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Addressable electron spin resonance using donors and donor molecules in silicon.


ABSTRACT: Phosphorus donor impurities in silicon are a promising candidate for solid-state quantum computing due to their exceptionally long coherence times and high fidelities. However, individual addressability of exchange coupled donors with separations ~15 nm is challenging. We show that by using atomic precision lithography, we can place a single P donor next to a 2P molecule 16 ± 1 nm apart and use their distinctive hyperfine coupling strengths to address qubits at vastly different resonance frequencies. In particular, the single donor yields two hyperfine peaks separated by 97 ± 2.5 MHz, in contrast to the donor molecule that exhibits three peaks separated by 262 ± 10 MHz. Atomistic tight-binding simulations confirm the large hyperfine interaction strength in the 2P molecule with an interdonor separation of ~0.7 nm, consistent with lithographic scanning tunneling microscopy images of the 2P site during device fabrication. We discuss the viability of using donor molecules for built-in addressability of electron spin qubits in silicon.

SUBMITTER: Hile SJ 

PROVIDER: S-EPMC6044739 | biostudies-literature | 2018 Jul

REPOSITORIES: biostudies-literature

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Addressable electron spin resonance using donors and donor molecules in silicon.

Hile Samuel J SJ   Fricke Lukas L   House Matthew G MG   Peretz Eldad E   Chen Chin Yi CY   Wang Yu Y   Broome Matthew M   Gorman Samuel K SK   Keizer Joris G JG   Rahman Rajib R   Simmons Michelle Y MY  

Science advances 20180713 7


Phosphorus donor impurities in silicon are a promising candidate for solid-state quantum computing due to their exceptionally long coherence times and high fidelities. However, individual addressability of exchange coupled donors with separations ~15 nm is challenging. We show that by using atomic precision lithography, we can place a single P donor next to a 2P molecule 16 ± 1 nm apart and use their distinctive hyperfine coupling strengths to address qubits at vastly different resonance frequen  ...[more]

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