Single entity electrochemistry and the electron transfer kinetics of hydrazine oxidation

Single entity electrochemistry and the electron transfer kinetics of hydrazine oxidation

The mechanism and kinetics of the electro-catalytic oxidation of hydrazine by graphene oxide platelets randomly decorated with palladium nanoparticles are deduced using single particle impact electrochemical measurements in buffered aqueous solutions across the pH range 2–11. Both hydrazine, N2H4, a...

Descrizione completa

Dettagli Bibliografici
Autori principali:	Miao, R, Shao, L, Compton, R
Natura:	Journal article
Lingua:	English
Pubblicazione:	Springer 2021

Documenti analoghi

Electro-oxidation of hydrazine shows Marcusian electron transfer kinetics
di: Miao, R, et al.
Pubblicazione: (2020)

Electrochemistry of hydrazine
di: Miao, R
Pubblicazione: (2021)

Towards mixed fuels: the electrochemistry of hydrazine in the presence of methanol and formic acid.
di: Aldous, L, et al.
Pubblicazione: (2011)

Editorial: Single-Entity Electrochemistry
di: Wei Ma, et al.
Pubblicazione: (2021-12-01)

The charge transfer kinetics of the oxidation of silver and nickel nanoparticles via particle-electrode impact electrochemistry.
di: Zhou, Y, et al.
Pubblicazione: (2012)

Single-entity electrochemistry: Diffusion-controlled transport of an analyte inside a particle
di: Le, H, et al.
Pubblicazione: (2018)

'Single entity' electrochemistry at carbon nanotubes
di: Kaliyaraj Selva Kumar, A
Pubblicazione: (2022)

The electro-oxidation of hydrazine: a self-inhibiting reaction
di: Miao, R, et al.
Pubblicazione: (2021)

Single-entity coccolithophore electrochemistry shows size is no guide to the degree of calcification
di: Yang, M, et al.
Pubblicazione: (2022)

Semiconducting Nanoparticles: Single Entity Electrochemistry and Photoelectrochemistry
di: S. Mathuri, et al.
Pubblicazione: (2021-06-01)

Electron transfer kinetics at single nanoparticles
di: Kahk, J, et al.
Pubblicazione: (2012)

Electron transfer kinetics at single nanoparticles
di: Kahk, J, et al.
Pubblicazione: (2012)

Electrochemistry of single entities and ensembles of metal-based nanoparticles
di: Xie, RC
Pubblicazione: (2021)

Mechanism of hydrazine oxidation at Palladium electrodes: Long-lived radical di-cation formation
di: Miao, R, et al.
Pubblicazione: (2021)

Understanding carbon nanotube voltammetry: distinguishing adsorptive and thin layer effects via “single-entity” electrochemistry
di: Kaliyaraj Selva Kumar, A, et al.
Pubblicazione: (2022)

The mechanism of hydrazine electro-oxidation revealed by platinum microelectrodes: role of residual oxides.
di: Aldous, L, et al.
Pubblicazione: (2011)

Electron transfer to decorated graphene oxide particles
di: Miao, R, et al.
Pubblicazione: (2019)

Electrochemistry of single enzymes: fluctuations of catalase activities
di: Lin, C, et al.
Pubblicazione: (2018)

MOLECULAR ELECTROCHEMISTRY
di: Compton, R, et al.
Pubblicazione: (1986)

Electrochemistry of nickel nanoparticles is controlled by surface oxide layers.
di: Zhou, Y, et al.
Pubblicazione: (2013)

SONO-ELECTROCHEMISTRY - THE OXIDATION OF BIS(CYCLOPENTADIENYL)MOLYBDENUM DICHLORIDE
di: Compton, R, et al.
Pubblicazione: (1995)

Electrochemistry /
di: Compton, R. G., editor, et al.
Pubblicazione: (2013)

Microwaves and Electrochemistry
di: Dale, S, et al.
Pubblicazione: (2013)

Definition of the transfer coefficient in electrochemistry (IUPAC Recommendations 2014)
di: Guidelli, R, et al.
Pubblicazione: (2014)

Graphane electrochemistry : electron transfer at hydrogenated graphenes
di: Poh, Hwee Ling, et al.
Pubblicazione: (2013)

Electrochemistry of single droplets of inverse (water-in-oil) emulsions
di: Zhang, H, et al.
Pubblicazione: (2017)

The electro-oxidation of hydrazine with palladium nanoparticle modified electrodes: dissecting chemical and physical effects: catalysis, surface roughness, or porosity?
di: Miao, R, et al.
Pubblicazione: (2021)

Defining the transfer coefficient in electrochemistry: An assessment (IUPAC Technical Report)
di: Guidelli, R, et al.
Pubblicazione: (2014)

An experimental insight into electrochemistry
di: Compton, R, et al.
Pubblicazione: (1992)

Single-entity Ti3C2Tx MXene electro-oxidation
di: Nayak, P, et al.
Pubblicazione: (2022)

Magnetoreception of Photoactivated Cryptochrome 1 in Electrochemistry and Electron Transfer
di: Zheng Zeng, et al.
Pubblicazione: (2018-05-01)

Cyclic voltammetry on electrode surfaces covered with porous layers: An analysis of electron transfer kinetics at single-walled carbon nanotube modified electrodes
di: Streeter, I, et al.
Pubblicazione: (2008)

The electroneutrality approximation in electrochemistry
di: Dickinson, E, et al.
Pubblicazione: (2011)

The electroneutrality approximation in electrochemistry
di: Dickinson, E, et al.
Pubblicazione: (2011)

The electroneutrality approximation in electrochemistry
di: Dickinson, E, et al.
Pubblicazione: (2011)

Impact electrochemistry reveals that graphene nanoplatelets catalyse the oxidation of dopamine via adsorption
di: Chen, L, et al.
Pubblicazione: (2017)

Channel microband electrode arrays for mechanistic electrochemistry. Two-dimensional voltammetry: Electrode kinetics
di: Prieto, F, et al.
Pubblicazione: (1999)

Single-Entity Electrochemistry in the Agarose Hydrogel: Observation of Enhanced Signal Uniformity and Signal-to-Noise Ratio
di: Jaedo Na, et al.
Pubblicazione: (2023-07-01)

Detection of Escherichia coli bacteria by impact electrochemistry
di: Couto, R, et al.
Pubblicazione: (2018)

Iron(III) oxide graphite composite electrodes: Application to the electroanalytical detection of hydrazine and hydrogen peroxide
di: Sljukic, B, et al.
Pubblicazione: (2006)