Detail publikace

Bio-inspired riboflavin derivatives for organic electronics and biomimetic energy storage

Originální název

Bio-inspired riboflavin derivatives for organic electronics and biomimetic energy storage

Anglický název

Bio-inspired riboflavin derivatives for organic electronics and biomimetic energy storage

Jazyk

en

Originální abstrakt

Biologically inspired molecular engineering is a promising way towards environmentally responsible, cheap, non-toxic and efficient materials for organic electronics and energy storage. As an example, flavines are one of most structurally and functionally versatile redox centers in nature, which act as catalyzers in a wide range of biotransformations and electron-transfer reactions. Present work demonstrates the implementation of riboflavin inspired derivatives in organic electronics applications; such as semiconducting materials and bio-inspired redox centers for biomimetic energy storage.

Anglický abstrakt

Biologically inspired molecular engineering is a promising way towards environmentally responsible, cheap, non-toxic and efficient materials for organic electronics and energy storage. As an example, flavines are one of most structurally and functionally versatile redox centers in nature, which act as catalyzers in a wide range of biotransformations and electron-transfer reactions. Present work demonstrates the implementation of riboflavin inspired derivatives in organic electronics applications; such as semiconducting materials and bio-inspired redox centers for biomimetic energy storage.

BibTex


@misc{BUT141138,
  author="Jozef {Krajčovič} and Jan {Richtár} and Alexander {Kovalenko} and Martin {Weiter}",
  title="Bio-inspired riboflavin derivatives for organic electronics and biomimetic energy storage",
  annote="Biologically inspired molecular engineering is a promising way towards environmentally responsible, cheap, non-toxic and efficient materials for organic electronics and energy storage. As an example, flavines are one of most structurally and functionally versatile redox centers in nature, which act as catalyzers in a wide range of biotransformations and electron-transfer reactions. Present work demonstrates the implementation of riboflavin inspired derivatives in organic electronics applications; such as semiconducting materials and bio-inspired redox centers for biomimetic energy storage.",
  booktitle="4th International Winterschool on Bioelectronics, Kirchberg in Tirol, Austria",
  chapter="141138",
  year="2017",
  month="march",
  type="abstract"
}