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Large scale quantum computing in silicon with imprecise qubit couplings ArXiv :1506.04913 (2015)

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1 Large scale quantum computing in silicon with imprecise qubit couplings ArXiv :1506.04913 (2015)

2 Silicon quantum computing 2010 2015 Single-shot readout of an electron spin in silicon Morello et al., Nature 467, 687 A single-atom electron spin qubit in silicon Pla et al., Nature 489, 541 2012 High-fidelity readout and control of a nuclear spin qubit in silicon Pla et al., Nature 496, 334 2013 Storing quantum information for 30 seconds in a nanoelectronic device 2014 Muhonen et al., Nat. Nanotech. 9, 986 An addressable quantum dot qubit with fault-tolerant control-fidelity Veldhorst et al., Nat. Nanotech. 9, 981 Veldhorst et al., arXiv :1411.5760 To appear in Nature A two-qubit logic gate in silicon SCALING UP!

3 Koiller et al., PRL 88, 027903 (2002) Donor spins in silicon : long memories are hard to couple Valley degeneracy affects exchange spin interactions Pica et al., PRB 89, 235306 (2014)

4 Electron spins in silicon quantum dots : malleable qubits are more fragile Couplings can be engineered Petta et al., Science 309, 2180 (2005) Veldhorst et al., arXiv :1411.5760 (2014)

5 If donors and dots are permanently mixed, donor coherence is lost Coupling «on demand» allows different degrees of freedom to be addressed when convenient Making an useful hybrid oxide - - + Si oxide -- + Si d + Dot voltage DOT DONOR J

6 Highly coherent donors Morley et al., Nature Materials 9, 725 (2010) Wolfowicz et al., Nature Nanotech. 8, 561 (2013) I=9/2 large spin Hilbert space Largest hyperfine coupling – fast (GHz) nuclear spin rotations High fidelity spin rotations A Bi DOT DONOR Clock transition

7 Three qubits Si:Bi clock transitions Bismuth and dot levels can cross at clock transition A DOT Quantum dot

8 Qubit coupling : controlled SWAP Dot-allowed avoided crossing Dot-forbidden crossing J

9 The importance of being adiabatic J CNOT from 3-qubit adiabatic controlled SWAP is more robust «Same» final state population if J is pulsed in μs (Landau-Zener physics)

10 High fidelity donor - dot CNOT “NMR” Global Pulsed ENDOR (CNOT on donor) Δ J 10 mT 10 mV x01x01 x00x00 0x10x1 NMR-controlled swap Dot “ESR” 0xx10xx1x0x1x0x1 x000x000 NMR-controlled swap x00x00 π Phase erasing steps

11 Adiabaticity gives large scale fault - tolerance SiO 2 Si ALD + SiO 2 + + + + + + + + + + + oxide + Si + Exchange couplings vary violently on sub-nm scale

12 Adiabaticity gives large scale fault - tolerance + + + + Uniform local magnetic fields 10 MHz local frequency shifts + + + + Realistic local shifts are < 1 MHz Extreme robustness to locally inhomogeneous magnetic fields

13 Donor - dot scaled architecture J J Adiabatic switching of electrodes is uniform across the array (minimal wiring)

14 One - page surface code Data bits are inspected on a rolling basis by measuring the measurement bits Data qubits Measurement qubits Locally entangled sets of physical qubits host collective logical qubit states Best proven single-qubit error threshold (~1%) Fowler et al., Phys. Rev. A 86, 032324 (2012)

15 Donor - dot surface code Data qubits Quantum Dots Measurement qubits Long coherence donors J J J J

16 CNOT fidelity >99.9% across almost the entire array > 99.5% donor readout fidelity Pla et al., Nature 489, 541 (2012) Watson et al., PRL (2015) A full surface code cycle (10 μs ) 1. The array of interface electron spins is rigidly shifted to neighbouring dots CCD gates should allow fast transport ( ~ 100 ps) 2. CNOTs between the donor-dot pairs to address allow entanglement of the MQ and the DQ The other pairs work as defects – uncostrained degrees of freedom 3. After a cycle of four nearest-neighbour movements the initial configuration is achieved 4. Measurement qubits (donors) are measured to check for errors occurred in the data qubits (dots) J J Fault tolerance

17 ArXiv :1506.04913 (2015) ArXiv :1506.04913 (2015) Presented a novel two-qubit gate between long memory donor states and scalable dot spins Adiabatic tuning of the donor-dot exchange interaction allows high fidelity CNOTs across most of the array, in spite of the vast coupling range Presented a fully scaled silicon architecture to implement the best error correction to date All manipulations are global but for easily controlled local voltage pulses – 10 μs / cycle + Si + oxide - - J

18 Further work Further work J Alternatives to electron transport between neighbouring quantum dots Cycle speed currently limited by ability to sweep the magnetic field (heating) – better ideas?

19 Acknowledgements Brendon Lovett University of St Andrews Stephen Lyon Princeton University Ravindra Bhatt Princeton University Thomas Schenkel Berkeley National Laboratory

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