Search

Your search keyword '"Deng, Mingtang"' showing total 42 results
Start Over Author "Deng, Mingtang"
42 results on '"Deng, Mingtang"'

1. Quantum transport in an ambipolar InSb nanowire quantum dot device

Author

Deng, Mingtang, Yu, Chunlin, Huang, Guangyao, Caroff, P., and Xu, H. Q.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Semiconductor InSb nanowires present a highly intriguing platform with immense potential for applications in spintronics and topological quantum devices. The narrow band gap exhibited by InSb allows for precise tuning of these nanowires, facilitating smooth transitions between the electron transport region and the hole transport region. In this study, we demonstrate quantum transport measurements obtained from a high-quality InSb nanowire quantum dot device. By utilizing a back gate, this device can be adjusted from an electron-populated quantum dot regime to a hole-populated one. Within both regimes, we have observed dozens of consecutive quantum levels without any charge rearrangement or impurity-induced interruptions. Our investigations in the electron transport regime have explored phenomena such as Coulomb blockade effect, Zeeman effect,and Kondo effect. Meanwhile, in the hole-transport regime, we have identified conductance peaks induced by lead states. Particularly, we have created a tomographic analysis method of these lead states by tracking the behavior of these conductance peaks across consecutive Coulomb diamond structures.

Published
2024

2. Cryogenic Control and Readout Integrated Circuits for Solid-State Quantum Computing

Author

Lei, Lingxiao, Huang, Heng, Chen, Pingxing, and Deng, Mingtang

Subjects
Quantum Physics, Electrical Engineering and Systems Science - Systems and Control
Abstract

In the pursuit of quantum computing, solid-state quantum systems, particularly superconducting ones, have made remarkable advancements over the past two decades. However, achieving fault-tolerant quantum computing for next-generation applications necessitates the integration of several million qubits, which presents significant challenges in terms of interconnection complexity and latency that are currently unsolvable with state-of-the-art room-temperature control and readout electronics. Recently, cryogenic integrated circuits (ICs), including CMOS radio-frequency ICs and rapid-single-flux-quantum-logic ICs, have emerged as potential alternatives to room-temperature electronics. Unlike their room-temperature counterparts, these ICs are deployed within cryostats to enhance scalability by reducing the number and length of transmission lines. Additionally, operating at cryogenic temperatures can suppress electronic noise and improve qubit control fidelity. However, for CMOS ICs specifically, circuit design uncertainties arise due to a lack of reliable models for cryogenic field effect transistors as well as issues related to severe fickle noises and power dissipation at cryogenic temperatures. This paper provides a comprehensive review of recent research on both types of cryogenic control and readout ICs but primarily focuses on the more mature CMOS technology. The discussion encompasses principles underlying control and readout techniques employed in cryogenic CMOS ICs along with their architectural designs; characterization and modeling approaches for field effect transistors under cryogenic conditions; as well as fundamental concepts pertaining to rapid single flux quantum circuits.

Published
2024

3. Simulating a Chern Insulator with C = $\pm$2 on Synthetic Floquet Lattice

Author

Lei, Lingxiao, Wang, Weichen, Huang, Guangyao, Hu, Shun, Cao, Xi, Zhang, Xinfang, Deng, Mingtang, and Chen, Pingxing

Subjects
Quantum Physics
Abstract

The synthetic Floquet lattice, generated by multiple strong drives with mutually incommensurate frequencies, provides a powerful platform for the quantum simulation of topological phenomena. In this study, we propose a 4-band tight-binding model of the Chern insulator with a Chern number C = $\pm$2 by coupling two layers of the half-BHZ lattice and subsequently mapping it onto the Floquet lattice to simulate its topological properties. To determine the Chern number of our Floquet-version model, we extend the energy pumping method proposed by Martin et al. [Phys. Rev. X 7, 041008 (2017)] and the topological oscillation method introduced by Boyers et al. [Phys. Rev. Lett. 125, 160505 (2020)], followed by numerical simulations for both methodologies. The simulation results demonstrate the successful extraction of the Chern number using either of these methods, providing an excellent prediction of the phase diagram that closely aligns with the theoretical one derived from the original bilayer half-BHZ model. Finally, we briefly discuss a potential experimental implementation for our model. Our work demonstrates significant potential for simulating complex topological matter using quantum computing platforms, thereby paving the way for constructing a more universal simulator for non-interacting topological quantum states and advancing our understanding of these intriguing phenomena.

Published
2024
Full Text
View/download PDF

4. Scheme for braiding Majorana zero modes in vortices using an STT-matrix

Author

Huang, Guangyao, Zhang, Xinfang, Yi, Xiaofeng, Fu, Jibang, Wang, Weichen, and Deng, Mingtang

Subjects
Condensed Matter - Superconductivity, Quantum Physics
Abstract

Recently conducted experiments on two-dimensional topological superconductors have revealed various indications of Majorana zero modes (MZMs). However, progress in the manipulation of MZM braiding has been limited, impeding the realization of topological quantum computing. In this study, we propose a potential braiding scheme based on a spintronic device matrix. This scheme involves utilizing a matrix composed of spin-transfer torque devices (STT-matrix) alongside a two-dimensional topological superconductor material. By programming the ON/OFF states of the spintronic devices within the STT-matrix, it becomes possible to manipulate vortices hosting MZMs in the two-dimensional topological superconductor. To further investigate this concept, we construct a time-dependent Ginzburg-Landau model and perform numerical simulations to analyze vortex-driving dynamics, MZM braiding processes, and MZM fusion phenomena. Our findings demonstrate that this system exhibits high versatility and flexibility in manipulating vortices. With advancements in spintronic device technology, our proposed scheme offers a feasible and practical method for operating MZMs within vortices present in topological superconductors.

Published
2024

5. Randomised benchmarking for characterizing and forecasting correlated processes

Author

Zhang, Xinfang, Wu, Zhihao, White, Gregory A. L., Xiang, Zhongcheng, Hu, Shun, Peng, Zhihui, Liu, Yong, Zheng, Dongning, Fu, Xiang, Huang, Anqi, Poletti, Dario, Modi, Kavan, Wu, Junjie, Deng, Mingtang, and Guo, Chu

Subjects
Quantum Physics
Abstract

The development of fault-tolerant quantum processors relies on the ability to control noise. A particularly insidious form of noise is temporally correlated or non-Markovian noise. By combining randomized benchmarking with supervised machine learning algorithms, we develop a method to learn the details of temporally correlated noise. In particular, we can learn the time-independent evolution operator of system plus bath and this leads to (i) the ability to characterize the degree of non-Markovianity of the dynamics and (ii) the ability to predict the dynamics of the system even beyond the times we have used to train our model. We exemplify this by implementing our method on a superconducting quantum processor. Our experimental results show a drastic change between the Markovian and non-Markovian regimes for the learning accuracies., Comment: 4 pages, 3 figures

Published
2023

6. Experimental quantum natural gradient optimization in photonics

Author

Wang, Yizhi, Xue, Shichuan, Wang, Yaxuan, Ding, Jiangfang, Shi, Weixu, Wang, Dongyang, Liu, Yong, Liu, Yingwen, Fu, Xiang, Huang, Guangyao, Huang, Anqi, Deng, Mingtang, and Wu, Junjie

Subjects
Quantum Physics, Computer Science - Machine Learning, Physics - Optics
Abstract

Variational quantum algorithms (VQAs) combining the advantages of parameterized quantum circuits and classical optimizers, promise practical quantum applications in the Noisy Intermediate-Scale Quantum era. The performance of VQAs heavily depends on the optimization method. Compared with gradient-free and ordinary gradient descent methods, the quantum natural gradient (QNG), which mirrors the geometric structure of the parameter space, can achieve faster convergence and avoid local minima more easily, thereby reducing the cost of circuit executions. We utilized a fully programmable photonic chip to experimentally estimate the QNG in photonics for the first time. We obtained the dissociation curve of the He-H$^+$ cation and achieved chemical accuracy, verifying the outperformance of QNG optimization on a photonic device. Our work opens up a vista of utilizing QNG in photonics to implement practical near-term quantum applications.

Published
2023
Full Text
View/download PDF

7. Quantum generative adversarial learning in photonics

Author

Wang, Yizhi, Xue, Shichuan, Wang, Yaxuan, Liu, Yong, Ding, Jiangfang, Shi, Weixu, Wang, Dongyang, Liu, Yingwen, Fu, Xiang, Huang, Guangyao, Huang, Anqi, Deng, Mingtang, and Wu, Junjie

Subjects
Quantum Physics, Computer Science - Artificial Intelligence, Computer Science - Emerging Technologies, Computer Science - Machine Learning, Physics - Optics
Abstract

Quantum Generative Adversarial Networks (QGANs), an intersection of quantum computing and machine learning, have attracted widespread attention due to their potential advantages over classical analogs. However, in the current era of Noisy Intermediate-Scale Quantum (NISQ) computing, it is essential to investigate whether QGANs can perform learning tasks on near-term quantum devices usually affected by noise and even defects. In this Letter, using a programmable silicon quantum photonic chip, we experimentally demonstrate the QGAN model in photonics for the first time, and investigate the effects of noise and defects on its performance. Our results show that QGANs can generate high-quality quantum data with a fidelity higher than 90\%, even under conditions where up to half of the generator's phase shifters are damaged, or all of the generator and discriminator's phase shifters are subjected to phase noise up to 0.04$\pi$. Our work sheds light on the feasibility of implementing QGANs on NISQ-era quantum hardware.

Published
2023
Full Text
View/download PDF

9. Large-scale full-programmable quantum walk and its applications

Author

Wang, Yizhi, Liu, Yingwen, Zhan, Junwei, Xue, Shichuan, Zheng, Yuzhen, Zeng, Ru, Wu, Zhihao, Wang, Zihao, Zheng, Qilin, Wang, Dongyang, Shi, Weixu, Fu, Xiang, Xu, Ping, Wang, Yang, Liu, Yong, Ding, Jiangfang, Huang, Guangyao, Yu, Chunlin, Huang, Anqi, Qiang, Xiaogang, Deng, Mingtang, Xu, Weixia, Lu, Kai, Yang, Xuejun, and Wu, Junjie

Subjects
Quantum Physics, Computer Science - Emerging Technologies, Physics - Optics
Abstract

With photonics, the quantum computational advantage has been demonstrated on the task of boson sampling. Next, developing quantum-enhanced approaches for practical problems becomes one of the top priorities for photonic systems. Quantum walks are powerful kernels for developing new and useful quantum algorithms. Here we realize large-scale quantum walks using a fully programmable photonic quantum computing system. The system integrates a silicon quantum photonic chip, enabling the simulation of quantum walk dynamics on graphs with up to 400 vertices and possessing full programmability over quantum walk parameters, including the particle property, initial state, graph structure, and evolution time. In the 400-dimensional Hilbert space, the average fidelity of random entangled quantum states after the whole on-chip circuit evolution reaches as high as 94.29$\pm$1.28$\%$. With the system, we demonstrated exponentially faster hitting and quadratically faster mixing performance of quantum walks over classical random walks, achieving more than two orders of magnitude of enhancement in the experimental hitting efficiency and almost half of the reduction in the experimental evolution time for mixing. We utilize the system to implement a series of quantum applications, including measuring the centrality of scale-free networks, searching targets on Erd\"{o}s-R\'{e}nyi networks, distinguishing non-isomorphic graph pairs, and simulating the topological phase of higher-order topological insulators. Our work shows one feasible path for quantum photonics to address applications of practical interests in the near future.

Published
2022

10. General Quantum Bernoulli Factory: Framework Analysis and Experiments

Author

Liu, Yong, Jiang, Jiaqing, Zhu, Pingyu, Wang, Dongyang, Ding, Jiangfang, Qiang, Xiaogang, Huang, Anqi, Xu, Ping, Zhang, Jialin, Tian, Guojing, Fu, Xiang, Deng, Mingtang, Wu, Chunqing, Sun, Xiaoming, Yang, Xuejun, and Wu, Junjie

Subjects
Quantum Physics
Abstract

The unremitting pursuit for quantum advantages gives rise to the discovery of a quantum-enhanced randomness processing named quantum Bernoulli factory (QBF). This quantum enhanced process can show its priority over the corresponding classical process through readily available experimental resources, thus in the near term it may be capable of accelerating the applications of classical Bernoulli factories, such as the widely used sampling algorithms. In this work, we provide the framework analysis of the QBF. We thoroughly analyze the quantum state evolution in this process, discovering the field structure of the constructible quantum states. Our framework analysis shows that naturally, the previous works can be described as specific instances of this framework. Then, as a proof of principle, we experimentally demonstrate this framework via an entangled two-photon source along with a reconfigurable photonic logic, and show the advantages of the QBF over the classical model through a classically infeasible instance. These results may stimulate the discovery of advantages of the quantum randomness processing in a wider range of tasks, as well as its potential applications., Comment: 9 pages, 4 figures

Published
2020
Full Text
View/download PDF

11. Variational Quantum Circuits for Quantum State Tomography

Author

Liu, Yong, Wang, Dongyang, Xue, Shichuan, Huang, Anqi, Fu, Xiang, Qiang, Xiaogang, Xu, Ping, Huang, He-Liang, Deng, Mingtang, Guo, Chu, Yang, Xuejun, and Wu, Junjie

Subjects
Quantum Physics, Computer Science - Machine Learning, Physics - Computational Physics
Abstract

Quantum state tomography is a key process in most quantum experiments. In this work, we employ quantum machine learning for state tomography. Given an unknown quantum state, it can be learned by maximizing the fidelity between the output of a variational quantum circuit and this state. The number of parameters of the variational quantum circuit grows linearly with the number of qubits and the circuit depth, so that only polynomial measurements are required, even for highly-entangled states. After that, a subsequent classical circuit simulator is used to transform the information of the target quantum state from the variational quantum circuit into a familiar format. We demonstrate our method by performing numerical simulations for the tomography of the ground state of a one-dimensional quantum spin chain, using a variational quantum circuit simulator. Our method is suitable for near-term quantum computing platforms, and could be used for relatively large-scale quantum state tomography for experimentally relevant quantum states., Comment: 7 pages, 3 figures

Published
2019
Full Text
View/download PDF

12. Sample caching Markov chain Monte Carlo approach to boson sampling simulation

Author

Liu, Yong, Xiong, Min, Wu, Chunqing, Wang, Dongyang, Liu, Yingwen, Ding, Jiangfang, Huang, Anqi, Fu, Xiang, Qiang, Xiaogang, Xu, Ping, Deng, Mingtang, Yang, Xuejun, and Wu, Junjie

Subjects
Quantum Physics
Abstract

Boson sampling is a promising candidate for quantum supremacy. It requires to sample from a complicated distribution, and is trusted to be intractable on classical computers. Among the various classical sampling methods, the Markov chain Monte Carlo method is an important approach to the simulation and validation of boson sampling. This method however suffers from the severe sample loss issue caused by the autocorrelation of the sample sequence. Addressing this, we propose the sample caching Markov chain Monte Carlo method that eliminates the correlations among the samples, and prevents the sample loss at the meantime, allowing more efficient simulation of boson sampling. Moreover, our method can be used as a general sampling framework that can benefit a wide range of sampling tasks, and is particularly suitable for applications where a large number of samples are taken., Comment: 5 pages, 4 figures

Published
2019
Full Text
View/download PDF

13. General-purpose quantum circuit simulator with Projected Entangled-Pair States and the quantum supremacy frontier

Author

Guo, Chu, Liu, Yong, Xiong, Min, Xue, Shichuan, Fu, Xiang, Huang, Anqi, Qiang, Xiaogang, Xu, Ping, Liu, Junhua, Zheng, Shenggen, Huang, He-Liang, Deng, Mingtang, Poletti, Dario, Bao, Wan-Su, and Wu, Junjie

Subjects
Quantum Physics, Physics - Computational Physics
Abstract

Recent advances on quantum computing hardware have pushed quantum computing to the verge of quantum supremacy. Random quantum circuits are outstanding candidates to demonstrate quantum supremacy, which could be implemented on a quantum device that supports nearest-neighbour gate operations on a two-dimensional configuration. Here we show that using the Projected Entangled-Pair States algorithm, a tool to study two-dimensional strongly interacting many-body quantum systems, we can realize an effective general-purpose simulator of quantum algorithms. This technique allows to quantify precisely the memory usage and the time requirements of random quantum circuits, thus showing the frontier of quantum supremacy. With this approach we can compute the full wave-function of the system, from which single amplitudes can be sampled with unit fidelity. Applying this general quantum circuit simulator we measured amplitudes for a $7\times 7$ lattice of qubits with depth $1+40+1$ and double-precision numbers in 31 minutes using less than $93$ TB memory on the Tianhe-2 supercomputer., Comment: 10 pages, 6 figures, 1 table

Published
2019
Full Text
View/download PDF

14. Current-phase relations of InAs nanowire Josephson junctions: from interacting to multi-mode regimes

Author

Hart, Sean, Cui, Zheng, Menard, Gerbold, Deng, Mingtang, Antipov, Andrey, Lutchyn, Roman M., Krogstrup, Peter, Marcus, Charles M., and Moler, Kathryn A.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity
Abstract

Gate-tunable semiconductor-superconductor nanowires with superconducting leads form exotic Josephson junctions that are a highly desirable platform for two types of qubits: those with topological superconductivity (Majorana qubits) and those based on tunable anharmonicity (gatemon qubits). Controlling their behavior, however, requires understanding their electrostatic environment and electronic structure. Here we study gated InAs nanowires with epitaxial aluminum shells. By measuring current-phase relations (CPR) and comparing them with analytical and numerical calculations, we show that we can tune the number of modes, determine the transparency of each mode, and tune into regimes in which electron-electron interactions are apparent, indicating the presence of a quantum dot. To take into account electrostatic and geometrical effects, we perform microscopic self-consistent Schrodinger-Poisson numerical simulations, revealing the energy spectrum of Andreev states in the junction as well as their spatial distribution. Our work systematically demonstrates the effect of device geometry, gate voltage and phase bias on mode behavior, providing new insights into ongoing experimental efforts and predictive device design., Comment: Main: 16 pages, 4 figures. Supplement: 8 pages, 4 figures

Published
2019
Full Text
View/download PDF

16. Engineering Hybrid Epitaxial InAsSb/Al Nanowire Materials for Stronger Topological Protection

Author

Sestoft, Joachim E., Kanne, Thomas, Gejl, Aske Nørskov, von Soosten, Merlin, Yodh, Jeremy S., Sherman, Daniel, Tarasinski, Brian, Wimmer, Michael, Johnson, Erik, Deng, Mingtang, Nygård, Jesper, Jespersen, Thomas Sand, Marcus, Charles M., and Krogstrup, Peter

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The combination of strong spin-orbit coupling, large $g$-factors, and the coupling to a superconductor can be used to create a topologically protected state in a semiconductor nanowire. Here we report on growth and characterization of hybrid epitaxial InAsSb/Al nanowires, with varying composition and crystal structure. We find the strongest spin-orbit interaction at intermediate compositions in zincblende InAs$_{1-x}$Sb$_{x}$ nanowires, exceeding that of both InAs and InSb materials, confirming recent theoretical studies \cite{winkler2016topological}. We show that the epitaxial InAsSb/Al interfaces allows for a hard induced superconducting gap and 2$e$ transport in Coulomb charging experiments, similar to experiments on InAs/Al and InSb/Al materials, and find measurements consistent with topological phase transitions at low magnetic fields due to large effective $g$-factors. Finally we present a method to grow pure wurtzite InAsSb nanowires which are predicted to exhibit even stronger spin-orbit coupling than the zincblende structure., Comment: 10 pages and 5 figures

Published
2017
Full Text
View/download PDF

17. Current-phase relations of few-mode InAs nanowire Josephson junctions

Author

Spanton, Eric M., Deng, Mingtang, Vaitiekėnas, Saulius, Krogstrup, Peter, Nygård, Jesper, Marcus, Charles M., and Moler, Kathryn A.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity
Abstract

Gate-tunable semiconductor nanowires with superconducting leads have great potential for quantum computation and as model systems for mesoscopic Josephson junctions. The supercurrent, $I$, versus the phase, $\phi$, across the junction is called the current-phase relation (CPR). It can reveal not only the amplitude of the critical current, but also the number of modes and their transmission. We measured the CPR of many individual InAs nanowire Josephson junctions, one junction at a time. Both the amplitude and shape of the CPR varied between junctions, with small critical currents and skewed CPRs indicating few-mode junctions with high transmissions. In a gate-tunable junction, we found that the CPR varied with gate voltage: Near the onset of supercurrent, we observed behavior consistent with resonant tunneling through a single, highly transmitting mode. The gate dependence is consistent with modeled subband structure that includes an effective tunneling barrier due to an abrupt change in the Fermi level at the boundary of the gate-tuned region. These measurements of skewed, tunable, few-mode CPRs are promising both for applications that require anharmonic junctions and for Majorana readout proposals.

Published
2017
Full Text
View/download PDF

20. Quantum generative adversarial learning in photonics

Author

Wang, Yizhi, primary, xue, shichuan, additional, Wang, Yaxuan, additional, Liu, Yong, additional, Ding, Jiangfang, additional, Shi, Weixu, additional, Wang, Dongyang, additional, Liu, Yingwen, additional, Fu, Xiang, additional, Huang, Guangyao, additional, Huang, Anqi, additional, Deng, Mingtang, additional, and Wu, Junjie, additional

Published
2023
Full Text
View/download PDF

21. Experimental quantum natural gradient optimization in photonics

Author

Wang, Yizhi, primary, Xue, Shichuan, additional, Wang, Yaxuan, additional, Ding, Jiangfang, additional, Shi, Weixu, additional, Wang, Dongyang, additional, Liu, Yong, additional, Liu, Yingwen, additional, Fu, Xiang, additional, Huang, Guangyao, additional, Huang, Anqi, additional, Deng, Mingtang, additional, and Wu, Junjie, additional

Published
2023
Full Text
View/download PDF

22. Variational Entanglement-Assisted Quantum Process Tomography with Arbitrary Ancillary Qubits

Author

Xue, Shichuan, primary, Wang, Yizhi, additional, Zhan, Junwei, additional, Wang, Yaxuan, additional, Zeng, Ru, additional, Ding, Jiangfang, additional, Shi, Weixu, additional, Liu, Yong, additional, Liu, Yingwen, additional, Huang, Anqi, additional, Huang, Guangyao, additional, Yu, Chunlin, additional, Wang, Dongyang, additional, Fu, Xiang, additional, Qiang, Xiaogang, additional, Xu, Ping, additional, Deng, Mingtang, additional, Yang, Xuejun, additional, and Wu, Junjie, additional

Published
2022
Full Text
View/download PDF

23. Optimization of quantum light sources and four-wave mixing based on a reconfigurable silicon ring resonator

Author

Wu, Chao, primary, Liu, Yingwen, additional, Wang, Yang, additional, Ding, Jiangfang, additional, Zhu, Pingyu, additional, Xue, Shichuan, additional, Yu, Xinyao, additional, Zheng, Qilin, additional, Yu, Miaomiao, additional, Huang, Anqi, additional, Fu, Xiang, additional, Qiang, Xiaogang, additional, Deng, Mingtang, additional, Wu, Junjie, additional, and Xu, Ping, additional

Published
2022
Full Text
View/download PDF

24. Quingo: A Programming Framework for Heterogeneous Quantum-Classical Computing with NISQ Features

Author

Fu, X., primary, Yu, Jintao, additional, Su, Xing, additional, Jiang, Hanru, additional, Wu, Hua, additional, Cheng, Fucheng, additional, Deng, Xi, additional, Zhang, Jinrong, additional, Jin, Lei, additional, Yang, Yihang, additional, Xu, Le, additional, Hu, Chunchao, additional, Huang, Anqi, additional, Huang, Guangyao, additional, Qiang, Xiaogang, additional, Deng, Mingtang, additional, Xu, Ping, additional, Xu, Weixia, additional, Liu, Wanwei, additional, Zhang, Yu, additional, Deng, Yuxin, additional, Wu, Junjie, additional, and Feng, Yuan, additional

Published
2021
Full Text
View/download PDF

26. General quantum Bernoulli factory: framework analysis and experiments

Author

Liu, Yong, primary, Jiang, Jiaqing, additional, Zhu, Pingyu, additional, Wang, Dongyang, additional, Ding, Jiangfang, additional, Qiang, Xiaogang, additional, Huang, Anqi, additional, Xu, Ping, additional, Zhang, Jialin, additional, Tian, Guojing, additional, Fu, Xiang, additional, Deng, Mingtang, additional, Wu, Chunqing, additional, Sun, Xiaoming, additional, Yang, Xuejun, additional, and Wu, Junjie, additional

Published
2021
Full Text
View/download PDF

29. Implementing graph-theoretic quantum algorithms on a silicon photonic quantum walk processor

Author

Qiang, Xiaogang, primary, Wang, Yizhi, additional, Xue, Shichuan, additional, Ge, Renyou, additional, Chen, Lifeng, additional, Liu, Yingwen, additional, Huang, Anqi, additional, Fu, Xiang, additional, Xu, Ping, additional, Yi, Teng, additional, Xu, Fufang, additional, Deng, Mingtang, additional, Wang, Jingbo B., additional, Meinecke, Jasmin D. A., additional, Matthews, Jonathan C. F., additional, Cai, Xinlun, additional, Yang, Xuejun, additional, and Wu, Junjie, additional

Published
2021
Full Text
View/download PDF

31. Remote-controlled quantum computing by quantum entanglement

Author

Wang, Dongyang, primary, Liu, Yong, additional, Ding, Jiangfang, additional, Qiang, Xiaogang, additional, Liu, Yingwen, additional, Huang, Anqi, additional, Fu, Xiang, additional, Xu, Ping, additional, Deng, Mingtang, additional, Yang, Xuejun, additional, and Wu, Junjie, additional

Published
2020
Full Text
View/download PDF

33. Variational quantum circuits for quantum state tomography

Author

Liu, Yong, primary, Wang, Dongyang, additional, Xue, Shichuan, additional, Huang, Anqi, additional, Fu, Xiang, additional, Qiang, Xiaogang, additional, Xu, Ping, additional, Huang, He-Liang, additional, Deng, Mingtang, additional, Guo, Chu, additional, Yang, Xuejun, additional, and Wu, Junjie, additional

Published
2020
Full Text
View/download PDF

35. General-Purpose Quantum Circuit Simulator with Projected Entangled-Pair States and the Quantum Supremacy Frontier

Author

Guo, Chu, primary, Liu, Yong, additional, Xiong, Min, additional, Xue, Shichuan, additional, Fu, Xiang, additional, Huang, Anqi, additional, Qiang, Xiaogang, additional, Xu, Ping, additional, Liu, Junhua, additional, Zheng, Shenggen, additional, Huang, He-Liang, additional, Deng, Mingtang, additional, Poletti, Dario, additional, Bao, Wan-Su, additional, and Wu, Junjie, additional

Published
2019
Full Text
View/download PDF

38. Engineering hybrid epitaxial InAsSb/Al nanowires for stronger topological protection

Author

Sestoft, Joachim E., primary, Kanne, Thomas, additional, Gejl, Aske Nørskov, additional, von Soosten, Merlin, additional, Yodh, Jeremy S., additional, Sherman, Daniel, additional, Tarasinski, Brian, additional, Wimmer, Michael, additional, Johnson, Erik, additional, Deng, Mingtang, additional, Nygård, Jesper, additional, Jespersen, Thomas Sand, additional, Marcus, Charles M., additional, and Krogstrup, Peter, additional

Published
2018
Full Text
View/download PDF

39. Engineering hybrid epitaxial InAsSb/Al nanowires for stronger topological protection

Author

Sestoft, Joachim E., Kanne, Thomas, Gejl, Aske Norskov, von Soosten, Merlin, Yodh, Jeremy S., Sherman, Daniel, Tarasinski, Brian, Wimmer, Michael, Johnson, Erik, Deng, Mingtang, Nygard, Jesper, Jespersen, Thomas Sand, Marcus, Charles M., Krogstrup, Peter, Sestoft, Joachim E., Kanne, Thomas, Gejl, Aske Norskov, von Soosten, Merlin, Yodh, Jeremy S., Sherman, Daniel, Tarasinski, Brian, Wimmer, Michael, Johnson, Erik, Deng, Mingtang, Nygard, Jesper, Jespersen, Thomas Sand, Marcus, Charles M., and Krogstrup, Peter

Published
2018

41. Charge Transport in Semiconductor Nanowire Quantum Devices: From Single Quantum Dots to Topological Superconductors

Author

Deng, Mingtang and Deng, Mingtang

Abstract

This thesis focuses on charge transport in semiconductor InSb nanowire quantum devices, including the electron transport, the hole transport, and the Cooper pair transport. Devices in which InSb semiconductor nanowire quantum dots are coupled with normal metals, superconductors or the proximity effect induced topological superconductors are fabricated and measured. Firstly, we have fabricated and measured normal metal contacted InSb nanowire devices. In each of these devices, a quantum dot is formed in the InSb nanowire between the contacts. We report on the magnetotransport measurements performed to these quantum dot devices, and reveal several novel transport features. First, we demonstrate the ambipolar quantum dot devices in which the quantum dots can be tuned from the n-type regime to the p-type regime. The transport measurements in both of the n-type regime and the p-type regime are performed. We also show that two methods can be used to estimate the effective g-factor of the quantum dot, but they can give very different estimation in the presence of a Kondo effect. In the p-type regime of an ambipolar quantum dot, we observe conductance peaks in the stability diagram which can be attributed to the quasi-1D lead states. Secondly, we have fabricated and characterized the superconductor coupled InSb nanowire quantum dots. We probe the density of states of the quasi-particles in the superconductor contacts, via a weakly coupled InSb quantum dot. In the strongly coupled InSb nanowire-superconductor junctions, dissipationless Josephson currents are observed. A SQUIDS device is also fabricated and measured, in which an anomalous modulation of the Josephson current in the magnetic field is observed. In the medium coupling regime, we observe the signatures of the multiple Andreev reflections, the sub-gab bound states, and the Josephson current, interplaying with the Kondo effect. By adjusting the gate voltages, we can control the dot-lead coupling strength and asymmet

Published
2013

42. Deng, Mingtang

Author

Deng, Mingtang and Deng, Mingtang

Published
2013

Catalog

Books, media, physical & digital resources
See catalog results