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Formation and dissociation of phosphorylated peptide radical cations.Tautomerization and Dissociation of Molecular Peptide Radical Cations.Novel Cβ-Cγ bond cleavages of tryptophan-containing peptide radical cations.A comparison of the fragmentation pathways of [Cu(II)(Ma)(Mb)]•2+ complexes where Ma and Mb are peptides containing either a tryptophan or a tyrosine residue.Bond dissociation energies of solvated silver(I)-amide complexes: competitive threshold collision-induced dissociations and calculations.Optimization of parameters used in algorithms of ion-mobility calculation for conformational analyses.Mechanistic investigation of phosphate ester bond cleavages of glycylphosphoserinyltryptophan radical cations under low-energy collision-induced dissociation.Threshold collision-induced dissociation measurements using a ring ion guide as the collision cell in a triple-quadrupole mass spectrometer.Conformation switching in gas-phase complexes of histidine with alkaline earth ions.Abundant dipositively charged protonated a2 and a3 ions from diproline and triproline.Kinetics for tautomerizations and dissociations of triglycine radical cations.Structure of the observable histidine radical cation in the gas phase: a captodative alpha-radical ion.Dissociation of the N-C(alpha) bond and competitive formation of the [z(n) - H](+) and [c(n) + 2H](+) product ions in radical peptide ions containing tyrosine and tryptophan: the influence of proton affinities on product formation.Binding energies of the silver ion to alcohols and amides: a theoretical and experimental study.Dissociations of copper(II)-containing complexes of aromatic amino acids: radical cations of tryptophan, tyrosine, and phenylalanine.Dipositively charged protonated a3 and a2 ions: generation by fragmentation of [La(GGG)(CH3CN)2]3+.Hydration Leads to Efficient Reactions of the Carbonate Radical Anion with Hydrogen Chloride in the Gas Phase.Discovery and mechanistic studies of facile N-terminal Cα-C bond cleavages in the dissociation of tyrosine-containing peptide radical cations.Ab initio studies on Al(+)(H(2)O)(n), HAlOH(+)(H(2)O)(n-1), and the size-dependent H(2) elimination reaction.Ab initio studies on the mechanism of the size-dependent hydrogen-loss reaction in Mg+(H2O)n.Reaction mechanisms for size-dependent H loss in Mg+(H2O)n: solvation controlled electron transfer.Electrons Mediate the Gas-Phase Oxidation of Formic Acid with Ozone.Self-Assembly of Binuclear Cu(II)-Histidine Complex for Absolute Configuration and Enantiomeric Excess Determination of Naproxen by Tandem Mass Spectrometry.The elimination of a hydrogen atom in Na(H2O)n.How large is the [Fe(III)(protoporphyrin IX)]+ ion (hemin+) in the gas phase?Kinetics of the reaction of CO3˙-(H2O)n, n = 0, 1, 2, with nitric acid, a key reaction in tropospheric negative ion chemistry.Mechanistic examination of Cβ-Cγ bond cleavages of tryptophan residues during dissociations of molecular peptide radical cations.Arginine-facilitated isomerization: radical-induced dissociation of aliphatic radical cationic glycylarginyl(iso)leucine tripeptides.Reactions of CH3SH and CH3SSCH3 with gas-phase hydrated radical anions (H2O)n(•-), CO2(•-)(H2O)n, and O2(•-)(H2O)n.Charge transfer reactions between gas-phase hydrated electrons, molecular oxygen and carbon dioxide at temperatures of 80–300 KReactivity of Hydrated Monovalent First Row Transition Metal Ions [M(H2O)n]+, M = Cr, Mn, Fe, Co, Ni, Cu, and Zn, n < 50, Toward AcetonitrileCC bond formation between CO2− and allyl alcohol: A mechanistic studyCarboxylation of Methyl Acrylate by Carbon Dioxide Radical Anions in Gas-Phase Water ClustersReduction of Acetonitrile by Hydrated Magnesium Cations Mg+(H2O)n(n≈20-60) in the Gas PhaseHydrated Magnesium Cations Mg+(H2O)n,n≈ 20–60, Exhibit Chemistry of the Hydrated Electron in Reactions with O2and CO2Selective Formic Acid Synthesis from Nanoscale ElectrochemistryReactions of Large Water Cluster Anions with Hydrogen Chloride: Formation of Atomic Hydrogen and Phase Separation in the Gas PhaseAb Initio Molecular Dynamics Studies of Ionic Dissolution and Precipitation of Sodium Chloride and Silver Chloride in Water Clusters, NaCl(H2O)n and AgCl(H2O)n,n = 6, 10, and 14Proton Transfer in Ionic Water ClustersBase-Catalyzed Hydrogen/Deuterium Exchange between Water and Acetonitrile in Anionic Water Clusters
P50
Q36446313-000A8F4A-6251-4017-A2FC-E41FC75C124CQ39398209-C470B32A-EB3E-4964-B720-ACFC1A4BD575Q40620125-D2EB008F-EEED-4148-A424-8286035755EAQ42820518-B2FDC188-3460-482E-BBA6-3CF97B91EAFEQ43025713-3AC9E63B-0E52-4FB1-971C-F7C13842144EQ43205707-9464F912-7AD5-4C48-B74E-B01824E18419Q45060002-224451E0-4780-4993-8C16-D0FC6EC30F57Q45918903-B6CB05F6-2124-40C8-8204-185B9278A969Q45938431-2AE2481E-2B88-40FA-A85F-4AF0661CA9FBQ46093611-FA49520D-53CF-4676-98E2-0CE9BAF856B0Q46103090-30E0CD5C-2CC0-4E1A-B921-9075028779ABQ46251267-A578F06C-CEFB-45AE-98D1-344BF6F5E81FQ46310447-23742499-F1AE-4C22-AD43-2EDE4FCBAACFQ46328016-9D9CEC64-1873-4B8B-910C-AA5BFF9DEBC9Q46345695-0D8131DD-3092-4C77-B8F7-6115235AEFDEQ46347533-1C623DB2-A315-494A-B633-B188E8ACD9E8Q46446637-43AFD0FF-210B-49B7-BEBB-7DC09546F8DEQ46912907-B2512DCF-EC6F-468F-B850-2D41FD91EAA0Q47178539-470D3B5A-07AE-420A-BF52-0C765346EA0CQ47178623-B10D036F-58DD-4247-AD25-F0F7630E27C1Q47389838-07133A6B-A0BD-4066-8872-45976E4A2078Q48055414-26281D6C-B759-4C60-B2EA-1FA174663FB4Q49889594-6EADB61E-4738-4422-8D65-F3EDD82D5E26Q51631635-FDB06056-9748-4706-B3C9-107F35E01C57Q51928161-2C76F54A-1D03-40BF-BF5C-E3036D2E8CEEQ52374251-DADB1293-58DC-424E-BF47-C7407E321DA8Q53162870-5991F67B-9C4E-40A8-AC84-440C069A5197Q53164458-9EC9B37D-503A-4D22-9E82-87D57D234123Q53178585-99EB3C2D-C276-4926-A040-5CD6C42FCD83Q59031218-B1F74F68-DAB5-44C9-866A-BB112C44C048Q59031349-2A4ACFDC-395D-4286-BD9B-9F2D5D70A82BQ59031420-801E9F07-917E-490A-BE1A-96726018DD88Q59031435-D55088DF-C4A6-4340-9AEA-07A5952B9DD9Q59031508-C99570F8-8CF2-4FE7-A16F-B89F46778E39Q59031662-66CA3C86-F234-4212-9A15-FC5E4E26A767Q59031771-13C8A8FD-15FE-4C5D-B860-ECFC9EF9A2BDQ59031960-16EB62B3-5A78-43A2-9829-FFD02D544146Q59031973-5FA8DAFB-EF88-4CA4-A464-D0979BE856C3Q59032004-61BE4AF6-8D57-4831-8DF5-F9AEDD5985D3Q59032120-D951B0D5-DF6E-44F6-8CDE-3F1A4F920831
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Chi-Kit Siu
@ast
Chi-Kit Siu
@en
Chi-Kit Siu
@es
Chi-Kit Siu
@nl
Chi-Kit Siu
@sl
type
label
Chi-Kit Siu
@ast
Chi-Kit Siu
@en
Chi-Kit Siu
@es
Chi-Kit Siu
@nl
Chi-Kit Siu
@sl
prefLabel
Chi-Kit Siu
@ast
Chi-Kit Siu
@en
Chi-Kit Siu
@es
Chi-Kit Siu
@nl
Chi-Kit Siu
@sl
P106
P1153
7006550712
P31
P496
0000-0002-1162-6899