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Full-Text Articles in Nanoscience and Nanotechnology
Extraction Of Carrier Mobility And Interface Trap Density In Ingaas Metal Oxide Semiconductor Structures Using Gated Hall Method, Thenappan Chidambaram
Extraction Of Carrier Mobility And Interface Trap Density In Ingaas Metal Oxide Semiconductor Structures Using Gated Hall Method, Thenappan Chidambaram
Legacy Theses & Dissertations (2009 - 2024)
III-V semiconductors are potential candidates to replace Si as a channel material in next generation CMOS integrated circuits owing to their superior carrier mobilities. Low density of states (DOS) and typically high interface and border trap densities (Dit) in high mobility group III-V semiconductors provide difficulties in quantification of Dit near the conduction band edge. The trap response above the threshold voltage of a MOSFET can be very fast, and conventional Dit extraction methods, based on capacitance/conductance response (CV methods) of MOS capacitors at frequencies <1MHz, cannot distinguish conducting and trapped carriers. In addition, the CV methods have to deal with high dispersion in the accumulation region that makes it a difficult task to measure the true oxide capacitance, Cox value. Another implication of these properties of III-V interfaces is an ambiguity of determination of electron density in the MOSFET channel. Traditional evaluation of carrier density by integration of the C-V curve, gives incorrect values for Dit and mobility. Here we employ gated Hall method to quantify the Dit spectrum at the high-κ oxide/III-V semiconductor interface for buried and surface channel devices using Hall measurement and capacitance-voltage data. Determination of electron density directly from Hall measurements allows for obtaining true mobility values
The Development Of Iii-V Semiconductor Mosfets For Future Cmos Applications, Andrew M. Greene
The Development Of Iii-V Semiconductor Mosfets For Future Cmos Applications, Andrew M. Greene
Legacy Theses & Dissertations (2009 - 2024)
Alternative channel materials with superior transport properties over conventional strained silicon are required for supply voltage scaling in low power complementary metal-oxide-semiconductor (CMOS) integrated circuits. Group III-V compound semiconductor systems offer a potential solution due to their high carrier mobility, low carrier effective mass and large injection velocity. The enhancement in transistor drive current at a lower overdrive voltage allows for the scaling of supply voltage while maintaining high switching performance. This thesis focuses on overcoming several material and processing challenges associated with III-V semiconductor development including a low thermal processing budget, high interface trap state density (Dit), low resistance …