Your search keyword '"Shengda D. Pu"' showing total 18 results

1. The effect of volume change and stack pressure on solid‐state battery cathodes

Author

Boyang Liu, Shengda D. Pu, Christopher Doerrer, Dominic Spencer Jolly, Robert A. House, Dominic L. R. Melvin, Paul Adamson, Patrick S. Grant, Xiangwen Gao, and Peter G. Bruce

Subjects

cathode, interface, mechanical degradation, stack pressure, solid‐state battery, Materials of engineering and construction. Mechanics of materials, TA401-492, Environmental engineering, TA170-171

Abstract

Abstract Solid‐state lithium batteries may provide increased energy density and improved safety compared with Li‐ion technology. However, in a solid‐state composite cathode, mechanical degradation due to repeated cathode volume changes during cycling may occur, which may be partially mitigated by applying a significant, but often impractical, uniaxial stack pressure. Herein, we compare the behavior of composite electrodes based on Li4Ti5O12 (LTO) (negligible volume change) and Nb2O5 (+4% expansion) cycled at different stack pressures. The initial LTO capacity and retention are not affected by pressure but for Nb2O5, they are significantly lower when a stack pressure of

Published

2023

2. A prognostic dynamic model applicable to infectious diseases providing easily visualized guides: a case study of COVID-19 in the UK

Author

Yuxuan Zhang, Chen Gong, Dawei Li, Zhi-Wei Wang, Shengda D. Pu, Alex W. Robertson, Hong Yu, and John Parrington

Subjects

Medicine, Science

Abstract

Abstract A reasonable prediction of infectious diseases’ transmission process under different disease control strategies is an important reference point for policy makers. Here we established a dynamic transmission model via Python and realized comprehensive regulation of disease control measures. We classified government interventions into three categories and introduced three parameters as descriptions for the key points in disease control, these being intraregional growth rate, interregional communication rate, and detection rate of infectors. Our simulation predicts the infection by COVID-19 in the UK would be out of control in 73 days without any interventions; at the same time, herd immunity acquisition will begin from the epicentre. After we introduced government interventions, a single intervention is effective in disease control but at huge expense, while combined interventions would be more efficient, among which, enhancing detection number is crucial in the control strategy for COVID-19. In addition, we calculated requirements for the most effective vaccination strategy based on infection numbers in a real situation. Our model was programmed with iterative algorithms, and visualized via cellular automata; it can be applied to similar epidemics in other regions if the basic parameters are inputted, and is able to synthetically mimic the effect of multiple factors in infectious disease control.

Published

2021

3. Interfaces between Ceramic and Polymer Electrolytes: A Comparison of Oxide and Sulfide Solid Electrolytes for Hybrid Solid-State Batteries

Author

Dominic Spencer Jolly, Dominic L. R. Melvin, Isabella D. R. Stephens, Rowena H. Brugge, Shengda D. Pu, Junfu Bu, Ziyang Ning, Gareth O. Hartley, Paul Adamson, Patrick S. Grant, Ainara Aguadero, and Peter G. Bruce

Subjects

solid-state battery, hybrid battery, interfaces, polymer electrolyte, solid electrolyte, solid-polymer electrolyte interphase, Inorganic chemistry, QD146-197

Abstract

Hybrid solid-state batteries using a bilayer of ceramic and solid polymer electrolytes may offer advantages over using a single type of solid electrolyte alone. However, the impedance to Li+ transport across interfaces between different electrolytes can be high. It is important to determine the resistance to Li+ transport across these heteroionic interfaces, as well as to understand the underlying causes of these resistances; in particular, whether chemical interphase formation contributes to giving high resistances, as in the case of ceramic/liquid electrolyte interfaces. In this work, two ceramic electrolytes, Li3PS4 (LPS) and Li6.5La3Zr1.5Ta0.5O12 (LLZTO), were interfaced with the solid polymer electrolyte PEO10:LiTFSI and the interfacial resistances were determined by impedance spectroscopy. The LLZTO/polymer interfacial resistance was found to be prohibitively high but, in contrast, a low resistance was observed at the LPS/polymer interface that became negligible at a moderately elevated temperature of 50 °C. Chemical characterization of the two interfaces was carried out, using depth-profiled X-ray photoelectron spectroscopy and time-of-flight secondary ion mass spectrometry, to determine whether the interfacial resistance was correlated with the formation of an interphase. Interestingly, no interphase was observed at the higher resistance LLZTO/polymer interface, whereas LPS was observed to react with the polymer electrolyte to form an interphase.

Published

2022

4. The role of an elastic interphase in suppressing gas evolution and promoting uniform electroplating in sodium metal anodes

Author

Chen Gong, Shengda D. Pu, Shengming Zhang, Yi Yuan, Ziyang Ning, Sixie Yang, Xiangwen Gao, Chloe Chau, Zixuan Li, Junliang Liu, Liquan Pi, Boyang Liu, Isaac Capone, Bingkun Hu, Dominic L. R. Melvin, Mauro Pasta, Peter G. Bruce, and Alex W. Robertson

Subjects

Nuclear Energy and Engineering, Renewable Energy, Sustainability and the Environment, Environmental Chemistry, Pollution

Abstract

Ether solvent based electrolytes exhibit excellent performance with sodium battery anodes, outperforming the carbonate electrolytes that are routinely used with the analogous lithium-ion battery. Uncovering the mechanisms that facilitate this high performance for ether electrolytes, and conversely diagnosing the causes of the poor cycling with carbonate electrolytes, is crucial for informing the design of optimized electrolytes that promote fully reversible sodium cycling. An important contributor to the performance difference has been suggested to be the enhanced elasticity of the ether-derived solid–electrolyte interphase (SEI) layer, however experimental demonstration of exactly how this translates to improving the microscopic dynamics of a cycled anode remain less explored. Here, we reveal how this more elastic SEI prevents gas evolution at the interface of the metal anode by employing operando electrochemical transmission electron microscopy (TEM) to image the cycled electrode–electrolyte interface in real time. The high spatial resolution of TEM imaging reveals the rapid formation of gas bubbles at the interface during sodium electrostripping in carbonate electrolyte, a phenomenon not observed for the higher performance ether electrolyte, which impedes complete Na stripping and causes the SEI to delaminate from the electrode. This non-conformal and inflexible SEI must thus continuously reform, leading to increased Na loss to SEI formation, as supported by mass spectrometry measurements. The more elastic ether interphase is better able to maintain conformality with the electrode, preventing gas formation and facilitating flat electroplating. Our work shows why an elastic and flexible interphase is important for achieving high performance sodium anodes.

Published

2023

5. High critical currents for dendrite penetration and voiding in potassium metal anode solid-state batteries

Author

Dominic Spencer Jolly, Johann Perera, Shengda D. Pu, Dominic L. R. Melvin, Paul Adamson, and Peter G. Bruce

Subjects

Electrochemistry, General Materials Science, Electrical and Electronic Engineering, Condensed Matter Physics

Abstract

Potassium metal anode solid-state cells with a K-beta”-alumina ceramic electrolyte are found to have relatively high critical currents for dendrite penetration on charge of approximately 4.8 mA/cm2, and voiding on discharge of approximately 2.0 mA/cm2, at 20 °C under 2.5 MPa stack-pressure. These values are higher than generally reported in the literature under comparable conditions for Li and Na metal anode solid-state batteries. The higher values for potassium are attributed to its lower yield strength and its readiness to creep under relatively low stack-pressures. The high critical currents of potassium anode solid-state batteries help to confirm the importance of the metal anode mechanical properties in the mechanisms of dendrite penetration and voiding.

Published

2022

6. Quantification of hydrogen trapping in multiphase steels: Part II – Effect of austenite morphology

Author

Pedro E.J. Rivera-Díaz-del-Castillo, Shengda D. Pu, Andrej Turk, David Bombač, and Enrique I. Galindo-Nava

Subjects

010302 applied physics, Austenite, Materials science, Polymers and Plastics, Hydrogen, Metals and Alloys, chemistry.chemical_element, Thermodynamics, 02 engineering and technology, Permeation, 021001 nanoscience & nanotechnology, Thermal diffusivity, 01 natural sciences, Electronic, Optical and Magnetic Materials, chemistry, Martensite, Ferrite (iron), 0103 physical sciences, Ceramics and Composites, Grain boundary, Diffusion (business), 0210 nano-technology

Abstract

We tackle the role of austenite in multiphase steels on hydrogen diffusion systematically for the first time, considering a range of factors such as morphology, interface kinetics and the additional effect of point traps using both experiments and modelling. This follows the findings from part I where we showed that austenite cannot be parametrised and modelled as point traps under the assumption of local equilibrium, unlike grain boundaries and dislocations. To solve this, we introduce a 2D hydrogen diffusion model accounting for the difference in diffusivities and solubilities between the phases. We first revisit the as-quenched martensite permeation results from part I and show that the extremely low H diffusivity there can be partly explained with the new description of austenite but is partly likely due to quench vacancies. We then also look at the H absorption and desorption rates in a duplex steel as a case study using a combination of simulations and experiments. The rates are shown to depend heavily on austenite morphology and the kinetics of H transition from ferrite to austenite and that an energy barrier is likely associated to this transition. We show that H diffusion through the ferrite matrix and austenite islands proceeds at similar rates and the assumption of negligible concentration gradients in ferrite occasionally applied in the literature is a poor approximation. This approach is also applicable to other austenite-containing steels as well as other multiphase alloys.

Published

2020

7. Current-Density-Dependent Electroplating in Ca Electrolytes: From Globules to Dendrites

Author

Shengda D. Pu, Chen Gong, Xiangwen Gao, Ziyang Ning, Boyang Liu, Sixie Yang, Jun Luo, Robert A. House, Peter G. Bruce, John-Joseph Marie, Alex W. Robertson, and Gareth O. Hartley

Subjects

Dendrons, Materials science, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Electrolytes, Fuel Technology, Chemical engineering, Chemistry (miscellaneous), Transmission electron microscopy, Electrical properties, Materials Chemistry, Deposition, 0210 nano-technology, Electroplating, Electrodes, Current density

Abstract

Multivalent cation rechargeable batteries, including those based on Ca, Mg, Al, etc., have attracted considerable interest as candidates for beyond Li-ion batteries. Recent developments have realized promising electrolyte compositions for rechargeable Ca batteries; however, an in-depth understanding of the Ca plating and stripping behavior and the mechanisms by which adverse dendritic growth may occur remains underdeveloped. In this work, via in situ transmission electron microscopy, we have captured the real-time nucleation, growth, and dissolution of Ca and the formation of dead Ca and demonstrated the critical role of current density and the solid-electrolyte interphase layer in controlling the plating morphology. In particular, the interface was found to influence Ca deposition morphology and can lead to Ca dendrite growth under unexpected conditions. These observations allow us to propose a model explaining the preferred conditions for reversible and efficient Ca plating.

Published

2020

8. Correction: The role of an elastic interphase in suppressing gas evolution and promoting uniform electroplating in sodium metal anodes

Author

Chen Gong, Shengda D. Pu, Shengming Zhang, Yi Yuan, Ziyang Ning, Sixie Yang, Xiangwen Gao, Chloe Chau, Zixuan Li, Junliang Liu, Liquan Pi, Boyang Liu, Isaac Capone, Bingkun Hu, Dominic L. R. Melvin, Mauro Pasta, Peter G. Bruce, and Alex W. Robertson

Subjects

Nuclear Energy and Engineering, Renewable Energy, Sustainability and the Environment, Environmental Chemistry, Pollution

Abstract

Correction for ‘The role of an elastic interphase in suppressing gas evolution and promoting uniform electroplating in sodium metal anodes’ by Chen Gong et al., Energy Environ. Sci., 2023, 16, 535–545, https://doi.org/10.1039/D2EE02606F.

Published

2023

9. Li2NiO2F a new oxyfluoride disordered rocksalt cathode material

Author

Peter G. Bruce, Robert A. House, Liquan Pi, Alex W. Robertson, Chen Gong, Gregory J. Rees, John-Joseph Marie, Xiaoyu Xu, and Shengda D. Pu

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, business.industry, Cathode material, TK, Materials Chemistry, Electrochemistry, Optoelectronics, QD, Condensed Matter Physics, business, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

Lithium-rich disordered rocksalts such as Li1.3Nb0.3Mn0.4O2 and Li2MnO2F are being investigated as high energy density cathodes for next generation Li-ion batteries. They can support the (de) lithiation of lithium ions over large compositional ranges while preserving the same overall structure. Here, we present a new Ni-rich oxyfluoride cathode, Li2NiO2F, with a disordered rocksalt structure. Li2NiO2F and can deliver a discharge capacity of 200 mAh g−1 at an average voltage of 3.2 V.

Published

2021

10. Atomic-precision tailoring of Au–Ag core–shell composite nanoparticles for direct electrochemical-plasmonic hydrogen evolution in water splitting

Author

Shik Chi Edman Tsang, Tong Li, Yun-Liang Soo, Tai-Sing Wu, Shengda D. Pu, Simson Wu, Alex W. Robertson, Weikai Xiang, Jiaying Mo, Eduardo C. M. Barbosa, Yiyang Li, Pedro H. C. Camargo, Yuancheng Sun, Winson C. H. Kuo, and Tiago Vinicius Alves

Subjects

Materials science, Heterojunction, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Electrochemistry, 01 natural sciences, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, Biomaterials, Photocatalysis, Water splitting, Hydrogen evolution, Composite nanoparticles, Surface plasmon resonance, 0210 nano-technology, Plasmon

Abstract

Traditionally, bandgap materials are a prerequisite to photocatalysis since they can harness a reasonable range of the solar spectrum. However, the high impedance across the bandgap and the low concentration of intrinsic charge carriers have limited their energy conversion. By contrast, metallic nanoparticles possess a sea of free electrons that can effectively promote the transition to the excited state for reactions. Here, an atomic layer of a bimetallic concoction of silver–gold shells is precisely fabricated onto an Au core via a sonochemical dispersion approach to form a core–shell of Au–Ag that exploits the wide availability of excited states of Ag while maintaining an efficient localized surface plasmon resonance (LSPR) of Au. Catalytic results demonstrate that this mix of Ag and Au can convert solar energy to hydrogen at high efficiency with an increase of 112.5% at an optimized potential of −0.5 V when compared to light-off conditions under the electrochemical LSPR. This outperforms the commercial Pt catalysts by 62.1% with a hydrogen production rate of 1870 µmol g−1 h−1 at room temperature. This study opens a new route for tuning the range of light capture of hydrogen evolution reaction catalysts using fabricated core–shell material through the combination of LSPR with electrochemical means.

Published

2021

11. Study of hydrogen release resulting from the transformation of austenite into martensite

Author

S. W. Ooi, Andrej Turk, Shengda D. Pu, and S. Lenka

Subjects

010302 applied physics, Austenite, Diffraction, Materials science, Hydrogen, Mechanical Engineering, technology, industry, and agriculture, Thermal desorption, Thermodynamics, chemistry.chemical_element, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Microprinting, chemistry, Mechanics of Materials, Martensite, Diffusionless transformation, 0103 physical sciences, General Materials Science, 0210 nano-technology, Embrittlement

Abstract

Hydrogen desorption behaviour of two different austenite-containing steels pre- and post-deformation was studied using a combination of X-ray diffraction, microprinting and thermal desorption analysis, aided by diffusion simulations. The change in hydrogen desorption rates was found to be closely related to the degree of martensitic transformation. In the duplex steel which exhibited no phase transformation, the hydrogen desorption rate stayed virtually unchanged after deformation. On the other hand, in the 304 austenitic steel which experienced substantial martensitic transformation, a large increase in the hydrogen desorption rate was detected after deformation. This is the first direct observation of deformation-induced hydrogen release, which has previously been proposed to be a key contributor to the embrittlement in austenite-containing steels.

Published

2019

12. Revealing the role of fluoride-rich battery electrode interphases by operando transmission electron microscopy

Author

Xiangwen Gao, Isaac Capone, Sixie Yang, Jun Luo, Shengda D. Pu, Gregory J. Rees, Junliang Liu, Liquan Pi, Gareth O. Hartley, Chris R. M. Grovenor, Alex W. Robertson, Jack Fawdon, Mauro Pasta, Peter G. Bruce, Chen Gong, Boyang Liu, and Ziyang Ning

Subjects

Battery (electricity), Materials science, Renewable Energy, Sustainability and the Environment, TK, chemistry.chemical_element, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Anode, Chemical engineering, chemistry, Transmission electron microscopy, Plating, Electrode, General Materials Science, Lithium, QD, 0210 nano-technology, Dissolution

Abstract

The solid electrolyte interphase (SEI), a complex layer that forms over the surface of electrodes exposed to battery electrolyte, has a central influence on the structural evolution of the electrode during battery operation. For lithium metallic anodes, tailoring this SEI is regarded as one of the most effective avenues for ensuring consistent cycling behavior, and thus practical efficiencies. While fluoride-rich interphases in particular seem beneficial, how they alter the structural dynamics of lithium plating and stripping to promote efficiency remains only partly understood. Here, operando liquid-cell transmission electron microscopy is used to investigate the nanoscale structural evolution of lithium electrodeposition and dissolution at the electrode surface across fluoride-poor and fluoride-rich interphases. The in situ imaging of lithium cycling reveals that a fluoride-rich SEI yields a denser Li structure that is particularly amenable to uniform stripping, thus suppressing lithium detachment and isolation. By combination with quantitative composition analysis via mass spectrometry, it is identified that the fluoride-rich SEI suppresses overall lithium loss through drastically reducing the quantity of dead Li formation and preventing electrolyte decomposition. These findings highlight the importance of appropriately tailoring the SEI for facilitating consistent and uniform lithium dissolution, and its potent role in governing the plated lithium's structure.

Published

2021

13. In Situ Transmission Electron Microscopy for Studying Lithium-Ion Batteries

Author

Alex W. Robertson, Chen Gong, and Shengda D. Pu

Subjects

In situ, Battery (electricity), Materials science, chemistry, Transmission electron microscopy, chemistry.chemical_element, Nanotechnology, Context (language use), Lithium, Lithium-ion battery, Ion, Characterization (materials science)

Abstract

The ability to directly resolve the dynamic processes that occur at the electrode-electrolyte interface of an operating battery cell holds great potential for enhancing the development of new materials and chemistries for the lithium-ion battery. We introduce and explore the use of in situ transmission electron microscopy (TEM) techniques to diagnose the material challenges of the lithium-ion battery. The different experimental approaches for studying an operating electrode-electrolyte interface within the vacuum of the TEM are outlined, and their respective advantages and limitations are discussed. Some recent examples of in situ TEM of batteries are highlighted with the context of these different experimental approaches. Finally, we approach the challenges associated with accounting for the damaging effect of the ionizing electron beam and discuss the damage mechanisms that occur during in situ TEM imaging.

Published

2021

14. Visualizing plating-induced cracking in lithium-anode solid-electrolyte cells

Author

Robin De Meyere, Dominic L. R. Melvin, Peter G. Bruce, Charles W. Monroe, T. James Marrow, Shengda D. Pu, Chen Gong, Paul Adamson, Anne Bonnin, Johannes Ihli, Dominic Spencer Jolly, Boyang Liu, Yang Chen, Gareth O. Hartley, Ziyang Ning, Guanchen Li, Oxana V. Magdysyuk, and Jitti Kasemchainan

Subjects

Materials science, Mechanical Engineering, chemistry.chemical_element, 02 engineering and technology, General Chemistry, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Anode, chemistry, Mechanics of Materials, Plating, visual_art, Electrode, visual_art.visual_art_medium, General Materials Science, Spallation, Lithium, Ceramic, Composite material, 0210 nano-technology, Short circuit

Abstract

Lithium dendrite (filament) propagation through ceramic electrolytes, leading to short circuits at high rates of charge, is one of the greatest barriers to realizing high-energy-density all-solid-state lithium-anode batteries. Utilizing in situ X-ray computed tomography coupled with spatially mapped X-ray diffraction, the propagation of cracks and the propagation of lithium dendrites through the solid electrolyte have been tracked in a Li/Li6PS5Cl/Li cell as a function of the charge passed. On plating, cracking initiates with spallation, conical ‘pothole’-like cracks that form in the ceramic electrolyte near the surface with the plated electrode. The spallations form predominantly at the lithium electrode edges where local fields are high. Transverse cracks then propagate from the spallations across the electrolyte from the plated to the stripped electrode. Lithium ingress drives the propagation of the spallation and transverse cracks by widening the crack from the rear; that is, the crack front propagates ahead of the Li. As a result, cracks traverse the entire electrolyte before the Li arrives at the other electrode, and therefore before a short circuit occurs. Lithium dendrite propagation through ceramic electrolytes can prevent the realization of high-energy-density all-solid-state lithium-anode batteries. The propagation of cracks and lithium dendrites through a solid electrolyte has now been tracked as a function of charge.

Published

2020

15. Liquid cell transmission electron microscopy and its applications

Author

Chen Gong, Alex W. Robertson, and Shengda D. Pu

Subjects

Materials science, Silicon, Ultra-high vacuum, Liquid phase, chemistry.chemical_element, Nanotechnology, Review Article, 02 engineering and technology, liquid cell transmission electron microscopy, 010402 general chemistry, 01 natural sciences, Nanomaterials, Biological specimen, transmission electron microscopy, lcsh:Science, Nanoscopic scale, in situ transmission electron microscopy, Multidisciplinary, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Chemistry, chemistry, Transmission electron microscopy, Liquid cell, lcsh:Q, 0210 nano-technology

Abstract

Transmission electron microscopy (TEM) has long been an essential tool for understanding the structure of materials. Over the past couple of decades, this venerable technique has undergone a number of revolutions, such as the development of aberration correction for atomic level imaging, the realization of cryogenic TEM for imaging biological specimens, and new instrumentation permitting the observation of dynamic systems in situ . Research in the latter has rapidly accelerated in recent years, based on a silicon-chip architecture that permits a versatile array of experiments to be performed under the high vacuum of the TEM. Of particular interest is using these silicon chips to enclose fluids safely inside the TEM, allowing us to observe liquid dynamics at the nanoscale. In situ imaging of liquid phase reactions under TEM can greatly enhance our understanding of fundamental processes in fields from electrochemistry to cell biology. Here, we review how in situ TEM experiments of liquids can be performed, with a particular focus on microchip-encapsulated liquid cell TEM. We will cover the basics of the technique, and its strengths and weaknesses with respect to related in situ TEM methods for characterizing liquid systems. We will show how this technique has provided unique insights into nanomaterial synthesis and manipulation, battery science and biological cells. A discussion on the main challenges of the technique, and potential means to mitigate and overcome them, will also be presented.

Published

2020

16. A prognostic dynamic model applicable to infectious diseases providing easily visualized guides -- A case study of COVID-19 in the UK

Author

Chen Gong, Yuxuan Zhang, Alex W. Robertson, Shengda D. Pu, Zhi-Wei Wang, John Parrington, Dawei Li, and Hong Yu

Subjects

0301 basic medicine, FOS: Computer and information sciences, Epidemiology, Computer science, Process (engineering), Science, Control (management), Psychological intervention, Statistics - Applications, Article, Herd immunity, 03 medical and health sciences, 0302 clinical medicine, Humans, Applications (stat.AP), 030212 general & internal medicine, Quantitative Biology - Populations and Evolution, computer.programming_language, Government, Multidisciplinary, SARS-CoV-2, Vaccination, Populations and Evolution (q-bio.PE), COVID-19, Models, Theoretical, Python (programming language), Prognosis, United Kingdom, 030104 developmental biology, Risk analysis (engineering), Viral infection, Infectious disease (medical specialty), FOS: Biological sciences, Key (cryptography), Infectious diseases, Medicine, computer

Abstract

A reasonable prediction of infectious diseases transmission process under different disease control strategies is an important reference point for policy makers. Here we established a dynamic transmission model via Python and realized comprehensive regulation of disease control measures. We classified government interventions into three categories and introduced three parameters as descriptions for the key points in disease control, these being intraregional growth rate, interregional communication rate, and detection rate of infectors. Our simulation predicts the infection by COVID-19 in the UK would be out of control in 73 days without any interventions; at the same time, herd immunity acquisition will begin from the epicentre. After we introduced government interventions, single intervention is effective in disease control but at huge expense while combined interventions would be more efficient, among which, enhancing detection number is crucial in control strategy of COVID-19. In addition, we calculated requirements for the most effective vaccination strategy based on infection number in real situation. Our model was programmed with iterative algorithms, and visualized via cellular automata, it can be applied to similar epidemics in other regions if the basic parameters are inputted, and is able to synthetically mimick the effect of multiple factors in infectious disease control., Comment: Errors appears in Results, data changed

Published

2020

17. Research Progress on Key Materials and Technologies for Secondary Batteries

Author

Junda Huang, Yuhui Zhu, Yu Feng, Yehu Han, Zhenyi Gu, Rixin Liu, Dongyue Yang, Kai Chen, Xiangyu Zhang, Wei Sun, Sen Xin, Yan Yu, Haijun Yu, Xu Zhang, Le Yu, Hua Wang, Xinhua Liu, Yongzhu Fu, Guojie Li, Xinglong Wu, Canliang Ma, Fei Wang, Long Chen, Guangmin Zhou, Sisi Wu, Zhouguang Lu, Xiuting Li, Jilei Liu, Peng Gao, Xiao Liang, Zhi Chang, Hualin Ye, Yanguang Li, Liang Zhou, Ya You, Peng-Fei Wang, Chao Yang, Jinping Liu, Meiling Sun, Minglei Mao, Hao Chen, Shanqing Zhang, Gang Huang, Dingshan Yu, Jiantie Xu, Shenglin Xiong, Jintao Zhang, Ying Wang, Yurong Ren, Chunpeng Yang, Yunhan Xu, Yanan Chen, Yunhua Xu, Zifeng Chen, Xiangwen Gao, Shengda D. Pu, Shaohua Guo, Qiang Li, Xiaoyu Cao, Jun Ming, Xinpeng Pi, Chaofan Liang, Long Qie, Junxiong Wang, Shuhong Jiao, Yu Yao, Chenglin Yan, Dong Zhou, Baohua Li, Xinwen Peng, Chong Chen, Yongbing Tang, Qiaobao Zhang, Qi Liu, Jincan Ren, Yanbing He, Xiaoge Hao, Kai Xi, Libao Chen, and Jianmin Ma

Subjects

Physical and Theoretical Chemistry

Published

2022

18. Hydrogen transport by dislocation movement in austenitic steel

Author

S. W. Ooi and Shengda D. Pu

Subjects

Condensed Matter::Quantum Gases, 010302 applied physics, Austenite, Materials science, Hydrogen, Mechanical Engineering, Lüders band, chemistry.chemical_element, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, chemistry, Mechanics of Materials, 0103 physical sciences, Hydrogen transport, engineering, General Materials Science, Physics::Atomic Physics, Austenitic stainless steel, Dislocation, Composite material, 0210 nano-technology

Abstract

Hydrogen movement within an austenitic stainless steel has been investigated by microprint technique. Hydrogen atoms show strong preferential segregation along slip bands for the hydrogen-charged then compressed specimens. Such segregation was not observed in other test conditions. This result gives strong support to the theory that dislocations act as hydrogen traps and trapped hydrogen atoms move with them during plastic deformation.

Published

2019