《納微薄膜修飾電極及其套用》以化學和相關邊緣學科為基礎,結合現代電化學、電分析化學、界面物理與化學的最新進展,系統地介紹納米TiO2、納米羥基磷灰石、納米多孔氧化鋁膜修飾電極的製備工藝及其在生物、環境等領域的套用,並對近期受到關注的分子印跡無機納米膜和有機薄膜修飾電極另列章節分別介紹。
基本介紹
- 書名:納微薄膜修飾電極及其套用
- 作者:楊政鵬
- 出版日期:2013年9月1日
- 語種:簡體中文, 英語
- 外文名:Nano/micro Film Modified Electrode and Its Application
- 出版社:化學工業出版社
- 頁數:203頁
- 開本:16
內容簡介,圖書目錄,
內容簡介
納微薄膜修飾電極的製備及套用已成為化學修飾電極研究的熱點。這本《納微薄膜修飾電極及其套用》是作者楊政鵬以該研究領域近幾年的研究成果為基礎而寫成的,主要介紹了納米TiO2、納米羥基磷灰石、納米多孔氧化鋁膜修飾電極的制各工藝及其在生物、醫學、環境等領域的套用,並對近期受到關注的分子印跡無機納米膜和有機薄膜修飾電極另列章節分別介紹。本書力求做到方法具體、內容新穎充實、分析深入,適於作電化學、電分析化學、界面化學和相關邊緣學科研究的參考書。
圖書目錄
Chapter 1 Introduction
1.1 Chemically modified electrode
1.2 Properties of nanomaterial and the application of electrodes modified by nanomaterial
1.3 Characteristics and application ofnanometer TiO2
1.4 Characteristics and application of nanometer hydroxyapatite
1.5 Characteristics and application of nanoporous alumina
1.6 Molecular imprinting technique
1.7 Piezoelectric quartz crystal sensing technique
References
Chapter 2 Nanosized TiO2 film modified electrode and its application
2.1 Preparation ofnanosized TiO2 film modified electrodes
2.2 QCM monitoring of the process of substances on nanosized TiO2 film modified electrodes
2.3 Adsorption and photoreduction of heavy metal ions on nanosized TiO2 film modified electrodes
2.4 Adsorption and photocatalytic degradation ofbilirubin on nanosized TiO2 film modified electrodes
2.5 Mechanism and kinetics of HAP formation on nanosized TiO2 film modified electrodes
2.6 Conclusions
References
Chapter 3 Electrode modified by molecularly imprinted TiO2 film with nanostructural surface and its application
3.1 Preparation of electrodes modified by molecularly imprinted TiO2 films with nanostructural surface
3.2 QCM monitoring of the process of substances on molecularly imprinted TiO2 films
3.3 Piezoelectric detection ofbilimbin based on bilirubin-imprinted TiO2 film electrode
3.4 Enhanced removal ofbilirubin on molecularly imprinted TiO2 film
3.5 Potentiometric urea biosensor based on immobilization ofurease onto urease-imprinted TiO2 film
3.6 Molecularly imprinted TiO2 film for atrazine removal
3.7 Conclusions
References
Chapter 4 Nanosized HAP film modified electrode and its application
4.1 Preparation of nanosized HAP film modified electrodes
4.2 QCM monitoring of the process of substances on nanosized HAP film modified electrodes
4.3 Adsorption/desorption behavior of protein on nanosized HAP film modified electrodes
4.4 Adsorption and photocatalytic degradation ofbilirubin on nanosized HAP film modified electrodes
4.5 Photocatalytic degradation ofbilirubin on HAP-modified nanocrystalline TiO2 films
4.6 Electrodes modified by molecularly imprinted HAP films for bilirubin recognition
4.7 Recyclable Fe304/HAP composite nanoparticles for photo- catalytic application
4.8 Conclusions
References
Chapter 5 Nanoporous alumina membrane with urease immobilization and its application
5.1 Preparation of nanoporous alumina membrane
5.2 Immobilization procedures ofurease on nanoporous alumina membrane
5.3 Measurement ofurease activity
5.4 Characterization of nanoporous alumina membranes
5.5 Immobilization ofurease via adsorption onto nanoporous alumina membranes
5.6 Optimization ofurease immobilization
5.7 Study on the stability of immobilized urease
5.8 Response characteristics of the urea biosensor
5.9 Long-term storage stability and clinical application of the urea biosensor
5.10 Conclusions
References
Chapter 6 Organic thin f'dm modified electrode and its application
6.1 Preparation of organic thin film modified electrodes
6.2 QCM monitoring of the process of substances on organic thin film modified electrodes
6.3 Bilirubin adsorption on self-assembled phospholipid bilayers
6.4 Controlled growth of calcium phosphate using phosphatidylcholine-modified porous TiO2 film as reaction compartments
6.5 Designing of MIP based QCM sensor for the determination of Cu(Ⅱ) ions in solution
6.6 Catalytic properties of magnetic single-enzyme nanoparticles modified by polymer film
6.7 Conclusions
References
1.1 Chemically modified electrode
1.2 Properties of nanomaterial and the application of electrodes modified by nanomaterial
1.3 Characteristics and application ofnanometer TiO2
1.4 Characteristics and application of nanometer hydroxyapatite
1.5 Characteristics and application of nanoporous alumina
1.6 Molecular imprinting technique
1.7 Piezoelectric quartz crystal sensing technique
References
Chapter 2 Nanosized TiO2 film modified electrode and its application
2.1 Preparation ofnanosized TiO2 film modified electrodes
2.2 QCM monitoring of the process of substances on nanosized TiO2 film modified electrodes
2.3 Adsorption and photoreduction of heavy metal ions on nanosized TiO2 film modified electrodes
2.4 Adsorption and photocatalytic degradation ofbilirubin on nanosized TiO2 film modified electrodes
2.5 Mechanism and kinetics of HAP formation on nanosized TiO2 film modified electrodes
2.6 Conclusions
References
Chapter 3 Electrode modified by molecularly imprinted TiO2 film with nanostructural surface and its application
3.1 Preparation of electrodes modified by molecularly imprinted TiO2 films with nanostructural surface
3.2 QCM monitoring of the process of substances on molecularly imprinted TiO2 films
3.3 Piezoelectric detection ofbilimbin based on bilirubin-imprinted TiO2 film electrode
3.4 Enhanced removal ofbilirubin on molecularly imprinted TiO2 film
3.5 Potentiometric urea biosensor based on immobilization ofurease onto urease-imprinted TiO2 film
3.6 Molecularly imprinted TiO2 film for atrazine removal
3.7 Conclusions
References
Chapter 4 Nanosized HAP film modified electrode and its application
4.1 Preparation of nanosized HAP film modified electrodes
4.2 QCM monitoring of the process of substances on nanosized HAP film modified electrodes
4.3 Adsorption/desorption behavior of protein on nanosized HAP film modified electrodes
4.4 Adsorption and photocatalytic degradation ofbilirubin on nanosized HAP film modified electrodes
4.5 Photocatalytic degradation ofbilirubin on HAP-modified nanocrystalline TiO2 films
4.6 Electrodes modified by molecularly imprinted HAP films for bilirubin recognition
4.7 Recyclable Fe304/HAP composite nanoparticles for photo- catalytic application
4.8 Conclusions
References
Chapter 5 Nanoporous alumina membrane with urease immobilization and its application
5.1 Preparation of nanoporous alumina membrane
5.2 Immobilization procedures ofurease on nanoporous alumina membrane
5.3 Measurement ofurease activity
5.4 Characterization of nanoporous alumina membranes
5.5 Immobilization ofurease via adsorption onto nanoporous alumina membranes
5.6 Optimization ofurease immobilization
5.7 Study on the stability of immobilized urease
5.8 Response characteristics of the urea biosensor
5.9 Long-term storage stability and clinical application of the urea biosensor
5.10 Conclusions
References
Chapter 6 Organic thin f'dm modified electrode and its application
6.1 Preparation of organic thin film modified electrodes
6.2 QCM monitoring of the process of substances on organic thin film modified electrodes
6.3 Bilirubin adsorption on self-assembled phospholipid bilayers
6.4 Controlled growth of calcium phosphate using phosphatidylcholine-modified porous TiO2 film as reaction compartments
6.5 Designing of MIP based QCM sensor for the determination of Cu(Ⅱ) ions in solution
6.6 Catalytic properties of magnetic single-enzyme nanoparticles modified by polymer film
6.7 Conclusions
References
