By Dr Fay Hudson

Conference Papers

Hudson FE; Buehler TM; Mckinnon RP; Gauja E; Peceros K; Macks LD; Chan VC; Mitic M; Dzurak A; Clark RG; Pakes CI; Yang C; Jamieson DN; Prawer S, 2002, 'Nanofabrication processes for single-ion implantation of silicon quantum computer devices', in 26th International Conference on the Physics of Semiconductors, Edinburgh, Scotland, presented at 26th International Conference on the Physics of Semiconductors, Edinburgh, Scotland, 29 July 2002 - 02 August 2002

Chan V; Hudson FE; Gauja E; Szymanksa J; Macks LD; Peceros K; Buehler TM; Mckinnon RP; Mitic M; Dzurak A; Clark RG; Yang C; Jamieson DN, 2002, 'Nanofabrication techniques for optimisation and miniturisation of silicon quantum computer devices with single-ion implants', in Neilson D (ed.), 15th Biennial Congress 2002-Physics and Industry Working Together, Australian Institute of Physics, pp. 433 - 436, presented at 15th Biennial Congress 2002-Physics and Industry Working Together, Australian Institute of Physics, 08 July 2002 - 11 July 2002

Jamieson DN; Pakes CI; Yang C; Donelan PG; Coulhurst A; George DP; Spizzirri PG; McCallum JC; Lay M; Millar V; Wellard CJ; Hollenberg L; Prawer S; Dzurak A; Hudson FE; Gauja E; Peceros K; Macks LD; Szymanksa J; Buehler TM; Mckinnon RP; Chan V; Mitic M; Reilly DJ; Simmons MY; Oberbeck L; Curson NJ; Schofield SR; Hamilton AR; Clark RG, 2002, 'Progress towards a revolutionary quantum computer silicon', in Neilson D (ed.), 15th Biennial Congress 2002-Physics and Industry Working Together, Australian Institute of Physics, pp. 343 - 345, presented at 15th Biennial Congress 2002-Physics and Industry Working Together, Australian Institute of Physics, 08 July 2002 - 11 July 2002

Hudson FE; Gauja E; Peceros K; Macks LD; Buehler TM; Mckinnon RP; Chan V; Mitic M; Dzurak A; Clark RG; Yang C; Pakes CI; McCallum JC; Jamieson DN; Prawer S, 2002, 'Top-down nanofabrication of single-ion implanted silicon quantum computer devices', in Neilson D (ed.), 15th Biennial Congress 2002-Physics and Industry Working Together, Australian Institute of Physics, pp. 437 - 440, presented at 15th Biennial Congress 2002-Physics and Industry Working Together, Australian Institute of Physics, 08 July 2002 - 11 July 2002

Working Papers

Cifuentes J; Tanttu T; Gilbert W; Huang J; Vahapoglu E; Leon R; Serrano S; Otter D; Dunmore D; Mai P; Schlattner F; Feng M; Itoh K; Abrosimov N; Pohl H-J; Thewalt M; Laucht A; Yang C-H; Escott C; Lim WH; Hudson F; Rahman R; Dzurak A; Saraiva A, 2023, Bounds to electron spin qubit variability for scalable CMOS architectures, http://dx.doi.org10.21203/rs.3.rs-3057916/v1, https://doi.org/10.21203/rs.3.rs-3057916/v1

Vahapoglu E; Slack-Smith JP; Leon RCC; Lim WH; Hudson FE; Day T; Cifuentes JD; Tanttu T; Yang CH; Saraiva A; Abrosimov NV; Pohl H-J; Thewalt MLW; Laucht A; Dzurak AS; Pla JJ, 2021, Coherent control of electron spin qubits in silicon using a global field, http://dx.doi.org, http://dx.doi.org/10.1038/s41534-022-00645-w

Creative Works (non-textual)

Wang Z; Feng M; Serrano S; Gilbert W; Leon RCC; Tanttu T; Mai P; Liang D; Huang JY; Su Y; Lim WH; Hudson FE; Escott CC; Morello A; Yang CH; Dzurak AS; Saraiva A; Laucht A, 2023, Jellybean Quantum Dots in Silicon for Qubit Coupling and On‐Chip Quantum Chemistry (Adv. Mater. 19/2023), at: https://doi.org/10.1002/adma.202370133

Preprints

Steinacker P; Goenka G; Su RY; Tanttu T; Lim WH; Serrano S; Botzem T; Cifuentes JD; Lim SQ; McCallum JC; Johnson BC; Hudson FE; Chan KW; Escott CC; Saraiva A; Yang CH; Mourik V; Morello A; Dzurak AS; Laucht A, 2025, Coupling a $^{73}$Ge nuclear spin to an electrostatically defined quantum dot

Stemp HG; Asaad S; van Blankenstein MR; Vaartjes A; Johnson MAI; Mądzik MT; Heskes AJA; Firgau HR; Su RY; Yang CH; Laucht A; Ostrove CI; Rudinger KM; Young K; Blume-Kohout R; Hudson FE; Dzurak AS; Itoh KM; Jakob AM; Johnson BC; Jamieson DN; Morello A, 2025, Tomography of entangling two-qubit logic operations in exchange-coupled donor electron spin qubits, http://dx.doi.org/10.48550/arxiv.2309.15463

Lin S-C; Steinacker P; Feng M; Dash A; Serrano S; Lim WH; Itoh KM; Hudson FE; Tanttu T; Saraiva A; Laucht A; Dzurak AS; Goan H-S; Yang CH, 2025, Interplay of Zeeman Splitting and Tunnel Coupling in Coherent Spin Qubit Shuttling, http://dx.doi.org/10.48550/arxiv.2507.15554

Stemp HG; Blankenstein MRV; Asaad S; Mądzik MT; Joecker B; Firgau HR; Laucht A; Hudson FE; Dzurak AS; Itoh KM; Jakob AM; Johnson BC; Jamieson DN; Morello A, 2025, Scalable entanglement of nuclear spins mediated by electron exchange, http://arxiv.org/abs/2503.06872v1

Wendoloski JP; Hillier J; Liles SD; Rendell M; Ashlea-Alava Y; Raes B; Li R; Kubicek S; Godfrin C; Jussot J; Beyne S; Wan D; Rahman MM; Yianni S; Chan KW; Hudson FE; Lim WH; Greve KD; Dzurak AS; Hamilton AR, 2025, Holes in silicon are heavier than expected: transport properties of extremely high mobility electrons and holes in silicon MOSFETs, http://arxiv.org/abs/2502.21173v1

Mai PY; Pereira PH; Alonso LA; Leon RCC; Yang CH; Hwang JCC; Dunmore D; Lemyre JC; Tanttu T; Huang W; Chan KW; Tan KY; Cifuentes JD; Hudson FE; Itoh KM; Laucht A; Pioro-Ladrière M; Escott CC; Feng M; Souza RDME; Dzurak A; Saraiva A, 2025, Enhancement of Electric Drive in Silicon Quantum Dots with Electric Quadrupole Spin Resonance, http://arxiv.org/abs/2502.01040v2

Lim WH; Tanttu T; Youn T; Huang JY; Serrano S; Dickie A; Yianni S; Hudson FE; Escott CC; Yang CH; Laucht A; Saraiva A; Chan KW; Cifuentes JD; Dzurak AS, 2024, A 2x2 quantum dot array in silicon with fully tuneable pairwise interdot coupling, http://arxiv.org/abs/2411.13882v2

Steinacker P; Stuyck ND; Lim WH; Tanttu T; Feng M; Nickl A; Serrano S; Candido M; Cifuentes JD; Hudson FE; Chan KW; Kubicek S; Jussot J; Canvel Y; Beyne S; Shimura Y; Loo R; Godfrin C; Raes B; Baudot S; Wan D; Laucht A; Yang CH; Saraiva A; Escott CC; Greve KD; Dzurak AS, 2024, A 300 mm foundry silicon spin qubit unit cell exceeding 99% fidelity in all operations, http://arxiv.org/abs/2410.15590v2

Vaartjes A; Nurizzo M; Zaw LH; Wilhelm B; Yu X; Holmes D; Schwienbacher D; Kringhøj A; Blankenstein MRV; Jakob AM; Hudson FE; Itoh KM; Murray RJ; Blume-Kohout R; Anand N; Dzurak AS; Jamieson DN; Scarani V; Morello A, 2024, Certifying the quantumness of a nuclear spin qudit through its uniform precession, http://arxiv.org/abs/2410.07641v2

Steinacker P; Tanttu T; Lim WH; Stuyck ND; Feng M; Serrano S; Vahapoglu E; Su RY; Huang JY; Jones C; Itoh KM; Hudson FE; Escott CC; Morello A; Saraiva A; Yang CH; Dzurak AS; Laucht A, 2024, Violating Bell's inequality in gate-defined quantum dots, http://arxiv.org/abs/2407.15778v2

Bartee SK; Gilbert W; Zuo K; Das K; Tanttu T; Yang CH; Stuyck ND; Pauka SJ; Su RY; Lim WH; Serrano S; Escott CC; Hudson FE; Itoh KM; Laucht A; Dzurak AS; Reilly DJ, 2024, Spin Qubits with Scalable milli-kelvin CMOS Control, http://dx.doi.org/10.48550/arxiv.2407.15151

Yu X; Wilhelm B; Holmes D; Vaartjes A; Schwienbacher D; Nurizzo M; Kringhøj A; Blankenstein MRV; Jakob AM; Gupta P; Hudson FE; Itoh KM; Murray RJ; Blume-Kohout R; Ladd TD; Anand N; Dzurak AS; Sanders BC; Jamieson DN; Morello A, 2024, Schrödinger cat states of a nuclear spin qudit in silicon, http://dx.doi.org/10.1038/s41567-024-02745-0

Liles S; Halverson D; Wang Z; Shamim A; Eggli R; Jin IK; Hillier J; Kumar K; Vorreiter I; Rendell M; Huang JY; Escott C; Hudson F; Lim WH; Culcer D; Dzurak A; Hamilton A, 2024, A singlet-triplet hole-spin qubit in MOS silicon, http://dx.doi.org/10.21203/rs.3.rs-3603337/v1

Hansen I; Seedhouse AE; Serrano S; Nickl A; Feng M; Huang JY; Tanttu T; Stuyck ND; Lim WH; Hudson FE; Itoh KM; Saraiva A; Laucht A; Dzurak AS; Yang CH, 2023, Entangling gates on degenerate spin qubits dressed by a global field, http://dx.doi.org/10.1038/s41467-024-52010-4

Liles SD; Halverson DJ; Wang Z; Shamim A; Eggli RS; Jin IK; Hillier J; Kumar K; Vorreiter I; Rendell M; Huang JH; Escott CC; Hudson FE; Lim WH; Culcer D; Dzurak AS; Hamilton AR, 2023, A singlet-triplet hole-spin qubit in MOS silicon, http://dx.doi.org/10.1038/s41467-024-51902-9

Stuyck ND; Seedhouse AE; Serrano S; Tanttu T; Gilbert W; Huang JY; Hudson F; Itoh KM; Laucht A; Lim WH; Yang CH; Saraiva A; Dzurak AS, 2023, Real-time feedback protocols for optimizing fault-tolerant two-qubit gate fidelities in a silicon spin system, http://dx.doi.org/10.1063/5.0179958

Seedhouse AE; Stuyck ND; Serrano S; Tanttu T; Gilbert W; Huang JY; Hudson FE; Itoh KM; Laucht A; Lim WH; Yang CH; Dzurak AS; Saraiva A, 2023, Wavelet correlation noise analysis for qubit operation variable time series, http://dx.doi.org/10.1038/s41598-024-79553-2

Dash A; Yianni S; Feng M; Hudson F; Saraiva A; Dzurak AS; Tanttu T, 2023, Silicon charge pump operation limit above and below liquid helium temperature, http://dx.doi.org/10.1103/PhysRevApplied.21.014040

Cifuentes JD; Tanttu T; Steinacker P; Serrano S; Hansen I; Slack-Smith JP; Gilbert W; Huang JY; Vahapoglu E; Leon RCC; Stuyck ND; Itoh K; Abrosimov N; Pohl H-J; Thewalt M; Laucht A; Yang CH; Escott CC; Hudson FE; Lim WH; Rahman R; Dzurak AS; Saraiva A, 2023, Impact of electrostatic crosstalk on spin qubits in dense CMOS quantum dot arrays, http://dx.doi.org/10.1103/PhysRevB.110.125414

Guo KS; Feng M; Huang JY; Gilbert W; Itoh KM; Hudson FE; Chan KW; Lim WH; Dzurak AS; Saraiva A, 2023, Methods for transverse and longitudinal spin-photon coupling in silicon quantum dots with intrinsic spin-orbit effect, http://arxiv.org/abs/2308.12626v1

Holmes D; Wilhelm B; Jakob AM; Yu X; Hudson FE; Itoh KM; Dzurak AS; Jamieson DN; Morello A, 2023, Improved placement precision of implanted donor spin qubits in silicon using molecule ions, http://arxiv.org/abs/2308.04117v1

Huang JY; Su RY; Lim WH; Feng M; Straaten BV; Severin B; Gilbert W; Stuyck ND; Tanttu T; Serrano S; Cifuentes JD; Hansen I; Seedhouse AE; Vahapoglu E; Abrosimov NV; Pohl H-J; Thewalt MLW; Hudson FE; Escott CC; Ares N; Bartlett SD; Morello A; Saraiva A; Laucht A; Dzurak AS; Yang CH, 2023, High-fidelity operation and algorithmic initialisation of spin qubits above one kelvin, http://dx.doi.org/10.1038/s41586-024-07160-2

Su RY; Huang JY; Stuyck ND; Feng MK; Gilbert W; Evans TJ; Lim WH; Hudson FE; Chan KW; Huang W; Itoh KM; Harper R; Bartlett SD; Yang CH; Laucht A; Saraiva A; Tanttu T; Dzurak AS, 2023, Characterizing non-Markovian Quantum Process by Fast Bayesian Tomography, http://arxiv.org/abs/2307.12452v2

Serrano S; Feng M; Lim WH; Seedhouse AE; Tanttu T; Gilbert W; Escott CC; Abrosimov NV; Pohl H-J; Thewalt MLW; Hudson FE; Saraiva A; Dzurak AS; Laucht A, 2023, Improved Single-Shot Qubit Readout Using Twin RF-SET Charge Correlations, http://dx.doi.org/10.1103/PRXQuantum.5.010301

Fuentes IFD; Botzem T; Johnson MAI; Vaartjes A; Asaad S; Mourik V; Hudson FE; Itoh KM; Johnson BC; Jakob AM; McCallum JC; Jamieson DN; Dzurak AS; Morello A, 2023, Navigating the 16-dimensional Hilbert space of a high-spin donor qudit with electric and magnetic fields, http://dx.doi.org/10.1038/s41467-024-45368-y

Cifuentes JD; Tanttu T; Gilbert W; Huang JY; Vahapoglu E; Leon RCC; Serrano S; Otter D; Dunmore D; Mai PY; Schlattner F; Feng M; Itoh K; Abrosimov N; Pohl H-J; Thewalt M; Laucht A; Yang CH; Escott CC; Lim WH; Hudson FE; Rahman R; Dzurak AS; Saraiva A, 2023, Bounds to electron spin qubit variability for scalable CMOS architectures, http://dx.doi.org/10.1038/s41467-024-48557-x

Tanttu T; Lim WH; Huang JY; Stuyck ND; Gilbert W; Su RY; Feng M; Cifuentes JD; Seedhouse AE; Seritan SK; Ostrove CI; Rudinger KM; Leon RCC; Huang W; Escott CC; Itoh KM; Abrosimov NV; Pohl H-J; Thewalt MLW; Hudson FE; Blume-Kohout R; Bartlett SD; Morello A; Laucht A; Yang CH; Saraiva A; Dzurak AS, 2023, Assessment of error variation in high-fidelity two-qubit gates in silicon, http://dx.doi.org/10.1038/s41567-024-02614-w

Jin IK; Kumar K; Rendell MJ; Huang JY; Escott CC; Hudson FE; Lim WH; Dzurak AS; Hamilton AR; Liles SD, 2022, Combining n-MOS Charge Sensing with p-MOS Silicon Hole Double Quantum Dots in a CMOS platform, http://dx.doi.org/10.1021/acs.nanolett.2c04417

Wang Z; Feng M; Serrano S; Gilbert W; Leon RCC; Tanttu T; Mai P; Liang D; Huang JY; Su Y; Lim WH; Hudson FE; Escott CC; Morello A; Yang CH; Dzurak AS; Saraiva A; Laucht A, 2022, Jellybean quantum dots in silicon for qubit coupling and on-chip quantum chemistry, http://dx.doi.org/10.1002/adma.202208557

Feng M; Yoneda J; Huang W; Su Y; Tanttu T; Yang CH; Cifuentes JD; Chan KW; Gilbert W; Leon RCC; Hudson FE; Itoh KM; Laucht A; Dzurak AS; Saraiva A, 2022, Control of dephasing in spin qubits during coherent transport in silicon, http://dx.doi.org/10.1103/PhysRevB.107.085427

Savytskyy R; Botzem T; Fuentes IFD; Joecker B; Pla JJ; Hudson FE; Itoh KM; Jakob AM; Johnson BC; Jamieson DN; Dzurak AS; Morello A, 2022, An electrically-driven single-atom `flip-flop' qubit, http://arxiv.org/abs/2202.04438v3

Gilbert W; Tanttu T; Lim WH; Feng M; Huang JY; Cifuentes JD; Serrano S; Mai PY; Leon RCC; Escott CC; Itoh KM; Abrosimov NV; Pohl H-J; Thewalt MLW; Hudson FE; Morello A; Laucht A; Yang CH; Saraiva A; Dzurak AS, 2022, On-demand electrical control of spin qubits, http://dx.doi.org/10.1038/s41565-022-01280-4

Johnson MAI; Mądzik MT; Hudson FE; Itoh KM; Jakob AM; Jamieson DN; Dzurak A; Morello A, 2021, Beating the thermal limit of qubit initialization with a Bayesian Maxwell's demon, http://dx.doi.org/10.1103/PhysRevX.12.041008

Hansen I; Seedhouse AE; Chan KW; Hudson F; Itoh KM; Laucht A; Saraiva A; Yang CH; Dzurak AS, 2021, Implementation of the SMART protocol for global qubit control in silicon, http://dx.doi.org/10.1063/5.0096467

Vahapoglu E; Slack-Smith JP; Leon RCC; Lim WH; Hudson FE; Day T; Cifuentes JD; Tanttu T; Yang CH; Saraiva A; Abrosimov NV; Pohl H-J; Thewalt MLW; Laucht A; Dzurak AS; Pla JJ, 2021, Coherent control of electron spin qubits in silicon using a global field, http://dx.doi.org/10.48550/arxiv.2107.14622

Evans TJ; Huang W; Yoneda J; Harper R; Tanttu T; Chan KW; Hudson FE; Itoh KM; Saraiva A; Yang CH; Dzurak AS; Bartlett SD, 2021, Fast Bayesian tomography of a two-qubit gate set in silicon, http://dx.doi.org/10.1103/PhysRevApplied.17.024068

Mądzik MT; Asaad S; Youssry A; Joecker B; Rudinger KM; Nielsen E; Young KC; Proctor TJ; Baczewski AD; Laucht A; Schmitt V; Hudson FE; Itoh KM; Jakob AM; Johnson BC; Jamieson DN; Dzurak AS; Ferrie C; Blume-Kohout R; Morello A, 2021, Precision tomography of a three-qubit donor quantum processor in silicon, http://dx.doi.org/10.1038/s41586-021-04292-7

Huang JY; Lim WH; Leon RCC; Yang CH; Hudson FE; Escott CC; Saraiva A; Dzurak AS; Laucht A, 2021, A high-sensitivity charge sensor for silicon qubits above one kelvin, http://dx.doi.org/10.1021/acs.nanolett.1c01003

Vahapoglu E; Slack-Smith JP; Leon RCC; Lim WH; Hudson FE; Day T; Tanttu T; Yang CH; Laucht A; Dzurak AS; Pla JJ, 2020, Single-electron spin resonance in a nanoelectronic device using a global field, http://dx.doi.org/10.1126/sciadv.abg9158

Liles SD; Martins F; Miserev DS; Kiselev AA; Thorvaldson ID; Rendell MJ; Jin IK; Hudson FE; Veldhorst M; Itoh KM; Sushkov OP; Ladd TD; Dzurak AS; Hamilton AR, 2020, Electrical control of the $g$-tensor of a single hole in a silicon MOS quantum dot, http://dx.doi.org/10.1103/PhysRevB.104.235303

Leon RCC; Yang CH; Hwang JCC; Lemyre JC; Tanttu T; Huang W; Huang JY; Hudson FE; Itoh KM; Laucht A; Pioro-Ladrière M; Saraiva A; Dzurak AS, 2020, Bell-state tomography in a silicon many-electron artificial molecule, http://dx.doi.org/10.1038/s41467-021-23437-w

Yoneda J; Huang W; Feng M; Yang CH; Chan KW; Tanttu T; Gilbert W; Leon RCC; Hudson FE; Itoh KM; Morello A; Bartlett SD; Laucht A; Saraiva A; Dzurak AS, 2020, Coherent spin qubit transport in silicon, http://dx.doi.org/10.1038/s41467-021-24371-7

Mądzik MT; Laucht A; Hudson FE; Jakob AM; Johnson BC; Jamieson DN; Itoh KM; Dzurak AS; Morello A, 2020, Conditional quantum operation of two exchange-coupled single-donor spin qubits in a MOS-compatible silicon device, http://dx.doi.org/10.1038/s41467-020-20424-5

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