TY  - GEN
AU  - Alonso-Vante,Nicolas
AU  - Granozzi,Gaetano
TI  - Electrochemical Surface Science: Basics and Applications
SN  - books978-3-03921-643-7
PY  - 2019///
PB  - MDPI - Multidisciplinary Digital Publishing Institute
KW  - Pd thin films
KW  - n/a
KW  - Auger-Electron Spectroscopy
KW  - benchmarking
KW  - potential-dependent structures
KW  - CO electro-oxidation
KW  - surface reconstruction
KW  - photo-electrochemistry
KW  - nitrogen doping
KW  - potential stepping
KW  - DFT
KW  - nanoparticles
KW  - carbon nanofiber
KW  - Pd
KW  - gas diffusion electrode
KW  - flexible ITO
KW  - UPS
KW  - palladium
KW  - Lead OPD
KW  - formic acid oxidation
KW  - cobalt oxide
KW  - adsorbed OH
KW  - electrochemistry
KW  - Pt
KW  - mesopore
KW  - DMFC
KW  - pH and concentration effects
KW  - solvothermal method
KW  - direct methanol fuel cells
KW  - EF-PEEM
KW  - PVDF
KW  - self-assembly
KW  - PEMFC
KW  - hard X rays
KW  - photochemistry
KW  - EQCM
KW  - potential cycling
KW  - surface alloy
KW  - near ambient pressure XPS
KW  - cobalt-based electrocatalyst
KW  - silver single crystals
KW  - Cu(111)
KW  - electrodeposited alloys
KW  - Pt single-crystal electrodes
KW  - SOFC
KW  - TiO2
KW  - oxygen evolution reaction
KW  - silicon nanoparticles
KW  - pump &amp
KW  - graphitization
KW  - in situ EC-STM
KW  - oxygen reduction
KW  - gold
KW  - diazonium salts
KW  - Au
KW  - micropore
KW  - solid/liquid interface
KW  - XPS
KW  - XAFS
KW  - surface chemistry
KW  - electrosynthesis
KW  - porous fiber
KW  - surface science
KW  - click chemistry
KW  - adhesion
KW  - in situ
KW  - methanol oxidation reaction
KW  - hydroxyl radical
KW  - mass transport
KW  - free electron laser
KW  - cyclic voltammetry
KW  - redox properties
KW  - electro-oxidation
KW  - X-ray absorption spectroscopy
KW  - hydrogen adsorption
KW  - electrodeposition
KW  - electrocatalysis
KW  - Ordered mesoporous carbon
KW  - Corrosion Protection
KW  - electrochemical interface
KW  - cyclic voltammetry (CV)
KW  - FEXRAV
KW  - photoelectron simulations
KW  - Pt–Ru catalysts
KW  - d-band theory
KW  - bimetallic alloy
KW  - photoconversion
KW  - ordered mesoporous carbons
KW  - carbon nanofibers (CNFs)
KW  - platinum
KW  - water splitting
KW  - Surface Modification
KW  - EPR spectroscopy
KW  - scanning photoelectron microscopy
KW  - model catalyst
KW  - energy dispersive
KW  - porphyrins
KW  - combined non-covalent control
KW  - AES
KW  - spin-coating
KW  - SAMs
KW  - water oxidation
KW  - in-situ X-ray diffraction
KW  - Au nanocrystals
KW  - model systems
KW  - platinum single crystals
KW  - cathode
KW  - redox monolayers
KW  - surface nanostructures
KW  - bifunctional oxygen electrode
KW  - polymer
KW  - photoelectrochemistry
KW  - metal-electrolyte interface
KW  - electrocatalysts
KW  - APTES
KW  - porogen
KW  - electrophoretic deposition
KW  - thin-films
KW  - ammonia activation
KW  - graphene
KW  - ORR
KW  - polypyrrole
KW  - iridium
KW  - surface area
KW  - reduced graphene oxide
KW  - Magnetite
KW  - Platinum
KW  - electrospinning
KW  - catalysts
KW  - Blackening of Steel
KW  - switchable surfaces
KW  - in situ ambient pressure XPS
KW  - fuel cells
KW  - methanol oxidation
KW  - quick-XAS
KW  - nickel
KW  - CO oxidation
KW  - solid oxide fuel cells
KW  - operando
KW  - probe
KW  - CdS
KW  - alkanthiols
KW  - ECALE
KW  - alkoxyamine surfaces
KW  - underpotential deposition (upd)
N1  - Open Access
N2  - Electrochemical surface science (EC-SS) is the natural advancement of traditional surface science (where gas–vacuum/solid interfaces are studied) to liquid (solution)/electrified solid interfaces. Such a merging between two different disciplines—i.e., surface science (SS) and electrochemistry—officially advanced ca. three decades ago. The main characteristic of EC-SS versus electrochemistry is the reductionist approach undertaken, inherited from SS and aiming to understand the microscopic processes occurring at electrodes on the atomic level. A few of the exemplary keystone tools of EC-SS include EC-scanning probe microscopies, operando and in situ spectroscopies and electron microscopies, and differential EC mass spectrometry (DEMS). EC-SS indirectly (and often unconsciously) receives a great boost from the requirement for rational design of energy conversion and storage devices for the next generation of energetic landscapes. As a matter of fact, the number of material science groups deeply involved in such a challenging field has tremendously expanded and, within such a panorama, EC and SS investigations are intimately combined in a huge number of papers. The aim of this Special Issue is to offer an open access forum where researchers in the field of electrochemistry, surface science, and materials science could outline the great advances that can be reached by exploiting EC-SS approaches. Papers addressing both the basic science and more applied issues in the field of EC-SS and energy conversion and storage materials have been published in this Special Issue
UR  - https://mdpi.com/books/pdfview/book/1652
UR  - https://directory.doabooks.org/handle/20.500.12854/46135
ER  -