Abstract

Minimizing recombination at semiconductor surfaces is required for the accurate determination of the bulk carrier lifetime. Proton donors, such as hydrofluoric acid and superacids, are well known to provide highly effective short-term surface passivation. We demonstrate here that aprotic solutions based on bis(trifluoromethanesulfonyl)methane (TFSM) in hexane or pentane can also result in excellent passivation of (100)-orientation silicon surfaces. We show that the optimized TFSM-pentane passivation scheme can measure effective lifetimes up to 20 ms, with a surface recombination velocity of 1.7 cm s−1 at an excess carrier density of 1015 cm−3. Fitting injection-dependent lifetime curves requires chemical passivation and field effect passivation from a negatively charged layer with a charge density of 1010–1011 q cm−2. The slightly higher recombination velocity of 2.3 cm s−1 measured with TFSM-hexane can be explained by a lower charge density in the passivating layer, suggesting that the steric hindrance associated with the solvent size could play a role in the passivation mechanism. Finally, phosphorus nuclear magnetic resonance experiments confirm that TFSM-based solutions have Lewis acidity without being superacids, which opens up opportunities for them to be used in materials systems sensitive to superacidic environments.

Highlights

  • These schemes can provide a surface recombination velocity, S, below 1 cm sÀ1.6,9,10 Non-acidic methods, such as halogen-alcohols, typically give best-case S values of 5–10 cm sÀ1.12–14

  • We demonstrate here that aprotic solutions based on bis(trifluoromethanesulfonyl)methane (TFSM) in hexane or pentane can result in excellent passivation of (100)-orientation silicon surfaces

  • Phosphorus nuclear magnetic resonance experiments confirm that TFSM-based solutions have Lewis acidity without being superacids, which opens up opportunities for them to be used in materials systems sensitive to superacidic environments

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Summary

Introduction

These schemes can provide a surface recombination velocity, S, below 1 cm sÀ1.6,9,10 Non-acidic methods, such as halogen-alcohols, typically give best-case S values of 5–10 cm sÀ1.12–14. Proton donors, such as hydrofluoric acid and superacids, are well known to provide highly effective short-term surface passivation.

Results
Conclusion

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