工作物质为“绝缘子-未掺杂硅绝缘子”的高频电容器

IF 0.2 Q4 INSTRUMENTS & INSTRUMENTATION
N. Poklonski, I. I. Anikeev, S. A. Vyrko
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引用次数: 0

摘要

研究具有各种工作物质的电容器的参数对电子元件的设计和制造,特别是对高频移相电路的开发具有重要意义。本工作的目的是用工作物质“绝缘子-未掺杂硅-绝缘子”计算不同施加于电容器直流(DC)电压下的高频电容,测量信号频率和温度。提出了这种电容器的模型,其中30µm厚的未掺杂(本征)晶体硅(i-Si)层与电容器的每个电极隔有1µm厚的绝缘层(二氧化硅)。计算了在绝对温度T = 300和400k时,零频率和测量信号频率为1mhz时,电容容量对金属电极上直流电压U的依赖关系。结果表明,在温度T = 300 K时,电容器电容的实部随U的变化呈单调递增,虚部随U的变化呈非单调递增。随着温度的升高,电容的实部电容增加到氧化层的几何电容,这是由于i-Si层的电阻降低所致。因此,当温度升高到400k时,电容的实部和虚部取与U无关的恒定值。温度T和电压U同时升高时,i-Si层的电容被该层的电导率分流。对于频率为0.3、1、10、30、100和300 MHz的正弦电信号,在温度为300和400 K时应用于电容器,确定相移。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
High-Frequency Capacitor with Working Substance "Insulator-Undoped Silicon-Insulator"
The study of the parameters of capacitors with various working substances is of interest for the design and creation of electronic elements, in particular for the development of high-frequency phase-shifting circuits.The purpose of the work is to calculate the high-frequency capacitance of a capacitor with the working substance "insulator-undoped silicon-insulator" at different applied to the capacitor direct current (DC) voltages, measuring signal frequencies and temperatures.A model of such the capacitor is proposed, in which 30 µm thick layer of undoped (intrinsic) crystalline silicon (i-Si) is separated from each of the capacitor electrodes by 1 µm thick insulator layer (silicon dioxide).The dependences of the capacitor capacitance on the DC electrical voltage U on metal electrodes at zero frequency and at the measuring signal frequency of 1 MHz at absolute temperatures T = 300 and 400 K are calculated. It is shown that the real part of the capacitor capacitance increases monotonically, while the imaginary part is negative and non-monotonically depends on U at the temperature T = 300 K. An increase in the real part of the capacitor capacitance up to the geometric capacitance of oxide layers with increasing temperature is due to a decrease in the electrical resistance of i-Si layer. As a result, with an increase in temperature up to 400 K, the real and imaginary parts of the capacitance take constant values independent of U. The capacitance of i-Si layer with an increase in both temperature T and voltage U is shunted by the electrical conductivity of this layer. The phase shift is determined for a sinusoidal electrical signal with a frequency of 0.3, 1, 10, 30, 100, and 300 MHz applied to the capacitor at temperatures 300 and 400 K.
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来源期刊
Devices and Methods of Measurements
Devices and Methods of Measurements INSTRUMENTS & INSTRUMENTATION-
自引率
25.00%
发文量
18
审稿时长
8 weeks
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