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Calculation method for cut-off frequency of small signal model of graphene transistor

A small-signal model, cut-off frequency technology, applied in computing, instrumentation, electrical and digital data processing, etc., to achieve the effect of reasonable theory, optimized cut-off frequency, and accurate results

Active Publication Date: 2016-01-06
INST OF MICROELECTRONICS CHINESE ACAD OF SCI
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Problems solved by technology

For the contact characteristics of the device, foreign experts have completed the research on the contact characteristics and contact capacitance characteristics of graphene and metals, but there is no complete small-signal model that takes into account the influence of the contact capacitance and the perfect small-signal model for the cut-off frequency The impact of the calculation of

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  • Calculation method for cut-off frequency of small signal model of graphene transistor
  • Calculation method for cut-off frequency of small signal model of graphene transistor
  • Calculation method for cut-off frequency of small signal model of graphene transistor

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Embodiment Construction

[0030] The technical side of the present invention will be described in detail below with reference to the accompanying drawings and in conjunction with schematic embodiments. In order to make the purpose, technical solution and advantages of the present invention clearer, the present invention will be further described in detail below with reference to the accompanying drawings.

[0031] like figure 1 As shown, the flow chart of the calculation method for obtaining the cut-off frequency of the improved small-signal model of the graphene transistor in the embodiment of the present invention includes the following steps:

[0032] Step 1: forming a plurality of MOSFETs with graphene material as the active region on the wafer substrate, wherein a source-drain metal contact is formed on each active region;

[0033] Step 2: Measure the cut-off frequency of each MOSFET;

[0034] Step 3: In view of the special properties of the original small signal model and the graphene contact ca...

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Abstract

A calculation method for a cut-off frequency of a small signal model of a graphene transistor comprises: forming a plurality of MOSFETs (Metal-Oxide -Semiconductor Field Effect Transistors) that use graphene materials as active regions, wherein source and drain metal contacts are formed on each active region; measuring a cut-off frequency of each MOSFET; modifying a conventional small signal model to obtain a new small signal equivalent model with respect to particular properties of an original small signal model and a contact capacity between the graphene active region and the source and drain metal contact; obtaining a new numerical solution of the cut-off frequency based on the new small signal equivalent model by using a conventional circuit analysis method, and KCL (Kirchhoff's Circuit Law) and LVL (Kirchhoff Voltage Law) analysis methods; and comparing the numerical solution of the cut-off frequency with a measured value of the cut-off frequency, and feeding back and modifying the small signal equivalence model. By using the method provided by the present invention, the cut-off frequency of the graphene transistor can be accurately calculated and fitted, and the method is suitable for high-frequency study of the graphene transistor. The method provided by the present invention is reasonable in theories, accurate in results, simple for operation, and facilitates establishment of a complete graphene transistor small signal simulation model.

Description

technical field [0001] The invention relates to the technical field of modeling and simulation of semiconductor electronic devices, in particular to a calculation method for the cutoff frequency of an improved small signal model of a graphene transistor. Background technique [0002] Graphene, as a typical two-dimensional material, has received continuous attention from the scientific community. Graphene has excellent electrical, thermal and mechanical properties, such as up to 100,000 cm at room temperature 2 The carrier mobility of / V s enables graphene to be used in touch panels, transparent conductive films and other fields. Graphene has a current density limit much greater than that of Cu, enabling low-cost wires that can pass higher currents than Cu. In the field of devices, the manufacturing process of graphene transistors is also becoming more and more perfect. In 2013, IBM produced the first graphene mixer integrated circuit. The application of graphene transisto...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G06F17/50
Inventor 汪令飞王伟徐光伟李泠刘明卢年端
Owner INST OF MICROELECTRONICS CHINESE ACAD OF SCI
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