Method for measuring low background carrier concentration by utilizing optical excitation differential capacitance method

Abstract

The invention discloses a method for measuring the low background carrier concentration in a semiconductor material device, and the method comprises the following steps: measuring the flat belt voltage on the surface of a region to be measured and the differential capacitance response under the optical excitation condition; establishing a numerical value model of the region to be measured and theadjacent region; and comparing the surface differential capacitance under the optical excitation condition of the region to be measured of the numerical value model and the practical measurement so as to determine the balanced carrier concentration. The method disclosed by the invention is suitable for the accurate measurement of the specific function region in the semiconductor material or device provided with a complicated structure, and the background carrier concentration of the specific function region is lower than 1015cm<-3>; and method can be used for detecting a single microcosmic block in an integrated or array device.

Description

technical field [0001] The invention relates to a method for measuring characteristic parameters of semiconductor material devices, in particular to the measurement of extremely low background carrier concentration in a specific region of a semiconductor material device. It belongs to the field of semiconductor material characterization. Background technique [0002] Semiconductor devices realize their electrical or photoelectric functions through the transport, transition and relaxation of free electrons, that is, carriers. Therefore, measuring and controlling the carrier concentration in each functional area is one of the important contents of semiconductor materials and device processes. In some specific regions of semiconductor devices, such as the absorption region of semiconductor photodetectors, a very low background carrier concentration (≤10 15 cm -3 ) to obtain key performances such as low noise, high mobility and long minority carrier lifetime; for this purpose,...

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Problems solved by technology

[0004] The electrochemical capacitance-bias ECV method can provide the carrier distribution in the depth direction of the sample with high accuracy, and the resolution can be down to the nanometer level, and its detectable concentration range can be as low as 10 in principle. 12 cm -3 ; but limited by the Debye length (P.Blood, Semicond.Sci.Technol.1 (1986) 7-27), low concentration measurement requires an increase in the thickness of the region, such as 1 × 10 15 cm -3 carrier concentration, the Debye length corresponding to the Schottky barrier with a height of only 0.1eV has reached 0.32 microns; Influenced by factors such as deviation, the error of ECV detection also increases greatly, so there is no ECV method with 1×10 15 cm

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