Materials Science of DNA

Front Cover
Jung-II Jin, James Grote
CRC Press, Dec 12, 2011 - Medical - 338 pages

The field of materials science and technology has undergone revolutionary advances due to the development of novel analytical tools, functional materials, and multidisciplinary approaches to engineering. Additionally, theoretical predictions combined with increasingly improved models and computational capabilities are making impressive contributions to the progress of materials science and technology. In particular, the materials science of DNA has emerged as a vital area of research and is expected to immensely broaden the horizon of material science and nanotechnology in this century.

Materials Science of DNA highlights the most important subjects and perspectives in the field, with the aim of stimulating the interdisciplinary community and bringing this intensively interesting, emerging field of molecular-scale materials science to maturation. The editors have not only been involved in the research of materials science of DNA for the past decade, but also lead the series of International Biotronics Workshops supported by the US Air Force Research Laboratory.

Biotechnology and DNA-based biopolymers are not only applicable for genomic sequencing and clinical diagnosis and treatment, but can also have a major impact on nonbiotech applications—such as electronics and photonics— opening up a whole new field for bioengineering. New concepts and insights gained from DNA research are expected to prove genuinely useful in a variety of devices in nano, micro, and macro dimensions in the future. Where silicon has been the building block of inorganic electronics and photonics, DNA holds promise to become the building block for organic electronics and photonics.

 

Selected pages

Other editions - View all

Materials Science of DNA
Jung-II Jin,James Grote
Limited preview - 2016
Materials Science of DNA
Jung Il Jin
No preview available - 2017

Common terms and phrases

applications aptamer aqueous array assembly Bartsch base pairs behavior binding BioLED biopolymer biosensors butanol capacitive test structure carbon nanotubes cation charge transport Chem chemical CNTs complex Copyright covalent cross-linked CTMA curves detection device dielectric dispersion DNA films DNA lattice DNA molecules DNA nanotechnology DNA origami DNA strand DNA-based DNA-CTMA film double helix electrical electrochemical electronic energy ethidium bromide fabricated fluorescence function gate gold nanoparticles graphene groove Grote Heckman helical hybrid materials increase interactions intercalation ionic conductivity ionic liquids Kwon layer ligand magnetic measured metal molecular weight Nano Lett nanomaterials nanoparticles nanostructures nanotechnology nucleic acid oligonucleotides optical Phys PMMA polymer Proc properties Reprinted with permission resistivity room temperature sample Seeman self-assembly semiconducting sensors sequence shown in Figure single-walled carbon nanotubes solution sonication spectroscopy SPIE ssDNA substrate surface SWNTs tion transistors voltage Wang Yaney

About the author (2011)

Jung-Il Jin is a Professor Emeritus, Chemistry Department of Korea University, Seoul, Korea. He is the immediate Past President of International Union of Pure and Applied Chemistry, IUPAC. He is the founding President of the Federation of the Asian Polymer Societies, FAPS. He obtained his Ph.D. in 1969 from the City University of New York (Advisor: Richard H. Wiley) and was a visiting professor at the University of Massachusetts, USA and the University of Cambridge, UK. His research areas have been liquid crystalline and polyconjugated polymers and materials science of DNA. He has published about 400 original research articles and contributed many chapters to various monographs related to functional polymers.

James G. Grote is a Principal Electronics Research Engineer with the Air Force Research Laboratory, Materials and Manufacturing Directorate at Wright-Patterson Air Force Base, Ohio, where he conducts research in polymer and biopolymer based opto-electronics. He is also an adjunct professor at the University of Dayton and University of Cincinnati. Dr. Grote received his BS degree in Electrical Engineering for Ohio University and both his MS and Ph.D. degrees in Electrical Engineering from the University of Dayton, with partial study at the University of California, San Diego. He was a visiting scholar at the Institut d’Optique, Universite de Paris, Sud in the summer of 1995 and a visiting scholar at the University of Southern California, the University of California in Los Angeles and the University of Washington in 2001. He received Doctor Honoris Causa from the Politehnica University of Bucharest in 2010. Dr. Grote is an Air Force Research Laboratory Fellow, a Fellow of the International Society for Optics and Photonics (SPIE), a Fellow of the Optical Society of America (OSA), a Fellow of the European Optical Society (EOS) and a Senior Member of the Institute of Electrical and Electronics Engineers (IEEE). He has co-authored more than 130 journal and conference papers, including 2 book chapters, and has served as editor for more than 25 conference proceedings and journal publications.

Bibliographic information

TitleMaterials Science of DNA
EditorsJung-II Jin, James Grote
Editionillustrated
PublisherCRC Press, 2011
ISBN1439827419, 9781439827413
Length338 pages
Subjects ›  › 

Medical / Biochemistry
Science / Biotechnology
Science / Life Sciences / Biochemistry
Technology & Engineering / Materials Science
Technology & Engineering / Nanotechnology & MEMS
  
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