{"id":547,"date":"2014-04-15T19:55:06","date_gmt":"2014-04-15T19:55:06","guid":{"rendered":"https:\/\/www.p-brane.com\/nm\/?p=547"},"modified":"2015-09-15T20:15:03","modified_gmt":"2015-09-15T20:15:03","slug":"graphene-fet-toy-physics-model","status":"publish","type":"post","link":"https:\/\/www.p-brane.com\/nm\/graphene-fet-toy-physics-model\/","title":{"rendered":"Graphene FET Toy Physics Model"},"content":{"rendered":"

This graphene FET toy physics model is primarily based on the graphene physics described in the paper\u00a0Electronic transport in two dimensional graphene<\/em> by S. D. Sarma et. al. and from materials properties data found in a number of sources (see the Description<\/strong> tab for the details). I’d appreciate any comments on errors, problems, inaccuracies, or how to make this model better.<\/p>\n

The IV Model<\/strong> tab allows you to selected the gate dielectric, dielectric thickness, mobility, gate voltage, phonon energy of the dielectric, drain-source voltage, drain-source length and width, and the resulting IV curve is plotted for these parameters.<\/p>\n

The Performance Table<\/strong> tab shows a summary of the graphene FET performance based on the selected values on the IV Model tab.<\/p>\n

The Materials Properties<\/strong> Tab shows the dielectric constant, breakdown voltage, and optical phonon energy for each gate dielectric that can be selected in the IV Model tab.<\/p>\n

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