This thesis examines a novel class of flexible electronic material with great potential for use in the construction of stretchable amplifiers and memory elements. Most remarkably the composite material produces spontaneous oscillations that increase in frequency when pressure is applied to it. In this way, the material mimics the excitatory response of pressure-sensing neurons in the human skin. The composites, formed of silicone and graphitic nanoparticles, were prepared in several allotropic forms and functionalized with naphthalene diimide molecules. A systematic study is presented of the...
This thesis examines a novel class of flexible electronic material with great potential for use in the construction of stretchable amplifiers and memo...
This book examines a novel class of flexible electronic material with great potential for use in the construction of stretchable amplifiers and memory elements which mimics the excitatory response of pressure-sensing neurons in the human skin.
This book examines a novel class of flexible electronic material with great potential for use in the construction of stretchable amplifiers and memory...
