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133 results on '"WANG Shao-min"'

1. Highly tunable 2D silicon quantum dot array with coupling beyond nearest neighbors

Author

Wang, Ning, Kang, Jia-Min, Lu, Wen-Long, Wang, Shao-Min, Wang, You-Jia, Li, Hai-Ou, Cao, Gang, Wang, Bao-Chuan, and Guo, Guo-Ping

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Scaling up quantum dots to two-dimensional (2D) arrays is a crucial step for advancing semiconductor quantum computation. However, maintaining excellent tunability of quantum dot parameters, including both nearest-neighbor and next-nearest-neighbor couplings, during 2D scaling is challenging, particularly for silicon quantum dots due to their relatively small size. Here, we present a highly controllable and interconnected 2D quantum dot array in planar silicon, demonstrating independent control over electron fillings and the tunnel couplings of nearest-neighbor dots. More importantly, we also demonstrate the wide tuning of tunnel couplings between next-nearest-neighbor dots,which plays a crucial role in 2D quantum dot arrays. This excellent tunability enables us to alter the coupling configuration of the array as needed. These results open up the possibility of utilizing silicon quantum dot arrays as versatile platforms for quantum computing and quantum simulation.

Published
2024
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2. Pursuing high-fidelity control of spin qubits in natural Si/SiGe quantum dot

Author

Wang, Ning, Wang, Shao-Min, Zhang, Run-Ze, Kang, Jia-Min, Lu, Wen-Long, Li, Hai-Ou, Cao, Gang, Wang, Bao-Chuan, and Guo, Guo-Ping

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Electron spin qubits in silicon are a promising platform for fault-tolerant quantum computing. Low-frequency noise, including nuclear spin fluctuations and charge noise, is a primary factor limiting gate fidelities. Suppressing this noise is crucial for high-fidelity qubit operations. Here, we report on a two-qubit quantum device in natural silicon with universal qubit control, designed to investigate the upper limits of gate fidelities in a non-purified Si/SiGe quantum dot device. By employing advanced device structures, qubit manipulation techniques, and optimization methods, we have achieved single-qubit gate fidelities exceeding 99% and a two-qubit Controlled-Z (CZ) gate fidelity of 91%. Decoupled CZ gates are used to prepare Bell states with a fidelity of 91%, typically exceeding previously reported values in natural silicon devices. These results underscore that even natural silicon has the potential to achieve high-fidelity gate operations, particularly with further optimization methods to suppress low-frequency noise.

Published
2024
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18. The deformed uncertainty relation and the corresponding beam quality factor

Author

Li, Kang, Zhao, Dao-Mu, and Wang, Shao-Min

Subjects
Quantum Physics
Abstract

By using the theory of deformed quantum mechanics, we study the deformed light beam theoretically. The deformed beam quality factor $M_q^2$ is given explicitly under the case of deformed light in coherent state. When the deformation parameter $q$ being a root of unity, the beam quality factor $M_q^2 \leq 1$., Comment: 11pages, revtex, no figures

Published
1996

30. A Structured Ultramicroporous Metal‐Organic Framework for Carbon Dioxide Capture†.

Author

Wang, Shao‐Min, Liu, Hao‐Ran, Ni, Shuang, and Yang, Qing‐Yuan

Subjects
*METAL-organic frameworks, *CARBON dioxide, *CARBON sequestration, *POLYVINYL butyral, *INDUSTRIAL capacity, *WOOD pellets
Abstract

Comprehensive Summary: Carbon dioxide (CO2) capture is one of the most important aspects of reducing global warming. In terms of CO2 capture, metal‐organic frameworks (MOFs) have several advantages. However, it isn't easy to shape MOFs while maintaining their performance. Herein, we describe the development of a pellet‐shaped ultramicroporous MOF, Ni(3‐ain)2 (3‐ain = 3‐aminoinoisonicotinic acid), that is capable of selectively adsorbing CO2. Polyvinyl butyral (PVB) is used as a binder during the production of Ni(3‐ain)2 MOF pellets. The adequately shaped material can maintain its crystallinity and exhibit a high CO2 adsorption capacity (3.73 mmol·g–1) at ambient conditions, which is significantly greater than those obtained for N2 (0.63 mmol·g–1) and CO (0.90 mmol·g–1). Consequently, this material displays high IAST selectivities for CO2/N2 (26.3, 15/85, V/V) and CO2/CO (19.2, 1/99, V/V). According to the theoretical calculations, Ni(3‐ain)2 preferentially adsorbs CO2 molecules over N2 molecules and CO molecules. The results of experiments on dynamic breakthrough have demonstrated that Ni(3‐ain)2 pellets are capable of effectively separating CO2/N2 or CO2/CO mixtures under conditions of dynamic flow. Furthermore, the structured MOF materials can be synthesized in one step at kilogram scale. This work provides an avenue for the shaping of MOFs for potential industrial applications in the future. [ABSTRACT FROM AUTHOR]

Published
2023
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31. A Structured Ultramicroporous Metal‐Organic Framework for Carbon Dioxide Capture†.

Author

Wang, Shao‐Min, Liu, Hao‐Ran, Ni, Shuang, and Yang, Qing‐Yuan

Subjects
METAL-organic frameworks, CARBON dioxide, CARBON sequestration, POLYVINYL butyral, INDUSTRIAL capacity, WOOD pellets
Abstract

Comprehensive Summary: Carbon dioxide (CO2) capture is one of the most important aspects of reducing global warming. In terms of CO2 capture, metal‐organic frameworks (MOFs) have several advantages. However, it isn't easy to shape MOFs while maintaining their performance. Herein, we describe the development of a pellet‐shaped ultramicroporous MOF, Ni(3‐ain)2 (3‐ain = 3‐aminoinoisonicotinic acid), that is capable of selectively adsorbing CO2. Polyvinyl butyral (PVB) is used as a binder during the production of Ni(3‐ain)2 MOF pellets. The adequately shaped material can maintain its crystallinity and exhibit a high CO2 adsorption capacity (3.73 mmol·g–1) at ambient conditions, which is significantly greater than those obtained for N2 (0.63 mmol·g–1) and CO (0.90 mmol·g–1). Consequently, this material displays high IAST selectivities for CO2/N2 (26.3, 15/85, V/V) and CO2/CO (19.2, 1/99, V/V). According to the theoretical calculations, Ni(3‐ain)2 preferentially adsorbs CO2 molecules over N2 molecules and CO molecules. The results of experiments on dynamic breakthrough have demonstrated that Ni(3‐ain)2 pellets are capable of effectively separating CO2/N2 or CO2/CO mixtures under conditions of dynamic flow. Furthermore, the structured MOF materials can be synthesized in one step at kilogram scale. This work provides an avenue for the shaping of MOFs for potential industrial applications in the future. [ABSTRACT FROM AUTHOR]

Published
2023
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33. Effects of Different Storage Temperatures and Preservatives on the Fresh-Keeping Effects of Pyrus communis Qiuyang.

Author

ZOU Man, YANG Juan-xia, ZHANG Kun-peng, WEI Shu-wei, WANG Shao-min, and ZHANG Qian

Abstract

In order to study the effects of different storage temperatures and preservatives on the preservation effects of Qiuyang pear fruits, the effects of 0.5 μL/L 1 -methylcyclopropene (1 -MCP) fumigation for 12 h and ethylene adsorbent treatments on the storage qualities of Qiuyang pears were investigated under different storage temperatures (-1 °C and 0 °C). The results showed that after 120 days of storage, the decay rates of fruits stored at 0°C was lower than that stored at -1°C under the same treatment conditions. At 270 days, the decay rates of fruits stored at 0 °C and -1°C in the two preservatives treatment groups were lower than those in CK group. The fruits peels brightness of CK group and ethylene sorbent treatment group at 0°C was higher than that stored at -1 °C. After 240 days of storage, the fruits hardness of 1-MCP treatment group was remarkably higher than that of other treatments groups (P<0.05), and the fruits hardness of 1-MCP treatment group stored at 0°C was significantly higher than that stored at -1°C at 270 days (P<0.05). The titratable acid contents of fruits in the two preservatives treatment groups were higher than that in CK group at 270 days of storage. The soluble solids contents of fruits in each group presented no significant changes during storage. In conclusion, Qiuyang pears presented low decay rates and well maintained peels brightness when stored at 0°C. The two preservatives treatments could both reduce the decay rates and delay the decline of titratable acid contents of Qiuyang pears, and the 1-MCP treatment showed better effects that could effectively maintain peel brightness and fruit firmness. [ABSTRACT FROM AUTHOR]

Published
2023
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37. Pore‐Structure Control in Metal–Organic Frameworks (MOFs) for Capture of the Greenhouse Gas SF6 with Record Separation.

Author

Wang, Shao‐Min, Mu, Xuan‐Tong, Liu, Hao‐Ran, Zheng, Su‐Tao, and Yang, Qing‐Yuan

Subjects
*METAL-organic frameworks, *GREENHOUSE gases, *SULFUR hexafluoride, *POROSITY, *INDUSTRIAL electronics
Abstract

In the electronics industry, the efficient recovery and capture of sulfur hexafluoride (SF6) from SF6/N2 mixtures is of great importance. Herein, three metal–organic frameworks with fine‐tuning pore structures, Cu(peba)2, Ni(pba)2, and Ni(ina)2, were designed for SF6 capture. Among them, Ni(ina)2 has perfect pore sizes (6 Å) that are comparable to the kinetic diameter of sulfur hexafluoride (5.2 Å), affording the benchmark binding affinity for SF6 gas. Ni(ina)2 exhibits the highest SF6/N2 selectivity (375.1 at 298 K and 1 bar) and ultra‐high SF6 uptake capacity (53.5 cm3 g−1 at 298 K and 0.1 bar) at ambient conditions. The remarkable separation performance of Ni(ina)2 was verified by dynamic breakthrough experiments. Theoretical calculations and the SF6‐loaded single‐crystal structure provided critical insight into the adsorption/separation mechanism. This porous coordination network has the potential to be used in industrial applications. [ABSTRACT FROM AUTHOR]

Published
2022
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40. Nickel‐Based Metal–Organic Frameworks for Coal‐Bed Methane Purification with Record CH4/N2 Selectivity.

Author

Wang, Shao‐Min, Shivanna, Mohana, and Yang, Qing‐Yuan

Subjects
*METAL-organic frameworks, *COALBED methane, *METHANE, *BENZOIC acid, *SEPARATION (Technology), *INDUSTRIAL capacity
Abstract

The enrichment and purification of coal‐bed methane provides a source of energy and helps offset global warming. In this work, we demonstrate a strategy involving the regulation of the pore size and pore chemistry to promote the separation of CH4/N2 mixtures in four nickel‐based coordination networks, named Ni(ina)2, Ni(3‐ain)2, Ni(2‐ain)2, and Ni(pba)2, (where ina=isonicotinic acid, 3‐ain=3‐aminoisonicotinic acid, 2‐ain=2‐aminoisonicotinic acid, and pba=4‐(4‐pyridyl)benzoic acid). Among them, Ni(ina)2 and Ni(3‐ain)2 can effectively separate CH4 from N2 with top‐performing performance because of the suitable pore size (≈0.6 and 0.5 nm) and pore environment. Explicitly, Ni(ina)2 exhibits the highest ever reported CH4/N2 selectivity of 15.8 and excellent CH4 uptake (40.8 cm3 g−1) at ambient conditions, thus setting new benchmarks for all reported MOFs and traditional adsorbents. The exceptional CH4/N2 separation performance of Ni(ina)2 is confirmed by dynamic breakthrough experiments. Under different CH4/N2 ratios, Ni(ina)2 selectively extracts methane from the gaseous blend and produces a high purity of CH4 (99 %). Theoretical calculations and CH4‐loading single‐crystal structure analysis provide critical insight into the adsorption/separation mechanism. Ni(ina)2 and Ni(3‐ain)2 can form rich intermolecular interactions with methane, indicating a strong adsorption affinity between pore walls and CH4 molecules. Importantly, Ni(ina)2 has good thermal and moisture stability and can easily be scaled up at a low cost ($25 per kilogram), which will be valuable for potential industrial applications. Overall, this work provides a powerful approach for the selective adsorption of CH4 from coal‐bed methane. [ABSTRACT FROM AUTHOR]

Published
2022
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41. Amino-Functionalized Microporous MOFs for Capturing Greenhouse Gases CF4and NF3with Record Selectivity

Author

Wang, Shao-Min, Lan, Hao-Ling, Guan, Guo-Wei, and Yang, Qing-Yuan

Abstract

The capture and separation of fluorinated gases (F-gases) from N2has the potential to not only reduce greenhouse gas emissions but also provide economic benefits for the semiconductor industry. In this work, two Ni-based metal–organic frameworks (MOFs), Ni-MOF(Ni(ina)2, ina = isonicotinic acid) and amine-functionalized NH2–Ni-MOF(Ni(3-ain)2, 3-ain = 3-aminoisonicotinic acid), were constructed for capturing F-gases (CF4and NF3). At ambient conditions, both materials exhibit very high CF4sorption capacities (2.92 mmol g–1for Ni-MOFand 2.69 mmol g–1for NH2–Ni-MOF). In addition, NH2–Ni-MOFexhibited a record selectivity of 46.3 for the CF4/N2mixture at 298 K and 100 kPa, surpassing all benchmark adsorbents, including Ni-MOF(34.7). The kinetic adsorption tests demonstrated that Ni-MOFand NH2–Ni-MOFperformed well for CF4/N2and NF3/N2mixtures. According to grand canonical Monte Carlo (GCMC) simulations, CF4or NF3interacts with NH2–Ni-MOFby multiple van der Waals interactions, resulting in stronger interaction than N2. More importantly, dynamic breakthrough experiments verified the practical separation potential of the two materials for CF4/N2and NF3/N2mixtures.

Published
2022
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