Silicon qubit performance in the presence of inhomogeneous strain
Abstract not provided.
Publications
Image Analysis Automation and Machine Learning Techniques Applied to MOS Quantum Dot Tune-Up
Abstract not provided.
Single-Shot Readout of a S/T Qubit with a Cryogenic AC-Coupled Amplifier in a Lithographic MOS Double Quantum Dot
Abstract not provided.
Towards a disorder model for the Si/SiO2 interface
Abstract not provided.
Analyzing the fidelity of a singlet-triplet spin-orbit qubit in silicon using gate set tomography
Abstract not provided.
Spin-Orbit Qubits in the Sandia Silicon MOS Multi-QD Platform
Abstract not provided.
Implications of the spin-orbit interaction for singlet-triplet qubits in silicon
Abstract not provided.
Modeling of Low-Frequency Nuclear Magnetic Noise in Silicon Qubits
Abstract not provided.
Coupling MOS Quantum Dot and Phosphorous Donor Qubit Systems
Abstract not provided.
AC controlled spin-orbit qubits
Abstract not provided.
High-Fidelity Single-Shot Readout for a Spin Qubit via an Enhanced Latching Mechanism
Physical Review. X
Abstract not provided.
Generalized model for tuning tunnel rates in a silicon quantum dot
Abstract not provided.
Implications of the Spin-Orbit Effect for Singlet-Triplet Qubit Operation
Abstract not provided.
All-electrical universal control of a double quantum dot qubit in silicon MOS
Technical Digest - International Electron Devices Meeting, IEDM
Qubits based on transistor-like Si MOS nanodevices are promising for quantum computing. In this work, we demonstrate a double quantum dot spin qubit that is all-electrically controlled without the need for any external components, like micromagnets, that could complicate integration. Universal control of the qubit is achieved through spin-orbit-like and exchange interactions. Using single shot readout, we show both DC- and AC-control techniques. The fabrication technology used is completely compatible with CMOS.
Dynamics of a nuclear spin bath in enriched silicon
Abstract not provided.
Probing low noise at the MOS interface with a spin-orbit qubit
Abstract not provided.
Theory of a silicon MOS spin-orbit singlet-triplet qubit
Abstract not provided.
Probing low noise at the MOS interface with a Spin-Orbit Singlet-Triplet Qubit
Abstract not provided.
Implications of the spin-orbit effect for singlet-triplet qubit operation
Abstract not provided.
Single Shot Pauli-Blockade in Lithographically Formed Few Electron MOS Double-Quantum-Dot Using a Single Layer Design
Abstract not provided.
Atomic-precision fabrication and metrology for epitaxial Si quantum devices
Abstract not provided.
Cobalt micro-magnet integration on silicon MOS quantum dots
Abstract not provided.
Two-axis control of a coupled quantum dot - donor qubit in Si-MOS
Abstract not provided.
Studying Si/SiGe disordered alloys within effective mass theory
Abstract not provided.
Magnetic field and angular dependent singlet-triplet rotations in a donor-quantum dot qubit
Abstract not provided.
A split accumulation gate architecture for silicon MOS quantum dots
Abstract not provided.
Tunnel coupling tuning of a QD-donor S-T qubit
Abstract not provided.
Coupling MOS quantum dot and phosphorous donor qubit systems
Technical Digest - International Electron Devices Meeting, IEDM
Si-MOS based QD qubits are attractive due to their similarity to the current semiconductor industry. We introduce a highly tunable MOS foundry compatible qubit design that couples an electrostatic quantum dot (QD) with an implanted donor. We show for the first time coherent two-axis control of a two-electron spin logical qubit that evolves under the QD-donor exchange interaction and the hyperfine interaction with the donor nucleus. The two interactions are tuned electrically with surface gate voltages to provide control of both qubit axes. Qubit decoherence is influenced by charge noise, which is of similar strength as epitaxial systems like GaAs and Si/SiGe.
Valley splitting of single-electron Si MOS quantum dots
Applied Physics Letters
Silicon-based metal-oxide-semiconductor quantum dots are prominent candidates for high-fidelity, manufacturable qubits. Due to silicon's band structure, additional low-energy states persist in these devices, presenting both challenges and opportunities. Although the physics governing these valley states has been the subject of intense study, quantitative agreement between experiment and theory remains elusive. Here, we present data from an experiment probing the valley states of quantum dot devices and develop a theory that is in quantitative agreement with both this and a recently reported experiment. Through sampling millions of realistic cases of interface roughness, our method provides evidence that the valley physics between the two samples is essentially the same.
Coupling MOS quantum dot and phosphorous donor qubit systems
IEEE International Electron Devices Meeting
Si-MOS based QD qubits are attractive due to their similarity to the current semiconductor industry. We introduce a highly tunable MOS foundry compatible qubit design that couples an electrostatic quantum dot (QD) with an implanted donor. We show for the first time coherent two-axis control of a two-electron spin logical qubit that evolves under the QD-donor exchange interaction and the hyperfine interaction with the donor nucleus. The two interactions are tuned electrically with surface gate voltages to provide control of both qubit axes. Qubit decoherence is influenced by charge noise, which is of similar strength as epitaxial systems like GaAs and Si/SiGe.
A split accumulation gate architecture for silicon MOS quantum dots
Abstract not provided.
A split accumulation gate architecture for silicon MOS quantum dots
Abstract not provided.
Atomically Precise Single Donor Placement by STM Lithography
Abstract not provided.
Fabrication of quantum dots in undoped Si/Si0.8Ge0.2 heterostructures using a single metal-gate layer
Applied Physics Letters
Enhancement-mode Si/SiGe electron quantum dots have been pursued extensively by many groups for their potential in quantum computing. Most of the reported dot designs utilize multiple metal-gate layers and use Si/SiGe heterostructures with Ge concentration close to 30%. Here, we report the fabrication and low-temperature characterization of quantum dots in the Si/Si0.8Ge0.2 heterostructures using only one metal-gate layer. We find that the threshold voltage of a channel narrower than 1 μm increases as the width decreases. The higher threshold can be attributed to the combination of quantum confinement and disorder. We also find that the lower Ge ratio used here leads to a narrower operational gate bias range. The higher threshold combined with the limited gate bias range constrains the device design of lithographic quantum dots. We incorporate such considerations in our device design and demonstrate a quantum dot that can be tuned from a single dot to a double dot. The device uses only a single metal-gate layer, greatly simplifying device design and fabrication.
Fabrictaion of Counted Donor Devices using Top-Down Ion Implantation
Abstract not provided.
Fabrication of Quantum Dots in Undoped SiGe with a single metal layer
Abstract not provided.
Exploiting Adiabaticity and Spin Refocusing for Circuit Model Multi-Qubit Gates
Abstract not provided.
A singlet-triplet qubit coupled to the nuclear spin of a single phosphorus donor
Abstract not provided.
Designing a flying qubit at a silicon interface
Abstract not provided.
What can we do with a singlet-triplet qubit coupled to a nuclear spin qubit?
Abstract not provided.
Full Controllability of a Singlet-Triplet Qubit Coupled to a Nuclear Spin Qubit
Abstract not provided.
ESR Experiments on a Single Donor Electron in Isotopically Enriched Silicon
Abstract not provided.
ESR Experiments on a Single Donor Electron in Isotopically Enriched Silicon
Abstract not provided.
All-electrical control of a singlet/triplet qubit coupled to a single nuclear spin
Abstract not provided.
Predicting the valley splitting of silicon quantum dots directly from a device layout
Abstract not provided.
Controlling a singlet-triplet qubit coupled to a nuclear spin qubit
Abstract not provided.
ESR Experiments on a Single Donor Electron in Isotopically Enriched Silicon
Abstract not provided.
fabrication of counted donor devices using top-down ion implantation
Abstract not provided.
Fabrication of Counted Donor Devices Using Ion Implantation
Abstract not provided.
Silicon Device Modeling: From Atoms to Hilbert Spaces
Abstract not provided.
Cryogenic amplifiers for fast readout
Abstract not provided.
Readout and Characterization of a P Donor Qubit in 28Si
Abstract not provided.
Predicting the valley splitting of silicon quantum dots directly from a device layout
Abstract not provided.
Modeling open quantum system device operation with multivalley effective mass theory
Abstract not provided.
Fabrication and Trasnport in Counted Donor Devices using Top-Down Ion Implantation
Abstract not provided.
Electron Spin Resonance of a Phosphorous Donor Qubit in Enriched Silicon
Abstract not provided.
Electron Spin Resonance of a Phosphorous Donor Qubit in Enriched Silicon
Abstract not provided.
Few Electron Quantum Dot coupling to Donor Implanted Electron Spins
Abstract not provided.
Science and Engineering of Quantum Information Systems: Robust Devices and Operations
Abstract not provided.
The Quantum Computer Aided Design (QCAD) Framework for Quantum Device Modeling
Abstract not provided.
Gap protection and dynamical decoupling for reliable multi-qubit gates
Abstract not provided.
[Response to PRL referee request for more information]
Sandia journal manuscript; Not yet accepted for publication
Abstract not provided.
Efficient self-consistent quantum transport simulator for quantum devices
Journal of Applied Physics
Abstract not provided.
Spontaneous emission spectrum of a diabatically pulsed silicon charge qubit
Nature Physics
Abstract not provided.
QCAD Simulation and Optimization of Semiconductor Quantum Dots
Journal of Applied Physics
Abstract not provided.
Efficient Self-Consistent Quantum Transport Simulator for Quantum Well Devices
Abstract not provided.
The QCAD Framework for Quantum Device Modeling
Abstract not provided.
Pulsed Electron Transition Measurements in a Silicon Double Quantum Dot
Abstract not provided.
Dynamically corrected gates for singlet-triplet spin qubits with control-dependent errors
Abstract not provided.
Measurements of spin lifetime of an antimony-bound electron in silicon
Abstract not provided.
Distinguishing adiabaticity from relaxation in a Si double quantum dot charge qubit
Abstract not provided.
The QCAD Framework for Quantum Device Modeling
Abstract not provided.
Silicon-Based Low-Dimensional Electronic Devices: Fabrication Characterization and their Physical Behavior in the Quantum Regime
Abstract not provided.
Measurements of Spin Life Time of an Antimony-Bound Electron in Silicon
Abstract not provided.
Silicon-Based Low-Dimensional Electronic Devices: Fabrication Characterization and their Physical Behavior in the Quantum Regime
Abstract not provided.
Silicon-Based Low-Dimensional Electronic Devices: Fabrication Characterization and their Physical Behavior in the Quantum Regime
Abstract not provided.
The QCAD Framework for Quantum Device Modeling
Abstract not provided.
Asymmetry in Charge Sensing for Silicon MOS Double Quantum Dot with Finite Bias
Abstract not provided.
Pulsed electron transition measurements in a silicon double quantum dot
Abstract not provided.
Modeling of Relaxation in DQDs and Implications for Adiabaticity
Abstract not provided.
STM fabrication of double quantum dot charge qubits for adiabatic quantum computing
Abstract not provided.
Exchange Gate Design in Two Donor Qubits
Abstract not provided.
Optimized pulses for the control of uncertain qubits
Physical Review A - Atomic, Molecular, and Optical Physics
The construction of high-fidelity control fields that are robust to control, system, and/or surrounding environment uncertainties is a crucial objective for quantum information processing. Using the two-state Landau-Zener model for illustrative simulations of a controlled qubit, we generate optimal controls for π/2 and π pulses and investigate their inherent robustness to uncertainty in the magnitude of the drift Hamiltonian. Next, we construct a quantum-control protocol to improve system-drift robustness by combining environment-decoupling pulse criteria and optimal control theory for unitary operations. By perturbatively expanding the unitary time-evolution operator for an open quantum system, previous analysis of environment-decoupling control pulses has calculated explicit control-field criteria to suppress environment-induced errors up to (but not including) third order from π/2 and π pulses. We systematically integrate this criteria with optimal control theory, incorporating an estimate of the uncertain parameter to produce improvements in gate fidelity and robustness, demonstrated via a numerical example based on double quantum dot qubits. For the qubit model used in this work, postfacto analysis of the resulting controls suggests that realistic control-field fluctuations and noise may contribute just as significantly to gate errors as system and environment fluctuations.
The QCAD framework for quantum device modeling
Abstract not provided.
The QCAD framework for quantum device modeling
Computational Electronics (IWCE), 2012 15th International Workshop on
We present the Quantum Computer Aided Design (QCAD) simulator that targets modeling quantum devices, particularly Si double quantum dots (DQDs) developed for quantum computing. The simulator core includes Poisson, Schrodinger, and Configuration Interaction solvers which can be run individually or combined self-consistently. The simulator is built upon Sandia-developed Trilinos and Albany components, and is interfaced with the Dakota optimization tool. It is being developed for seamless integration, high flexibility and throughput, and is intended to be open source. The QCAD tool has been used to simulate a large number of fabricated silicon DQDs and has provided fast feedback for design comparison and optimization.
Quantum Decoherence of the Central Spin in a Sparse System of Dipolar Coupled Spins
Physical Review B
Abstract not provided.
Computer assisted design of poly-silicon gated enhancement-mode lateral double quantum dot devices for quantum computing
Abstract not provided.
Optimization of Realistic Silicon Double Quantum Dots through Simulation
Abstract not provided.
Effect of fixed charge gate oxide defects on the exchange energy of a multi-valley silicon double quantum dot
Abstract not provided.
Development of few-electron Si quantum dots for use as qubits
Abstract not provided.
Spin-Bath Decoherence of a Si/SiGe Quantum Dot
Abstract not provided.
Impact of charged defects on silicon MOS quantum dots
Abstract not provided.
Impact of Charged Defects on MOS Quantum Dots
Abstract not provided.
CAD tools for quantum dots
Abstract not provided.
Copy of Noisy (spin) neighbors of a solid state (spin) qubit
Abstract not provided.
Atomistic simulations of valley splitting in silicon quantum dots in the presence of disorder
Abstract not provided.
Combining DD with optimal control for improved QIP
Abstract not provided.
Electron spin decoherence in isotope-enriched silicon
Physical Review Letters
Abstract not provided.
Spectroscopy and capacitance measurements of tunneling resonances in an Sb-implanted point contact
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.
Atomistic simulations of coherent tunneling adiabatic passage in an imperfect donor chain
Abstract not provided.
Electron spin decoherence in isotopice-enriched silicon
Abstract not provided.
Atomistic simulations of coherent tunneling adiabatic passage in an imperfect donor chain
Abstract not provided.
Excited states and valley effects in a negatively charged impurity in a silicon FinFET
The observation and characterization of a single atom system in silicon is a significant landmark in half a century of device miniaturization, and presents an important new laboratory for fundamental quantum and atomic physics. We compare with multi-million atom tight binding (TB) calculations the measurements of the spectrum of a single two-electron (2e) atom system in silicon - a negatively charged (D-) gated Arsenic donor in a FinFET. The TB method captures accurate single electron eigenstates of the device taking into account device geometry, donor potentials, applied fields, interfaces, and the full host bandstructure. In a previous work, the depths and fields of As donors in six device samples were established through excited state spectroscopy of the D0 electron and comparison with TB calculations. Using self-consistent field (SCF) TB, we computed the charging energies of the D- electron for the same six device samples, and found good agreement with the measurements. Although a bulk donor has only a bound singlet ground state and a charging energy of about 40 meV, calculations show that a gated donor near an interface can have a reduced charging energy and bound excited states in the D- spectrum. Measurements indeed reveal reduced charging energies and bound 2e excited states, at least one of which is a triplet. The calculations also show the influence of the host valley physics in the two-electron spectrum of the donor.
Coherence of Donor Electron Spins in Isotopically Enriched Silicon
Abstract not provided.
Combining dynamical decoupling with optimal control for improved QIP
Constructing high-fidelity control pulses that are robust to control and system/environment fluctuations is a crucial objective for quantum information processing (QIP). We combine dynamical decoupling (DD) with optimal control (OC) to identify control pulses that achieve this objective numerically. Previous DD work has shown that general errors up to (but not including) third order can be removed from {pi}- and {pi}/2-pulses without concatenation. By systematically integrating DD and OC, we are able to increase pulse fidelity beyond this limit. Our hybrid method of quantum control incorporates a newly-developed algorithm for robust OC, providing a nested DD-OC approach to generate robust controls. Motivated by solid-state QIP, we also incorporate relevant experimental constraints into this DD-OC formalism. To demonstrate the advantage of our approach, the resulting quantum controls are compared to previous DD results in open and uncertain model systems.
Quantum Information Sciences Research at Sandia
Abstract not provided.
Coherence of Donor Electron Spins in Isotopically Enriched Silicon
Abstract not provided.
Brief Announcement: The Impact of Classical Electronics Constraints on a Solid-State Logical Qubit Memory
Abstract not provided.
Modeling physical qubits using tightbinding and effective mass theories
Abstract not provided.
109 Results