Mechanism of the Reduction of Lead Ions in Aqueous Solution (a Pulse Radiolysis Study)

Breitenkamp, M.; Henglein, A.; Lilie, J.

doi:10.1002/bbpc.19760801009

Cited by 100 publications

(35 citation statements)

References 10 publications

(17 reference statements)

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“…However, the formation of CO 2 /CO 2 À pair needs more than À2.0 V (NHE) [25][26][27][28]. The reduction of CO 2 at more positive potentials than À2.0 V (NHE) can not be explained by the formulated mechanism in path 1.…”

Section: Hcoo + H 2 O ! Hcooh + Ohmentioning

confidence: 85%

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Reduction of CO2 under high pressure and high temperature on Pb-granule electrodes in a fixed-bed reactor in aqueous medium

Köleli

Balun

2004

Applied Catalysis A: General

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Section: Hcoo + H 2 O ! Hcooh + Ohmentioning

confidence: 85%

“…HCOOH Or HCOO ad + e À ! HCOO À If we consider the applied potential values, such as À1.6, À1.7 V (SCE) in the present work in a detailed manner and compare these with the potentials formulated for CO 2 /CO 2 À formation in [26][27][28][29], a direct electron transfer onto CO 2 molecule appears to be impossible.…”

Section: Hcoo + H 2 O ! Hcooh + Ohmentioning

confidence: 96%

Reduction of CO2 under high pressure and high temperature on Pb-granule electrodes in a fixed-bed reactor in aqueous medium

Köleli

Balun

2004

Applied Catalysis A: General

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“…The predicted value is significantly more endothermic than the Ϫ0.6 eV cited in the experimental radiolysis literature. 31,64,65 That Ϫ0.6 eV value was derived by estimating the Ni + ⌬G hyd using a simple Pauling ionic radius and a dielectric continuum approximation; 65 as the authors stressed, ligand field effects, which can be a fraction of an eV for first row transition metal ions in water, 66 were neglected. AIMD ⌬G hyd calculations, free from these assump-tions, should yield more accurate redox potentials for metal ions in unstable valence states encountered as transients in radiolysis experiments.…”

Section: Ag + +Ni + \ Ag+ Ni 2+mentioning

confidence: 99%

“…AIMD ⌬G hyd calculations, free from these assump-tions, should yield more accurate redox potentials for metal ions in unstable valence states encountered as transients in radiolysis experiments. 64,65,67 Finally, we note that the Ni 2+ ⌬G hyd depends on whether the DFT+ U approach is used in calculating ͗dH͑q͒ / q͘ q along the AIMD trajectory. Setting U =4͑6͒ eV already decreases the gas phase Ni 2+ -͑H 2 O͒ 6 cluster binding energy by ϳ0.5 eV ͑1.0 eV͒ without inducing noticeable changes in the geometry of the complex.…”

Section: Ag + +Ni + \ Ag+ Ni 2+mentioning

confidence: 99%

Ab initio molecular dynamics calculations of ion hydration free energies

Leung

Rempe

Lilienfeld

2009

The Journal of Chemical Physics

120

150

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We apply ab initio molecular dynamics (AIMD) methods in conjunction with the thermodynamic integration or "lambda-path" technique to compute the intrinsic hydration free energies of Li(+), Cl(-), and Ag(+) ions. Using the Perdew-Burke-Ernzerhof functional, adapting methods developed for classical force field applications, and with consistent assumptions about surface potential (phi) contributions, we obtain absolute AIMD hydration free energies (DeltaG(hyd)) within a few kcal/mol, or better than 4%, of Tissandier et al.'s [J. Phys. Chem. A 102, 7787 (1998)] experimental values augmented with the SPC/E water model phi predictions. The sums of Li(+)/Cl(-) and Ag(+)/Cl(-) AIMD DeltaG(hyd), which are not affected by surface potentials, are within 2.6% and 1.2 % of experimental values, respectively. We also report the free energy changes associated with the transition metal ion redox reaction Ag(+)+Ni(+)-->Ag+Ni(2+) in water. The predictions for this reaction suggest that existing estimates of DeltaG(hyd) for unstable radiolysis intermediates such as Ni(+) may need to be extensively revised.

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“…The reduction potential for methanol and ethanol radicals is E0(H + + CH20/CH2OH) = --0.97 V and E0(H ÷ + CH3CHO/CH3CHOH) = --1.1 V [18]. This can partly explain the higher rate constant for ethanol radicals (see Table II).…”

Section: Reduction By Methanol-and Ethanol Radicalsmentioning

confidence: 93%

Reduction of ferricytochrome c, methemoglobin and metmyoglobin by hydroxyl and alcohol radicals

Leeuwen

Tromp

Nauta

1979

Biochimica et Biophysica Acta (BBA) - Protein Structure

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SummaryWe have studied the reaction of ferricytochrome c, methemoglobin and metmyoglobin with OH and alcohol radicals {methanol, ethanol, ethylene glycol and glycerol). These radicals can be divided into three groups:1. The OH radicals which reduce the ferricytochrome c with a yield of (30 _+ 10)% and methemoglobin with a yield of (40 + 10)%. They do not reduce metmyoglobin. The reduction is not a normal bimolecular reaction but is most probably an intramolecular electron transfer of a protein radical.2. Methanol and ethanol radicals which reduce all three hemoproteins with a yield of (100 + 5)%. This reduction is a normal bimolecular reaction.3. Glycerol radicals which do not reduce the ferrihemoproteins under our experimental conditions. Ethylene glycol radicals do not reduce ferricytochrome c and metmyoglobin but they do reduce methemoglobin with a yield of (30 + 10)%.

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Mechanism of the Reduction of Lead Ions in Aqueous Solution (a Pulse Radiolysis Study)

Cited by 100 publications

References 10 publications

Reduction of CO2 under high pressure and high temperature on Pb-granule electrodes in a fixed-bed reactor in aqueous medium

Reduction of CO2 under high pressure and high temperature on Pb-granule electrodes in a fixed-bed reactor in aqueous medium

Ab initio molecular dynamics calculations of ion hydration free energies

Reduction of ferricytochrome c, methemoglobin and metmyoglobin by hydroxyl and alcohol radicals

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