Free space microwave measurement of permittivity of gate dielectric for semiconductor technology / Fatimah ‘Audah Md. Zaki
A non-destructive and non-contacting technique for measuring the relative permittivity of an epitaxial layer on semiconductor has been developed. The samples were thermally grown SiO2 of different dopants and thicknesses. The measurement set up consists of spot-focusing horn antennas and a vector ne...
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| Format: | Thesis |
| Language: | English |
| Published: |
2012
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| Subjects: | |
| Online Access: | https://ir.uitm.edu.my/id/eprint/54161/1/54161.pdf |
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| Summary: | A non-destructive and non-contacting technique for measuring the relative permittivity of an epitaxial layer on semiconductor has been developed. The samples were thermally grown SiO2 of different dopants and thicknesses. The measurement set up consists of spot-focusing horn antennas and a vector network analyzer for measuring the reflected signals in free space. By applying some calculations, the dielectric constants and other electrical properties of silicon dioxide can be obtained. Results for p- and n-type SiO2are reported in the frequency range of 18 to 26 GHz. This measurement technique is able to differentiate between doped and undoped materials. It was found that the doped SiO2layer absorbed more signals than the undoped ones due to different conductivity values as the result of dopant addition. Moreover, different result is shown by n- and p-type wafers which are caused by depletion and pileup effect in the semiconductor as the outcome of the oxidation of silicon surface. The dielectric constants of the SiO2 films were found to be approximately 3.8 at 22 GHz, which agrees with other researchers. The research also found that this method can distinguish different oxide thicknesses, where fewer signals are being reflected for thicker oxides. It was observed that the Sn reduction is insignificant for oxide thickness greater than the skin depth. Furthermore, the conductivity and loss tan of Si02 increases with increasing oxide thickness. The method is able to measure relative permittivity of double-layered dielectric or media, provided the layer thickness does not exceed skin depth. This shows that the measurement technique is reliable because it is sensitive to the properties of the epitaxial layer only. |
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