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1 se ions react like typical diradicals (e.g., H atom abstractions).
2 th the aliphatic C-H bonds of amino acids by H atom abstraction.
3 ,6-tetramethylpiperidin-1-ol derivatives via H atom abstraction.
4 idate radicals, allowing their first use for H atom abstraction.
5 action with H atom donors proceed via direct H atom abstraction.
6 ze remarkably diverse reactions initiated by H-atom abstraction.
7 do unit contributes to the driving force for H-atom abstraction.
8 ilic substrate PPh3 but is not activated for H-atom abstraction.
9 te can direct the 5'-dAdo* toward productive H-atom abstraction.
10 e corresponding Co-imine complexes via alpha-H-atom abstraction.
11 iminyl radical was too slow to compete with H-atom abstraction.
12 ither retro-Bergman ring opening or external H-atom abstraction.
13 rmodynamically and kinetically competent for H-atom abstraction.
14 s 6 and 7 that also come from intermolecular H-atom abstraction.
15 C-C bond constructions, dehalogenations, and H-atom abstractions.
17 is enzyme initiates its reaction by C(alpha) H-atom abstraction and is able to catalyze the formation
18 zed in the presence of this cluster both via H-atom abstraction and oxygenation with approximately 50
19 e enantioselectivity is dictated by both the H-atom abstraction and radical recombination steps due t
20 uted alpha-ketoamides proceed by competitive H-atom abstraction and sequential SET-desilylation pathw
21 tion that consists of enantiodifferentiative H-atom abstraction and stereoretentive radical substitut
22 0, which were all formed from intramolecular H-atom abstraction and trapping of the corresponding bir
24 de reactions such as alpha-deprotonation and H atom abstraction, and to facilitate enantioselective h
27 in k(cat) (approximately 3000-fold) support H-atom abstraction as the relevant substrate-activation
30 I, an Fe(IV)-Fe(IV) complex, followed by the H-atom abstraction at the transition state III leading t
31 ggest that the reaction proceeds through 1,5-H atom abstraction by a hydroxyl radical generated with
32 approximately 7) and strongly suggests that H atom abstraction by the peroxyl radical occurs with su
33 l to aldehyde equilibration involving formyl H-atom abstraction by a TEDA(2+) radical dication, decar
34 rimental and theoretical evidence for direct H-atom abstraction by ABLM and proposes an attractive me
35 fined by the NRVS data, show that the direct H-atom abstraction by ABLM is thermodynamically favored
37 proposed mechanism for LO catalysis involves H-atom abstraction by an FeIII-OH- site, best described
40 ic isotope effect (KIE) = 6, consistent with H-atom abstraction by S being the rate-determining step.
41 ce that bifurcation of radical rebound after H-atom abstraction can be driven both by the ability of
43 f 4-methyl-N-hydroxyphthalimide (4-Me-NHPI), H-atom abstraction competes with self-decomposition in t
44 spectra of isoleucine and leucine show that H-atom abstraction distal to the alpha-carbon occurs pre
45 step of all these processes, intramolecular H-atom abstraction efficiently intercepts the p-benzyne
48 om N(2) extrusion, which mediates a proximal H-atom abstraction followed by a rapid C-O bond forming
50 [k(H)/k(D) = 38.4(1)], suggesting a stepwise H-atom abstraction followed by radical recombination.
51 o produce nitrocatechols, one (equivalent to H atom abstraction) following fast electron transfer fro
52 Fe(III)-OOH is found to be more effective in H-atom abstraction for strong C-H bonds, while the highe
53 ion that Fe(III)-O2(-) species can carry out H atom abstraction from a C-H bond to initiate the 4-ele
56 tion, there is a roughly 85:1 preference for H atom abstraction from C6 versus C7; however, this inve
62 h of these reactions are expected to involve H atom abstraction from each of two adjacent carbon cent
63 single spectrum permits the relative rate of H atom abstraction from each position to be determined.
64 as a demonstration of highly chemoselective H atom abstraction from electron-rich and relatively wea
65 )OOH)](2+); this is further substantiated by H atom abstraction from O-H substrates by [Cu(II)(2)(BPM
66 vity consistent with a minor contribution of H atom abstraction from the -OCH3 group to the overall r
67 ructural basis for direct and stereospecific H atom abstraction from the buried G(734) of pyruvate fo
68 enerate a Cu(II)-superoxo species capable of H atom abstraction from the peptidyl substrate, followed
69 n-and that homolysis of SAM concomitant with H atom abstraction from the substrate is readily reversi
70 rrous intermediate, formed by O(2)-activated H atom abstraction from the substrate, can exploit diffe
71 iperidin-1-yloxidanyl) resulted in immediate H- atom abstraction from the benzylic position of the ch
73 s significantly stronger than the C7-H bond, H-atom abstraction from C4 is facilitated by H-bond form
74 coupled electron transfer), followed by (b) H-atom abstraction from LH by the Ag-coordinated F atom.
75 fferent NHC-boryl radicals were generated by H-atom abstraction from NHC-ligated trihydroborates.
76 studies indicate that C-H amidation involves H-atom abstraction from R-H substrates by nitrene interm
78 dition to the aminoxyl moiety of 4-O-TPO and H-atom abstraction from the 2- or 6-methyl groups or fro
79 osphoglycolate termini that are derived from H-atom abstraction from the 4'-position of the deoxyribo
83 roxyl radical to the double bond followed by H-atom abstraction from the intermediate by another equi
85 arrier of the initial (and rate-determining) H-atom abstraction from the stearoyl substrate as compar
86 orts the conclusion that cleavage occurs via H-atom abstraction from the sugar moieties, consistent w
89 IV)-oxo core remains highly reactive in both H atom abstraction (HAA) and O atom transfer (OAT) react
91 bound and dissociation mechanisms) following H-atom abstraction (HAA) from a substrate C-H bond by hi
92 isotope effect (KIE = 31.9 +/- 1.0) suggests H-atom abstraction (HAA) is the rate-determining step, i
93 ctive oxygen-centered radical 2b undergoes a H-atom abstraction (HAA) reaction with 1,4-cyclohexadien
94 N]Ni horizontal lineNAd (1), which undergoes H-atom abstraction (HAA) reactions with benzylic substra
95 er decay of [((Tr) L)Co(NC(6) F(5) )](2) via H-atom abstraction (HAA) reveals saturation kinetic beha
97 cal rebound hydroxylation at the site of the H-atom abstraction (HAA); however, recent reports have s
99 In this work we probed the specific role of H atom abstraction in HydG-catalyzed carbon monoxide and
100 ding the selectivity of S-oxygenation versus H atom abstraction in thiolate-ligated nonheme metalloen
101 tigate possible reactive Cu/O(2) species for H-atom abstraction in peptidylglycine alpha-hydroxylatin
102 substrates, whereas the transition state of H atom abstraction is destabilized, presumably due to a
104 nsity in terms of relative rate constants of H-atom abstraction (k(inh)) from the various tocopherol
105 ring opening, k(-1), and the intermolecular H-atom abstraction, k2, were determined from the depende
108 lectivities are achieved by highly selective H atom abstraction of equatorially disposed alpha-hydrox
109 ions revealed that the reaction barriers for H-atom abstraction of cyclohexane by the ground state of
110 a reaction mechanism involving dibenzylamine H-atom abstraction or electron-transfer oxidation by the
113 result of stabilization of the [Cu(2)OH](2+) H-atom abstraction product by electron delocalization ov
114 r distribution-and abundance relative to the H-atom abstraction products-changes in the presence of g
115 intermediate, caught in the act of substrate H-atom abstraction, providing new insights into the mech
117 n a dichloromethane solution, the rate of an H atom abstraction reaction can be accelerated by a fact
120 a significant effect on the energetics of a H-atom abstraction reaction by the Cu(II)(M)-OOH interme
125 of the (hydroxo)iron(III) complex to undergo H atom abstraction reactions is the basis for its cataly
126 XYLO)(O(2)(*-))](2+) (1), as demonstrated in H atom abstraction reactions with certain phenolic ArO-H
127 I)-OOH complexes are found to perform direct H-atom abstraction reactions but with very different rea
130 shed fundamental thermochemical data for the H atom abstraction reactivity of dicopper(II) superoxo c
132 trast to the behavior of LS Fe(III)-OOH, the H-atom abstraction reactivity of HS Fe(III)-OOH is found
134 t phenyl nitrenium reacts through sequential H atom abstractions, resulting in the eventual formation
136 data are consistent with an initial E(1) net H-atom abstraction step that furnishes the cis amide/amm
137 netic isotope effect (1.35 0.03) suggests an H-atom abstraction step with an asymmetric transition st
138 rizontal lineO unit is much more reactive at H-atom abstraction than its S = 1 counterpart and sugges
139 ished mechanism of autoxidation proceeds via H-atom abstraction through a cyclic network of peroxy-hy
140 rimary (N-demethylation) sp(3) C-H bonds via H atom abstraction to form dehydro- and desmethyl-ofloxa
141 on of a biradical species via intramolecular H atom abstraction to generate its lowest triplet ketone
142 , with a phenolic substrate, involving a net H-atom abstraction to cleave the bridging peroxo O-O bon
143 ted state decays by efficient intramolecular H-atom abstraction to form a 1,4-biradical, 8, that has
144 out this reaction via alpha-carbon (Calpha) H-atom abstraction to form a peptidyl Calpha radical tha
145 sitizer moiety, undergoes intramolecular 1,4-H-atom abstraction to form biradical 6, which was identi
147 e substrate can undergo different reactions (H-atom abstraction vs. electrophilic aromatic attack) wi
148 mpetition experiments, the rate constant for H atom abstraction was determined and found to be about
149 moted reactivity (e.g., nitrene transfer and H-atom abstraction), where the divergent reactivity is r
150 suggested by Aoyama, involves excited-state H-atom abstraction while the other, put forth by Whitten