STABILITY OF TRANSONIC SHOCKS TO THE EULER-POISSON SYSTEM WITH VARYING BACKGROUND CHARGES

This paper is devoted to studying the stability of transonic shock solutions to the Euler-Poisson system in a one-dimensional nozzle of finite length.The background charge in the Poisson equation is a piecewise constant function.The structural stability of the steady transonic shock solution is obtained by the monotonicity argument.Furthermore,this transonic shock is proved to be dynamically and exponentially stable with respect to small perturbations of the initial data.One of the crucial ingredients of the analysis is to establish the global well-posedness of a free boundary problem for a quasilinear second order equation with nonlinear boundary conditions.

Polymer Fiber Rigid Network with High Glass Transition Temperature Reinforces Stability of Organic Photovoltaics

Organic photovoltaics(OPVs)need to overcome limitations such as insufficient thermal stability to be commercialized.The reported approaches to improve stability either rely on the development of new materials or on tailoring the donor/acceptor morphology,however,exhibiting limited applicability.Therefore,it is timely to develop an easy method to enhance thermal stability without having to develop new donor/acceptor materials or donor–acceptor compatibilizers,or by introducing another third component.Herein,a unique approach is presented,based on constructing a polymer fiber rigid network with a high glass transition temperature(T_(g))to impede the movement of acceptor and donor molecules,to immobilize the active layer morphology,and thereby to improve thermal stability.A high-T_(g) one-dimensional aramid nanofiber(ANF)is utilized for network construction.Inverted OPVs with ANF network yield superior thermal stability compared to the ANF-free counterpart.The ANF network-incorporated active layer demonstrates significantly more stable morphology than the ANF-free counterpart,thereby leaving fundamental processes such as charge separation,transport,and collection,determining the device efficiency,largely unaltered.This strategy is also successfully applied to other photovoltaic systems.The strategy of incorporating a polymer fiber rigid network with high T_(g) offers a distinct perspective addressing the challenge of thermal instability with simplicity and universality.

Experimental investigation of the effects of oil asphaltene content on CO_(2) foam stability in the presence of nanoparticles and sodium dodecyl sulfate

Foam stability tests were performed using sodium dodecyl sulfate(SDS)surfactant and SiO2 nanoparticles as foaming system at different asphaltene concentrations,and the half-life of CO_(2) foam was measured.The mechanism of foam stability reduction in the presence of asphaltene was analyzed by scanning electron microscope(SEM),UV adsorption spectrophotometric concentration measurement and Zeta potential measurement.When the mass ratio of synthetic oil to foam-formation suspension was 1:9 and the asphaltene mass fraction increased from 0 to 15%,the half-life of SDS-stabilized foams decreased from 751 s to 239 s,and the half-life of SDS/silica-stabilized foams decreased from 912 s to 298 s.When the mass ratio of synthetic oil to foam-formation suspension was 2:8 and the asphaltene mass fraction increased from 0 to 15%,the half-life of SDS-stabilized foams decreased from 526 s to 171 s,and the half-life of SDS/silica-stabilized foams decreased from 660 s to 205 s.In addition,due to asphaltene-SDS/silica interaction in the aqueous phase,the absolute value of Zeta potential decreases,and the surface charges of particles reduce,leading to the reduction of repulsive forces between two interfaces of thin liquid film,which in turn,damages the foam stability.

Influence of a liquid-filled compartment structure on the incoming shaped charge jet stability

Liquid-filled compartment structure consists of a bulk steel plate with matrix blind holes which are filled with liquid and a steel front plate to seal up the liquid with rings and bolts.The liquid-filled compartment structure can resist the shaped charge warhead effectively.This paper presents experimental and theoretical investigations of the penetration ability of the residual shaped charge jet emerging from the liquid-filled compartment structure after the penetration process at different impact angles.On the basis of shock wave propagation theory,the influence of the liquid-filled compartment structure on jet stability is analysed.The interferences of the liquid backflow caused by a reflected shock wave and a back plate on jet stability under different impact angles are also examined.In addition,the range of the disturbed velocity segments of the jet at different impact angles and the penetration ability of the residual jet are obtained.A theoretical model is validated against the experimental penetration depths.

Enabling stable 4.6 V LiCoO_(2) cathode through oxygen charge regulation strategy

LiCoO_(2) is the preferred cathode material for consumer electronic products due to its high volumetric energy density. However, the unfavorable phase transition and surface oxygen release limits the practical application of LiCoO_(2)at a high-voltage of 4.6 V to achieve a higher energy density demanded by the market. Herein, both bulk and surface structures of LiCoO_(2)are stabilized at 4.6 V through oxygen charge regulation by Gd-gradient doping. The enrichment of highly electropositive Gd on LiCoO_(2) surface will increase the effective charge on oxygen and improve the oxygen framework stability against oxygen loss.On the other hand, Gd ions occupy the Co-sites and suppress the unfavorable phase transition and microcrack. The modified LiCoO_(2) exhibits superior cycling stability with capacity retention of 90.1% over 200 cycles at 4.6 V, and also obtains a high capacity of 145.7 m Ah/g at 5 C. This work shows great promise for developing high-voltage LiCoO_(2) at 4.6 V and the strategy could also contribute to optimizing other cathode materials with high voltage and large capacity, such as cobalt-free high-nickel and lithiumrich manganese-based cathode materials.

Enhancing the stability of planar perovskite solar cells by green and inexpensive cellulose acetate butyrate

Although the efficiency of organic–inorganic hybrid halide perovskite solar cells has been improved rapidly, the intrinsic instability of perovskite materials restricts their commercial application. Here, an eco-friendly and low-cost organic polymer, cellulose acetate butyrate(CAB), was introduced to the grain boundaries and surfaces of perovskite, resulting in a high-quality and low-defect perovskite film with a nearly tenfold improvement in carrier lifetime. More importantly, the CAB-treated perovskite films have a well-matched energy level with the charge transport layers, thus suppressing carrier nonradiative recombination and carrier accumulation. As a result, the optimized CAB-based device achieved a champion efficiency of 21.5% compared to the control device(18.2%). Since the ester group in CAB bonds with Pb in perovskite, and the H and O in the hydroxyl group bond with the I and organic cations in perovskite,respectively, it will contribute to superior stability under heat, high humidity, and light soaking conditions. After aging under 35% humidity(relative humidity, RH) for 3300 h, the optimized device can still maintain more than 90% of the initial efficiency;it can also retain more than 90% of the initial efficiency after aging at 65 ℃, 65% RH, or light(AM 1.5G) for 500 h. This simple optimization strategy for perovskite stability could facilitate the commercial application of perovskite solar cells.

液晶电解质在锂离子电池中的研究进展

液晶电解质作为新型电解质材料,具有高离子导电性、优异的力学性能和热稳定性等优点,成为近年来锂离子电池领域研究的热点之一。液晶电解质可以通过自组装形成柱状相、近晶相或双连续立方相等结构,为锂离子的传输提供高效的离子传输通道。综述了液晶电解质在锂离子电池中的应用及研究进展,主要包括液晶电解质的基本概念和在锂离子电池中的研究进展,主要从离子电导率、电化学稳定性和充放电循环这3个方面来叙述。最后,对液晶电解质在锂离子电池领域未来的发展进行了展望。

Unraveling the Fundamental Mechanism of Interface Conductive Network Influence on the Fast‑Charging Performance of SiO‑Based Anode for Lithium‑Ion Batteries

Progress in the fast charging of high-capacity silicon monoxide(SiO)-based anode is currently hindered by insufficient conductivity and notable volume expansion.The construction of an interface conductive network effectively addresses the aforementioned problems;however,the impact of its quality on lithium-ion transfer and structure durability is yet to be explored.Herein,the influence of an interface conductive network on ionic transport and mechanical stability under fast charging is explored for the first time.2D modeling simulation and Cryo-transmission electron microscopy precisely reveal the mitigation of interface polarization owing to a higher fraction of conductive inorganic species formation in bilayer solid electrolyte interphase is mainly responsible for a linear decrease in ionic diffusion energy barrier.Furthermore,atomic force microscopy and Raman shift exhibit substantial stress dissipation generated by a complete conductive network,which is critical to the linear reduction of electrode residual stress.This study provides insights into the rational design of optimized interface SiO-based anodes with reinforced fast-charging performance.

基于分层架构的退役电池可重构均衡控制研究

利用退役电池构建储能系统,充分利用其剩余价值,是解决大量退役电池再利用的重要途径。然而,经过多次充放电影响,退役电池不一致性问题较新电池更为突出。在此背景下,首先,针对退役电池储能系统提出了分层式可重构均衡拓扑。其次,基于该拓扑提出了分层式均衡控制策略。考虑组内部和组间两个层次的均衡控制,组内以SOC和端电压为均衡变量,通过重构实现电池单体状态均衡,组间以SOC为均衡变量,通过重构保证全电池簇均衡。同时考虑多种运行工况:静置过程中通过自均衡提高电池组的均衡效率和可用容量,放电过程中通过拓扑结构变换维持输出电压稳定,充电过程中考虑能量损耗和充电速度合理优化充电电流,缩短充电时间,减少温升,延长电池使用寿命。最后,在Matlab中验证了所提拓扑与均衡策略在不同工况下的有效性。

战斗部装药侵彻损伤及热点生成研究

针对战斗部侵彻过程中PBX装药损伤及安定性预测问题,应用PBX炸药微裂纹-微孔洞损伤点火细观模型,研究了战斗部装药损伤演化及热点生成机理,分析了战斗部侵彻过程中不同温升机制对热点生成的影响,对比研究了战斗部前端有无缓冲材料对侵彻过程中装药力学损伤与点火响应的影响规律。结果表明,侵彻混凝土厚靶时战斗部内部装药经历多次压缩-反弹过程,反复加卸载环境使得装药内部的微缺陷损伤加剧累积,包括微裂纹的扩展和孔洞塌缩,进而导致装药头部和尾部的热点产生;微裂纹的摩擦生热为PBX装药主导的温升机制;添加缓冲材料可有效减少装药损伤、热点温升幅值及裂纹热点密度,并能有效降低装药头部的孔洞坍塌温升及宏观体温升。

三元材料锂离子电池的多阶段恒流恒压快充

锂离子电池多采取单阶段恒流恒压快速充电,容量衰减严重,并有析锂的风险。结合XRD、SEM、TEM、显微共焦拉曼(Raman)光谱等方法分析以LiNi_(0.5)Co_(0.2)Mn_(0.3)O_(2)(NCM523)为正极活性物质软包装锂离子电池在单阶段和多阶段恒流恒压策略下的循环行为。经过600次循环后(电压3.80~4.35 V、电流0.60~1.50 C),采用多阶段恒流恒压快充方法的电池的循环容量保持率为94.24%,较单阶段提升了4.91个百分点,欧姆阻抗及电荷转移阻抗的增长率为21.05%和2.86%,对比单阶段循环后分别降低了26.32及3.11个百分点;三元正极材料的层状结构比单阶段完整,多阶段负极的石墨化度为0.061 7,比单阶段低0.028 2,析锂现象更轻微。多阶段恒流恒压充电在快充工况中的性能优势更加明显。

基于多元线性回归模型的预裂爆破参数分析

某露天铜矿采用预裂爆破控制技术进行靠帮作业,为进一步优化预裂爆破参数,分析不同预裂爆破参数对爆破效果的影响,本文引入多元线性回归模型,以预裂孔孔距a和预裂缝至缓冲孔排距D为目标变量,以未破碎矿岩量Y为预测变量,根据二因素三水平均匀设计法进行预裂爆破试验。研究结果表明:(1)多元线性回归模型拟合度R^(2)=0.692,拟合效果良好,可用于优化预裂爆破参数研究;(2)在其他预裂爆破参数不变的情况下,为取得最佳爆破效果,建议预裂孔孔距a及预裂缝至缓冲孔排距D的分别选取1.1 m与2.4 m;(3)预裂孔孔距a与未破碎矿岩量Y呈正相关性,预裂缝至缓冲孔排距D对未破碎矿岩量Y的影响程度更大。

氧化气氛中PdAg纳米合金的表面相稳定性与原子电荷的关系

在多相催化中,纳米合金的氧化和偏析可能导致特殊的电催化性质。基于第一性原理原子热力学方法,本文通过表面相稳定性图计算氧化气氛中Pd_(6)@Ag_(32)和Ag_(6)@Pd_(32)核壳纳米合金的早期氧化阶段。Ag_(38)纳米团簇(Δμ_(0)=-0.95 eV)的稳定性高于Pd_(38)纳米团簇(Δμ_(0)=-1.3 eV),但是Pd_(6)@Ag_(32)核壳纳米合金(Δμ_(0)=-0.9 eV)显示出高于Ag_(38)纳米团簇的表面相稳定性,而Pd偏析的Pd_(6)@Ag_(32)纳米合金的稳定性低于Ag_(38)纳米团簇。同时,Ag_(6)@Pd_(32)核壳纳米合金(Δμ_(0)=-1.5 eV)的表面相稳定性比Pd_(38)纳米团簇低,而Ag偏析的Ag_(6)@Pd_(32)纳米合金显示出高于Pd_(38)纳米团簇的表面相稳定性。表面Ag原子偏析越多的Pd_(6)@Ag_(32)和Ag_(6)@Pd_(32)核壳纳米合金具有更高的表面相稳定性。表面相稳定性的顺序遵循原子电荷的趋势,即越多的负电荷对应于越低的表面相稳定性。研究结果能够为设计燃料电池中具有合适表面相稳定性的PdAg基纳米合金催化剂提供有效信息。

原油沥青质含量对纳米颗粒-十二烷基硫酸钠发泡二氧化碳泡沫稳定性的影响

采用十二烷基硫酸钠(SDS)表面活性剂和SiO_(2)纳米颗粒作为发泡体系,在不同原油沥青质含量下进行泡沫稳定性实验,测量CO_(2)泡沫半衰期;采用扫描电子显微图像、紫外分光光度法测试和Zeta电位测量,分析沥青质降低CO_(2)泡沫稳定性的机理。研究表明:当合成油与发泡体系质量比为1∶9时,合成油沥青质质量分数从0增至15%,SDS稳定泡沫半衰期从751 s减少至239 s,SDS-SiO_(2)稳定泡沫半衰期从912 s缩短至298 s;当合成油与发泡体系质量比为2∶8时,随着沥青质质量分数增大,SDS稳定泡沫半衰期从526 s缩短至171 s,SDS-SiO_(2)稳定泡沫半衰期从660 s缩短至205 s。由于沥青质与SDS和SiO_(2)纳米颗粒在水相中的相互作用,Zeta电位绝对值减小,颗粒表面电荷降低,导致薄液膜两侧界面之间的排斥力减小,从而破坏泡沫稳定性。

Synchrotron-Radiation Photoemission Study of Growth and Stability of Au Clusters on Rutile TiO2（110）-1×1

The growth and thermal stability of Au clusters on a partially-reduced rutile TiO2 （110）-1 × 1 surface were investigated by high-resolution photoelectron spectroscopy using synchrotron- radiation-light. The valence-band photoelectron spectroscopy results demonstrate that the Ti^3＋3d feature attenuates quickly with the initial deposition of Au clusters, implying that Au clusters nucleate at the oxygen vacancy sites. The Au4f core-level photoelectron spectroscopy results directly prove the existence of charge transfer from oxygen vacancies to Au clusters. The thermal stability of Au clusters on the partially-reduced and stoichiometric TiO2（110） surfaces was also comparatively investigated by the annealing experiments. With the same film thickness, Au clusters are more thermally stable on the partially-reduced TiO2（110） surface than on the stoichiometric TiO2（110） surface. Meanwhile, large Au nanoparticles are more thermally stable than fine Au nanoparticles.

N/P比对锂离子混合型电容器性能的影响研究

锂离子混合型电容器因兼具锂离子电池的高比能量和超级电容器的高比功率优点而被高度重视。然而,负极/正极容量比(N/P)的变化,不仅会在初始循环过程中造成容量损失消耗活性锂,而且可能导致过充电和过放电,对锂离子混合型电容器的长期循环稳定性、快充性能和安全性能的影响很大。因此,研究N/P比对于首次库伦效率(ICE)、循环性能、快充性能和安全性能具有重要意义。本文采用活性炭和电池型材料LiNi_(0.5)Co_(0.2)Mn_(0.3)O_(2)做复合正极材料(AC/NCM),硬碳(HC)做负极材料,设计并制备了不同N/P比(0.5、0.6、0.8、1.2、1.8、2.7)的软包锂离子混合型电容器,通过一系列研究表明,N/P比远大于1时,对能量密度和首效的发挥不利,N/P比小于1时,对安全性能极为不利。

小直径乳化炸药装药质量稳定性的研究

通过对小直径胶状乳化炸药生产过程中装药系统的辅助装置和压力、温度、流量等工艺参数进行监测统计,再分析调整;同时对产品的敏化工艺进行试验与改进,解决了小直径产品质量不稳定的问题,提高了产品的合格率。

碱金属离子共掺Sr_(3)Ga_(2)Ge_(4)O_(14)∶Dy^(3+)发光性能研究

本文采用高温固相法制备了一系列新型Sr_(3-x)Ga_(2)Ge_(4)O_(14)∶xDy^(3+)(x=0~0.40)(摩尔分数)及Sr_(2.68)Ga_(2)Ge_(4)O_(14)∶0.16Dy^(3+),0.16M^(+)(M=Li、Na、K)荧光粉。EDS能谱分析证实该荧光粉中存在Sr、Ga、Ge、O、Dy元素。系列Sr_(3-x)Ga_(2)Ge_(4)O_(14)∶xDy^(3+)在350 nm光激发下产生了以568 nm为主波长,对应于^(4)F_(9/2)→^(6)H_(13/2)跃迁的强黄光发射。荧光粉的发射光谱显示,其发射强度随Dy^(3+)浓度的增加而变化,且当x=0.16时达到最强。共掺杂碱金属M(M=Li、Na、K)作为电荷补偿离子,其中Li^(+)对增加Dy^(3+)的发射强度效果最明显,使得荧光粉的发射强度提高到没有电荷补偿离子时的2倍。此外,随着Dy3+掺杂浓度的提高,荧光粉的荧光寿命不断减少。最后探讨了荧光粉Sr_(2.68)Ga_(2)Ge_(4)O_(14)∶0.16Dy^(3+),0.16Li^(+)的CIE色度坐标和热稳定性,其CIE色度坐标为(0.3719,0.4046),位于黄色区域,在453 K的发光强度约为其室温发光强度的95.5%。因此,Dy^(3+),Li^(+)共掺杂Sr_(3-x)Ga_(2)Ge_(4)O_(14)荧光粉是潜在的显示器件和白光LED器件候选材料。

大规模电动汽车充电对配电网稳定性的影响与调度优化研究

随着电动汽车的普及和大规模使用,电车充电对配电网稳定性产生了重要影响。文章通过分析电动汽车充电特点、充电负荷对配电网稳定性的影响机理,以及现有问题和挑战,提出了配电网稳定性调度优化方法,主要包括建立电动汽车充电负荷预测模型、设计配电网负荷平衡优化策略。同时,探讨了充电设施布局优化方法,通过优化充电站的地理位置和数量,提高充电服务的覆盖率和效率。结合仿真与实验验证,评估文章所提优化算法的效果,验证了算法在实际应用中的可行性和稳定性。文章的研究为电动汽车充电对配电网稳定性的影响提供了深入的理论分析和实用的解决方案,为提高配电网稳定性提供了重要参考,对于配电网运营商和电动汽车用户具有实际指导意义。

Study about thermal runaway behavior of high specific energy density Li-ion batteries in a low state of charge

Lithium-ion batteries are widely used in electric vehicles and electronics, and their thermal safety receives widespread attention from consumers. In our study, thermal runaway testing was conducted on the thermal stability of commercial lithium-ion batteries, and the internal structure of the battery was analyzed with an in-depth focus on the key factors of the thermal runaway. Through the study of the structure and thermal stability of the cathode, anode, and separator, the results showed that the phase transition reaction of the separator was the key factor affecting the thermal runaway of the battery for the condition of a low state of charge.