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Assessing atomically thin delta-doping of silicon using mid-infrared ellipsometry

Journal of Materials Research

Katzenmeyer, Aaron M.; Luk, Ting S.; Bussmann, Ezra B.; Young, Steve M.; Anderson, Evan M.; Marshall, Michael T.; Ohlhausen, J.A.; Kotula, Paul G.; Lu, Ping L.; Campbell, DeAnna M.; Lu, Tzu-Ming L.; Liu, Peter Q.; Ward, Daniel R.; Misra, Shashank M.

Hydrogen lithography has been used to template phosphine-based surface chemistry to fabricate atomic-scale devices, a process we abbreviate as atomic precision advanced manufacturing (APAM). Here, we use mid-infrared variable angle spectroscopic ellipsometry (IR-VASE) to characterize single-nanometer thickness phosphorus dopant layers (δ-layers) in silicon made using APAM compatible processes. A large Drude response is directly attributable to the δ-layer and can be used for nondestructive monitoring of the condition of the APAM layer when integrating additional processing steps. The carrier density and mobility extracted from our room temperature IR-VASE measurements are consistent with cryogenic magneto-transport measurements, showing that APAM δ-layers function at room temperature. Finally, the permittivity extracted from these measurements shows that the doping in the APAM δ-layers is so large that their low-frequency in-plane response is reminiscent of a silicide. However, there is no indication of a plasma resonance, likely due to reduced dimensionality and/or low scattering lifetime.

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Spectroscopy and capacitance measurements of tunneling resonances in an Sb-implanted point contact

Bishop, Nathaniel B.; Stevens, Jeffrey S.; Childs, Kenton D.; Ohlhausen, J.A.; Lilly, Michael L.; Carroll, Malcolm; Young, Ralph W.; Bielejec, Edward S.; Ten Eyck, Gregory A.; Wendt, J.R.; Rahman, Rajib R.; Grubbs, Robert K.

We fabricated a split-gate defined point contact in a double gate enhancement mode Si-MOS device, and implanted Sb donor atoms using a self-aligned process. E-beam lithography in combination with a timed implant gives us excellent control over the placement of dopant atoms, and acts as a stepping stone to focused ion beam implantation of single donors. Our approach allows us considerable latitude in experimental design in-situ. We have identified two resonance conditions in the point contact conductance as a function of split gate voltage. Using tunneling spectroscopy, we probed their electronic structure as a function of temperature and magnetic field. We also determine the capacitive coupling between the resonant feature and several gates. Comparison between experimental values and extensive quasi-classical simulations constrain the location and energy of the resonant level. We discuss our results and how they may apply to resonant tunneling through a single donor.

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2 Results
2 Results