Graphene Molecular  Memories A new non-volatile charge trapping memory using isolated nano-graphene crystals and uniform distribution as a nano floating gate (PhD in Nano-Microelectronics)

Researcher  and author: Dr.   (   Afshin Rashid)



Note: Graphene Molecular  Memories A new non-volatile charge trapping memory using isolated nano-graphene crystals and uniform distribution is used as a nano floating gate with excellent controllability and uniformity. Nano-graphene load trapping memory with large memory gate (4.5 volts) at low operating voltage (8 volts), chemical and thermal stability (1000 ° C), as well as adjustable memory performance using different tunneling .

Graphene has outstanding nanoelectronic properties, very high electron mobility and unparalleled nanoscale conductivity. It is so conductive that it transmits electrons ten times faster than silicon. These properties make graphene an ideal candidate for future-generation nanoelectronic applications such as   graphene molecular nanoparticles  .




The interaction of absorbed nano-graphene particles  , which changes the electrical conductivity  at the surface  of Nano Memory Moulcolar Graphene  Absorption of  small amounts of nano-electrons  with very low molecular motion alters the resistance of nano-graphene  , which is commensurate with  the molecular nanoparticles of graphene Nano Memory Moulcolar  . Graphene Molecular Nano Memories Moulcolar is  a transparent flexible nano graphene floating gate transistor memory device made by combining an active single-layer graphene channel with gold nanoparticle trap elements. Systematically the dimensions of the gold nanoparticle trap elements, the thickness of the dielectric tunneling layer and the graphene doping surface are very important in its production. In particular, conductivity differences (  e.g.  , memory window) between programming and clearing operations at a specific gate voltage can be maximized by doping. The resulting graphene nanomaterials  are molecularly developed, excellent programmable nanoscale memory performance compared to previous graphene memory devices and a large memory window (12 volts), fast switching speed (1 microsecond), capability Shows strong electrical reliability. Graphene molecular nanoparticles display  unique electronic properties, and their small size, structural strength, and high performance make them very promising as a charge storage medium for nanoparticle applications. With the development of small and large devices, graphene nanostructures are emerging as an ideal material.



Conclusion : 

Graphene Molecular Nano Memories  A new non-volatile charge trapping memory using isolated nano-graphene crystals and uniform distribution is used as a nano floating gate with excellent controllable capacity and uniformity. Nano-graphene load trapping memory with large memory gate (4.5 volts) at low operating voltage (8 volts), chemical and thermal stability (1000 ° C), as well as adjustable memory performance using different tunneling .

Researcher  and author: Dr.   (   Afshin Rashid)

PhD in Nano-Microelectronics