World Scientific, 2011, 374 pages
The scope of this book will be focused on the interface issues and problems in organic materials as electronic device applications. The organic material electronics is a rapidly progressing field for potential applications in flexible field effect transistors, plastic solar cells, organic luminescent devices, etc.
However, the performance of these organic devices is still not sufficient. To enhance the understanding and practical applications of organic devices, we need to understand the fundamental organic device physics which is somewhat different from the conventional inorganic device physics. This book will discuss the detailed progress in these topics.
This book treats the important issues of interface control in organic devices in a wide range of applications that cover from electronics, displays, and sensors to biorelated devices. This book is composed of three parts:
Nanoscale interface
Molecular electronics
Polymer electronics.
In Part 1, the charge injection, the effect of space-charge, and the contact resistances are discussed at the nanoscale interface in organic transistors which are used as a driving circuit element in the organic flexible displays. In Part 2, the charge conduction mechanisms in molecular-based electronics are mainly discussed. Scanning tunneling microscopic tool was used to investigate the charge conduction in the molecular memory, sensors as well as solid-state type molecular electronic devices. In Part 3, synthesis and deposition techniques to prepare polymer materials and devices are discussed for more variety of devices applications, such as organic optoelectronic devices and ID tags. Bioelectronic devices using biomolecules are also discussed.
The scope of this book will be focused on the interface issues and problems in organic materials as electronic device applications. The organic material electronics is a rapidly progressing field for potential applications in flexible field effect transistors, plastic solar cells, organic luminescent devices, etc.
However, the performance of these organic devices is still not sufficient. To enhance the understanding and practical applications of organic devices, we need to understand the fundamental organic device physics which is somewhat different from the conventional inorganic device physics. This book will discuss the detailed progress in these topics.
This book treats the important issues of interface control in organic devices in a wide range of applications that cover from electronics, displays, and sensors to biorelated devices. This book is composed of three parts:
Nanoscale interface
Molecular electronics
Polymer electronics.
In Part 1, the charge injection, the effect of space-charge, and the contact resistances are discussed at the nanoscale interface in organic transistors which are used as a driving circuit element in the organic flexible displays. In Part 2, the charge conduction mechanisms in molecular-based electronics are mainly discussed. Scanning tunneling microscopic tool was used to investigate the charge conduction in the molecular memory, sensors as well as solid-state type molecular electronic devices. In Part 3, synthesis and deposition techniques to prepare polymer materials and devices are discussed for more variety of devices applications, such as organic optoelectronic devices and ID tags. Bioelectronic devices using biomolecules are also discussed.