ナノ粒子表面における触媒反応および電極触媒反応<br>Catalysis and Electrocatalysis at Nanoparticle Surfaces

個数:

ナノ粒子表面における触媒反応および電極触媒反応
Catalysis and Electrocatalysis at Nanoparticle Surfaces

  • 在庫がございません。海外の書籍取次会社を通じて出版社等からお取り寄せいたします。
    通常6~9週間ほどで発送の見込みですが、商品によってはさらに時間がかかることもございます。
    重要ご説明事項
    1. 納期遅延や、ご入手不能となる場合がございます。
    2. 複数冊ご注文の場合、分割発送となる場合がございます。
    3. 美品のご指定は承りかねます。
  • 【入荷遅延について】
    世界情勢の影響により、海外からお取り寄せとなる洋書・洋古書の入荷が、表示している標準的な納期よりも遅延する場合がございます。
    おそれいりますが、あらかじめご了承くださいますようお願い申し上げます。
  • ◆画像の表紙や帯等は実物とは異なる場合があります。
  • ◆ウェブストアでの洋書販売価格は、弊社店舗等での販売価格とは異なります。
    また、洋書販売価格は、ご注文確定時点での日本円価格となります。
    ご注文確定後に、同じ洋書の販売価格が変動しても、それは反映されません。
  • 製本 Hardcover:ハードカバー版/ページ数 980 p.
  • 言語 ENG
  • 商品コード 9780824708795
  • DDC分類 620.5

Full Description

Catalysis and Electrocatalysis at Nanoparticle Surfaces illustrates the latest developments in electrochemical nanotechnology, heterogeneous catalysis, surface science, and theoretical modeling. It describes the manipulation, characterization, control, and application of nanoparticles for enhanced catalytic activity and selectivity and presents a range of experimental and synthetic strategies for work in nanoscale surface science.

Thisis a comprehensive source for physical, surface, and colloid chemists; materials scientists; interfacial chemists and electrochemists; electrochemical engineers; theoretical physicists; chemical engineers; and upper-level undergraduate and graduate students in these disciplines.

Contents

Theory of nanoparticle catalysis and electrocatalysis: theory and modelling of catalytic and electrocatalytic reactions - some selected examples; simulations of the reaction kinetics on nm supported catalyst particles; electronic structure and chemisorption properties of supported metal clusters - model calculations. Model systems - from single crystals to nanoparticles: state-of-the-art characterization of single crystal surfaces; single crystal surfaces as model platinum-based fuell cell electrocatalysts; electrochemical nanostructuring of surfaces; adsorption and reaction at supported model catalysts; size-dependent electronic, structural, and catalytic properties of metal clusters supported on ultra-thin oxide films; physical and electrochemical characterization of bimetallic nanoparticle electrodes. Synthetic approaches in nanoparticle catalysis and electrocatalysis: nanomaterials as precursors for electrocatalysts; preparation, characterization, and properties of bimetallic nanoparticles; physicochemical aspects of preparation of carbon supported Nobel metal catalysis. Advanced experimental concepts: NMR investigation of supported metal catalysts; in situ X-ray adsorption spectroscopy investigations of the carbon-supported pt electrocatalysts; STM and infrared spectroscopy in studies of fuel cell model catalysts. Particle size, support, and promotional effects: electrochemical and chemical promotion on metal films and nanoparticles; metal-supported interaction in low temperature fuel cell electrocatalysis; effects of nanoparticle size, structure, and metal-support interactions; promotion, electrochemical promotion and metal-support interactions; support effects on catalytic performance of nanoparticles; abnormal infrared effects of nanometer scale thins film material of platinum group metals and alloys at electrode/electrolyte interfaces; design of electrocatalysts for fuel cells; effect of particle size and support on some catalytic properties of metallic and