Bias-Temperature Stability of Ti–Si–N–O Films

Bias-Temperature Stability of Ti–Si–N–O Films

Copper shows a tendency to drift into contiguous dielectric material under bias and temperature stressing. The stability of different compositions (by changing silane gas flow rate) of Ti-Si-N-O films has been investigated using metal-oxide-semiconductor (MOS) capacitors. MOS samples preannealed at...

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Veröffentlicht in:Journal of the Electrochemical Society 2006, Vol.153 (5), p.G470-G474
Hauptverfasser: Ee, Y. C., Juneja, Jasbir S., Wang, Pei-I, Lu, T.-M., Bakhru, H., Chan, L., Law, S. B., Yong, Clare, Chen, Z., Xu, S.
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container_end_page G474
container_issue 5
container_start_page G470
container_title Journal of the Electrochemical Society
container_volume 153
creator Ee, Y. C.
Juneja, Jasbir S.
Wang, Pei-I
Lu, T.-M.
Bakhru, H.
Chan, L.
Law, S. B.
Yong, Clare
Chen, Z.
Xu, S.
description Copper shows a tendency to drift into contiguous dielectric material under bias and temperature stressing. The stability of different compositions (by changing silane gas flow rate) of Ti-Si-N-O films has been investigated using metal-oxide-semiconductor (MOS) capacitors. MOS samples preannealed at 250 deg C and subjected to bias temperature stressing (BTS) at 150 deg C, 200 deg C under an electrical field of 0.5 or 1MV/cm show stable capacitance-voltage behavior with no flatband voltage shift from as-annealed to 90 min of BTS for Ti-Si-N-O film with Si/Ti ratio of 0.48. The lack of flatband voltage shift indicates that Ti-Si-N-O film is able to prevent Cu ion penetration. It is found that the electrical stability of Ti-Si-N-O film is reduced with higher Si/Ti ratio. For Ti-Si-N-O film with Si/Ti ratio of 0.91, flatband voltage shifts 0.75V after 90 min of BTS at 150 deg C and 0.5 MV/cm, and this shift is attributed to the interface states at the Ti-Si-N-O/oxide interface that were generated during the plasma process and could not be fully healed after 250 deg C annealing. Thus, it is suggested that with low silane gas flow rate, an electrically stable Ti-Si-N-O film can be achieved with fewer interface states.
doi_str_mv 10.1149/1.2184070
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C.</au><au>Juneja, Jasbir S.</au><au>Wang, Pei-I</au><au>Lu, T.-M.</au><au>Bakhru, H.</au><au>Chan, L.</au><au>Law, S. B.</au><au>Yong, Clare</au><au>Chen, Z.</au><au>Xu, S.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Bias-Temperature Stability of Ti–Si–N–O Films</atitle><jtitle>Journal of the Electrochemical Society</jtitle><date>2006</date><risdate>2006</risdate><volume>153</volume><issue>5</issue><spage>G470</spage><epage>G474</epage><pages>G470-G474</pages><issn>0013-4651</issn><abstract>Copper shows a tendency to drift into contiguous dielectric material under bias and temperature stressing. The stability of different compositions (by changing silane gas flow rate) of Ti-Si-N-O films has been investigated using metal-oxide-semiconductor (MOS) capacitors. MOS samples preannealed at 250 deg C and subjected to bias temperature stressing (BTS) at 150 deg C, 200 deg C under an electrical field of 0.5 or 1MV/cm show stable capacitance-voltage behavior with no flatband voltage shift from as-annealed to 90 min of BTS for Ti-Si-N-O film with Si/Ti ratio of 0.48. The lack of flatband voltage shift indicates that Ti-Si-N-O film is able to prevent Cu ion penetration. It is found that the electrical stability of Ti-Si-N-O film is reduced with higher Si/Ti ratio. For Ti-Si-N-O film with Si/Ti ratio of 0.91, flatband voltage shifts 0.75V after 90 min of BTS at 150 deg C and 0.5 MV/cm, and this shift is attributed to the interface states at the Ti-Si-N-O/oxide interface that were generated during the plasma process and could not be fully healed after 250 deg C annealing. Thus, it is suggested that with low silane gas flow rate, an electrically stable Ti-Si-N-O film can be achieved with fewer interface states.</abstract><doi>10.1149/1.2184070</doi></addata></record>
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