99 Q46712447-C49DDC01-4ADD-4CEB-96F0-6F7328CA9BD5 Q47327740-0F5BA9F3-237B-4365-8503-928951C5431F Q47831939-CF14B7E8-99C8-48CA-887B-F236C0B6C19B Q47839815-EC10F981-F886-435D-ACDF-6EF614ECF724 Q48105824-A58BDF38-B097-4FCD-A9E7-B748548B0ACD

P2860

Thermodynamic control of asymmetric amplification in amino acid catalysis.

http://www.wikidata.org/entity/Q47843872

description

2006 nî lūn-bûn

@nan

2006年の論文

@ja

2006年学术文章

@wuu

2006年学术文章

@zh-cn

2006年学术文章

@zh-hans

2006年学术文章

@zh-my

2006年学术文章

@zh-sg

2006年學術文章

@yue

2006年學術文章

@zh

2006年學術文章

@zh-hant

name

Thermodynamic control of asymmetric amplification in amino acid catalysis.

@en

Thermodynamic control of asymmetric amplification in amino acid catalysis.

@nl

type

label

Thermodynamic control of asymmetric amplification in amino acid catalysis.

@en

Thermodynamic control of asymmetric amplification in amino acid catalysis.

@nl

prefLabel

Thermodynamic control of asymmetric amplification in amino acid catalysis.

@en

Thermodynamic control of asymmetric amplification in amino acid catalysis.

@nl

P1433

Q47843872-F291B7F7-7174-4482-94B1-2063B2C9D43E

P1476

Q47843872-31E73E92-79E7-4296-BD57-874CA6228084

P2093

Q47843872-1EE9395E-A5F8-4E0E-A853-2373F31419D6

Q47843872-310A5B38-8B8A-4B54-AA75-4B828A43742B

Q47843872-32821088-81D4-43D7-BA47-456C371AB918

Q47843872-5B9F21E8-E769-43B2-9F57-0E84402999E0

Q47843872-717C8744-CEED-4513-B3A2-453555F08CD7

Q47843872-F8922603-DC8B-4D3B-8F07-3E1DD92E22E9

P2860

Q47843872-039E81B1-105A-47B0-B63C-425AB90D9BBF

Q47843872-04195F07-D874-4126-9FD2-B11D8C215EA8

Q47843872-1F92517B-6F7C-4AA7-872F-A30E11AB9DA6

Q47843872-20D456A6-E747-4F7D-839C-3DE281785903

Q47843872-2532B7B2-BDCA-48A7-A889-4C2AFB7670FA

Q47843872-31742E8B-7D07-4BDC-8DB4-F34B9C520957

Q47843872-3AAD2851-C32C-4BFD-9D83-41D5DE18EECA

Q47843872-4BD47027-D573-48A5-8756-B9BE2F705048

Q47843872-591D24DC-D596-4B18-A455-A03654181A4F

Q47843872-5F613802-2017-4046-8511-D8FFD46A3C52

P2888

Q47843872-743E8CB8-605B-4A04-9F83-C80DD7A60504

P304

Q47843872-2FD57B51-0E2B-431A-92AA-93919C6FED46

P31

Q47843872-E785FFF4-1A1F-4DA6-9B66-4BB9EADA60D3

P356

Q47843872-AD4580F1-51CE-4E4F-A7ED-0FDF2D49E6BA

P407

Q47843872-75416F0F-912C-4A45-AF86-B2F0A52E8AA1

P433

Q47843872-B0141542-7FB9-4C1E-B17A-B5867F63348D

P478

Q47843872-E71756C4-792E-4640-92F4-B962D3DAB4AC

P50

Q47843872-81665782-37AD-4D3B-9317-ED6F2EE03106

P577

Q47843872-AEB2ABDD-7298-42C1-861D-2322FB30F55A

P5875

Q47843872-2528CA1D-7433-4CC1-8447-296660010A11

P6179

Q47843872-166A7490-0D19-4FEE-B492-FFDA3EE544E9

P698

Q47843872-27DCD633-F3FD-4E78-8ED5-3300CE2CB2CE

P356

P1433

P1476

Thermodynamic control of asymmetric amplification in amino acid catalysis.

@en

P2093

Alan Armstrong

http://www.w3.org/2001/XMLSchema#string

David H Wells

http://www.w3.org/2001/XMLSchema#string

Donna G Blackmond

http://www.w3.org/2001/XMLSchema#string

Hiroshi Iwamura

http://www.w3.org/2001/XMLSchema#string

Suju P Mathew

http://www.w3.org/2001/XMLSchema#string

Urvish Pandya

http://www.w3.org/2001/XMLSchema#string

P2860

Kinetic and Stereochemical Evidence for the Involvement of Only One Proline Molecule in the Transition States of Proline-Catalyzed Intra- and Intermolecular Aldol Reactions

Origin of organic molecules and biomolecular homochirality.

Kinetic aspects of nonlinear effects in asymmetric catalysis.

Chiral autocatalysis, spontaneous symmetry breaking, and stochastic behavior.

Asymmetric autocatalysis and its implications for the origin of homochirality.

Amplification of enantiomeric excess in a proline-mediated reaction.

Chiral symmetry breaking in sodium chlorate crystallizaton.

Exploratory studies to investigate a linked prebiotic origin of RNA and coded peptides.

Asymmetric autocatalysis: novel structures, novel mechanism?

Serine octamer reactions: indicators of prebiotic relevance.

P2888

P304

621-623

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1038/NATURE04780

http://www.w3.org/2001/XMLSchema#string

P407

P433

7093

http://www.w3.org/2001/XMLSchema#string

P478

441

http://www.w3.org/2001/XMLSchema#string

P50

Martin Klussmann

P577

2006-06-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

7043586

http://www.w3.org/2001/XMLSchema#string

P6179

1036200117

http://www.w3.org/2001/XMLSchema#string

P698

16738656

http://www.w3.org/2001/XMLSchema#string