A combined method using Lattice Boltzmann Method(LBM)and Finite Volume Method(FVM)to simulate geothermal reservoirs in Enhanced Geothermal System(EGS)

With the development of industrial activities,global warming has accelerated due to excessive emission of CO_(2).Enhanced Geothermal System(EGS)utilizes deep geothermal heat for power generation.Although porous medium theory is commonly employed to model geothermal reservoirs in EGS,Hot Dry Rock(HDR)presents a challenge as it consists of impermeable granite with zero porosity,potentially distorting the physical interpretation.To address this,the Lattice Boltzmann Method(LBM)is employed to simulate CO_(2)flow within geothermal reservoirs and the Finite Volume Method(FVM)to solve the energy conservation equation for temperature distribution.This combined method of LBM and FVM is imple-mented using MATLAB.The results showed that the Reynolds numbers(Re)of 3,000 and 8,000 lead to higher heat extraction rates from geothermal reservoirs.However,higher Re values may accelerate thermal breakthrough,posing challenges to EGS operation.Meanwhile,non-equilibrium of density in fractures becomes more pronounced during the system's life cycle,with non-Darcy's law becoming significant at Re values of 3,000 and 8,000.Density stratification due to buoyancy effects significantly impacts temperature distribution within geothermal reservoirs,with buoyancy effects at Re=100 under gravitational influence being noteworthy.Larger Re values(3,000 and 8,000)induce stronger forced convection,leading to more uniform density distribution.The addition of proppant negatively affects heat transfer performance in geothermal reservoirs,especially in single fractures.Practical engineering considerations should determine the quantity of proppant through detailed numerical simulations.

YPO_4 nanocrystals: preparation and size-induced lattice symmetry enhancement

YPO4 and Eu doped YPO4 nanocrystals were prepared via a simple hydrothermal method. The phase purity, rnicrostructure, surface absorbed water and luminescence properties were characterized with X-ray diffraction （XRD）, transmission electron microscopy （TEM）, fluorescence spectrum, infrared spectroscopy, Raman spectroscopy and thermogravimetry analysis（TGA）. Combined with XRD and TEM analysis, it was found that YPO4 nanocrystals crystallized into a single phase of tetragonal （141/amd） zircon structure. YPO4 nanocrystals showed a size reduction with the reaction temperature decreasing. Considering the XRD, IR and Raman results, a lattice expansion and the unit cell symmetry enhancement were observed with the particle size decreasing. A dipole to dipole interaction model was applied to investigate the relationship of the variation of microstrucmre and the particle size. The emission spectrum of Eu doped YPO4 nanocrystals was also presented and the emission bands were clearly ascribed to the f to f transitions of Eu^3＋.

Interplay between out-of-plane magnetic plasmon and lattice resonance for modified resonance lineshape and near-field enhancement in double nanoparticles array

Two-dimensional double nanoparticle （DNP） arrays are demonstrated theoretically, supporting the interaction between out-of-plane magnetic plasmons and in-plane lattice resonances, which can be achieved by tuning the nanoparticle height or the array period due to the height-dependent magnetic resonance and the periodicity-dependent lattice resonance. The interplay between the two plasmon modes can lead to a remarkable change in resonance lineshape and an improvement on magnetic field enhancement. Simultaneous electric field and magnetic field enhancement can be obtained in the gap region between neighboring particles at two resonance frequencies as the interplay occurs, which presents “open” cavities as electromagnetic field hot spots for potential applications on detection and sensing. The results not only offer an attractive way to tune the optical responses of plasmonic nanostructure, but also provide further insight into the plasmon interactions in periodic nanostructure or metamaterials comprising multiple elements.

面向金属泡沫散热器设计的自然对流拓扑优化

针对传统方块型金属泡沫散热器散热效率不高,难以满足高功率电子器件散热需求的问题,发展了基于格子Boltzmann和水平集方法的三维拓扑优化方法。首先,采用格子Boltzmann方法求解多孔介质内的流动和传热过程;然后,采用伴随格子Boltzmann方法计算梯度;最后,根据反应-扩散方程更新水平集函数。通过对底部放置发热元件方腔的自然对流过程开展拓扑优化,得到特征格拉晓夫数为2.4×10^(2)~1.2×10^(5)的4种优化散热器结构,定量评估了散热器的强化换热性能并分析相关机理。研究结果表明:随着格拉晓夫数的增大,散热主导机制由热传导转变为热对流,优化结构由伸展的树枝状向收缩的花朵状结构转变,以留出更多空间使得流动涡旋充分发展;与传统的金属泡沫方块结构和开槽的金属泡沫块结构相比,所提优化结构表现出优异的散热性能,其分支结构和中空结构能够优化方腔内的流动,从而将散热效率提升了29.7%以上,表明了所提拓扑优化方法的有效性。研究工作可为新型金属泡沫散热器的设计提供理论指导。

致密砂岩气藏注CO_(2)提高天然气采收率微观机理

中国致密砂岩气藏资源储量丰富,复杂的气水渗流关系和气水同产特征制约了单井产能的发挥和天然气采收率提高,注CO_(2)是提高气藏采收率(EGR)和实现碳埋存的双赢途径。为明确致密砂岩气藏CO_(2)驱替微观渗流和提高天然气采收率机理,指导致密砂岩气藏CO_(2)-EGR方案设计,基于格子玻尔兹曼方法(LBM)建立了孔隙尺度多相多组分流动模型,揭示了致密砂岩气藏储层微观气水分布特征和CO_(2)-EGR的微观渗流机理,并明确了CO_(2)-EGR的主控因素。研究结果表明:①驱动压差显著影响了致密砂岩气藏的气水微观分布和水锁程度,使得气水流动能力和气水相对渗透率特征不同;②CO_(2)-EGR微观渗流过程包括气水两相的非混相驱替和CO_(2)-CH_(4)的混相驱替,对应EGR机理为分别受生产压差和地层压力控制的黏性驱替和混相扩散;③注入的CO_(2)可有效缓解水锁现象和贾敏效应,与CH_(4)良好的混相能力能促进沟通分散气泡,微观驱气效率可达42%~94%;④含水饱和度、孔隙结构和驱动压差显著影响微观驱气的作用机制和驱气效率的改善幅度。结论认为,在进行致密砂岩气CO_(2)-EGR的方案设计时,可优先考虑中—低含水饱和度的区块作为试验靶区,并根据靶区储层孔隙结构特征,优化不同注气阶段的注采参数,可充分发挥CO_(2)对CH_(4)的黏性驱替和混相扩散作用。

Hydro-mechanical-electrical simulations of synthetic faults in two orthogonal directions with shear-induced anisotropy

Fluid flow in fractures controls subsurface heat and mass transport,which is essential for developing enhanced geothermal systems and radioactive waste disposal.Fracture permeability is controlled by fracture microstructure(e.g.aperture,roughness,and tortuosity),but in situ values and their anisotropy have not yet been estimated.Recent advances in geophysical techniques allow the detection of changes in electrical conductivity due to changes in crustal stress and these techniques can be used to predict subsurface fluid flow.However,the paucity of data on fractured rocks hinders the quantitative interpretation of geophysical monitoring data in the field.Therefore,considering different shear displacements and chemical erosions,an investigation was conducted into the hydraulic-electric relationship as an elevated stress change in fractures.The simulation of fracture flows was achieved using the lattice Boltzmann method,while the electrical properties were calculated through the finite element method,based on synthetic faults incorporating elastic-plastic deformation.Numerical results show that the hydraulic and electrical properties depend on the rock's geometric properties(i.e.fracture length,roughness,and shear displacement).The permeability anisotropy in the direction parallel or perpendicular to the shear displacement is also notable in high stress conditions.Conversely,the permeability econductivity(i.e.,formation factor)relationship is unique under all conditions and follows a linear trend in logarithmic coordinates.However,both matrix porosity and fracture spacing alter this relationship.Both increase the slope of the linear trend,thereby changing the sensitivity of electrical observations to permeability changes.

基于选区激光熔化的Ti-6Al-4V钛合金节点增强型点阵结构及其力学行为

以Ti-6Al-4V钛合金粉末为原材料,采用选区激光熔化技术制备了常规和节点增强型体心四方点阵结构。研究了两种点阵结构的形貌、微观结构及力学性能。并探究了常规热处理对节点增强型点阵结构微观结构及力学性能的影响。结果表明,在节点处提高制备激光功率后该处直径增大,节点处表面粗糙度及孔隙率值均增大,整体结构相对密度提高24.8%,节点处初生β晶发生了等轴化。增强后的点阵结构失效由贯穿整体的斜60°瞬间坍塌模式转变为逐层沉降式坍塌模式,比弹性模量增加了112%,比抗压强度增加了52%,30%应变时的比吸能提升了88%,整体力学性能有了显著提升。热处理后节点增强型点阵结构抗压强度下降,但能量吸收能力得到了提高。

Thermal and Structural Insight into Lightweight Lattice Channels for Active Cooling Technology

The active cooling technology that can reduce the combustor temperature is commonly used to protect the scramjet.In order to further improve the performance of active cooling,the structural weight reduction,cooling efficiency and stress level of the cooling channel must be considered simultaneously.In this paper,new types of lattice channels for active cooling were designed and compared with the conventional cooling channel in terms of weight reduction,thermal and structural performance.The results showed that,at the same channel height,the cooling channel with staggered lattice arrays has the optimal comprehensive performance:the weight reduction effect reaches 39.93%;the wall temperature drops significantly,and the maximum Nu number is 2.155times of the conventional channel.The flow field analysis showed that horseshoe vortices formed by the impact effect and hairpin vortices near the trailing edge are the main factors of heat transfer enhancement.The disturbed boundary layer and the excited turbulent kinetic energy also contribute much to enhance the heat transfer.In addition,due to the HTE-induced increment of metal tensile strength,the system reliability of lattice channel is better than the conventional one.

Integrating lattice and gap plasmonic modes to construct dual-mode metasurfaces for enhancing light–matter interaction

Photonic structures with optical resonances beyond a single controllable mode are strongly desired for enhancing light±matter interactions and bringing about advanced photonic devices. However, the realization of effective multimodal photonic structures has been restricted by the limited tunable range of mode manipulation, the spatial dispersions of electric fields or the polarization-dependent excitations. To overcome these limitations, we create a dualmode metasurface by integrating the plasmonic surface lattice resonance and the gap plasmonic modes;this metasurface offers a widely tunable spectral range, good overlap in the spatial distribution of electric fields, and polarization independence of excitation light. To show that such dual-mode metasurfaces are versatile platforms for enhancing light±matter interactions, we experimentally demonstrate a significant enhancement of second-harmonic generation using our design, with a conversion efficiency of 1±3 orders of magnitude larger than those previously obtained in plasmonic systems. These results may inspire new designs for functional multimodal photonic structures.

轻质高强点阵金属材料的制备及其力学性能强化的研究进展

如何在现有的材料和结构基础上减轻重量并获得更优良的力学性能是材料和力学工作者面临的挑战.概述了国内外轻质点阵金属材料的主要制备技术,评价了点阵金属三明治板的关键焊接技术,并根据各类点阵金属材料的微结构特征分析了其静态力学性能.针对点阵金属材料力学性能强化的关键点进行了系统分析,总结和阐述了点阵金属材料强化研究的关键进展,讨论并展望了轻质材料和结构的研究发展趋势.

格子波尔兹曼方法的医学图像同步去噪增强算法

格子波尔兹曼的理论基础为分子动理学和统计力学,具有算法简单高效,执行速度快,易于并行处理等优点,近年来成功地应用于图像处理领域.本文针对医学图像反差较低且包含噪声污染的特点,通过设计分段线性拉伸函数作为格子波尔兹曼方程的外力项,实现医学图像的同步去噪和反差增强.同时构建基于TV下降流的PDE反差增强模型与本文的方法进行对比,实验表明,本文的方法处理效果优于TV下降流对应的效果.

组合表面调控液滴特性强化蒸汽冷凝传热

制备了具有不同疏水区宽度和面积分率的疏水-亲水间隔规则排列的组合表面。观测常压蒸汽在组合表面上冷凝时疏水区液滴的特性(液滴移除方式和最大液滴半径),利用格子Boltzmann方法模拟组合表面上凝液的运动。考察疏水区、亲水区宽度和表面过冷度对组合表面强化蒸汽冷凝传热的影响。利用滴状-膜状组合传热模型分析组合表面蒸汽冷凝传热性能的影响因素,并与实验结果比较。发现疏水区液滴自发地向亲水区定向迁移,精细设计的组合表面可以实现蒸汽滴状冷凝传热的强化,实验中强化因子可达1.20。疏水区宽度约为0.55 mm时组合表面的传热性能最大。表面过冷度越大,组合表面强化传热的效果越差,模型分析与实验结果吻合良好。

基于时变信号模型和格型陷波器的科氏流量计信号处理方法

采用能跟踪频率变化的自适应格型陷波器对频率、幅值和相位均按照随机游动模型变化的科氏流量计传感器输出信号进行滤波,求其频率;采用自适应谱线增强器从含有噪声的数据中提取出信号;然后采用具有重叠窗的滑动G oertze l算法实时计算两路信号之间的相位差和时间差,求得质量流量。仿真和测试结果表明所研究的方法是有效的。

掺磷氢化纳晶硅薄膜的晶粒尺寸和晶格畸变的研究

采用等离子增强化学气相沉积在玻璃衬底上制备了掺磷氢化纳晶硅薄膜,并利用X射线衍射谱(XRD)和拉曼散射谱研究了PH3浓度(GFR=[PH3]/[Si H4])对薄膜平均晶粒尺寸和晶格畸变的影响.结果显示磷弱掺杂有利于晶化,而重掺杂抑制晶化.随着GFR的增大,Si(111)方向上的平均晶粒尺寸呈现出先减小后增大的趋势,而对应的晶格畸变则呈现了相反的变化趋势,小的晶粒尺寸诱导了大的晶格畸变.该结果可归结于与平均晶粒尺寸相关的表面增强效应.在掺磷氢化纳晶硅薄膜的制备过程中,PH起了关键的有效掺杂作用.

气液界面传质过程Rayleigh对流模拟的格子Boltzmann方法

浓度梯度导致的Rayleigh对流是一种通常在传质过程中观察到的界面现象.为了模拟乙醇吸收CO2气液传质过程中界面传质引发的Rayleigh对流现象,提出了描述界面扰动的随机扰动模型,并建立了带有双分布模型的二维格子Boltzmann方法(LBM).模拟二维液相Rayleigh对流过程中,假设界面上CO2浓度为常数.通过模拟研究,确定了随机扰动模型的2个参数:局部扰动概率P和浓度扰动大小ρD.模拟结果表明,当0<ρD≤10-9,kg/m3、10-6≤P≤10-1时,平均液相传质系数存在一个稳定值:(1.09±0.02)×10-5,m/s.通过考察浓度分布结构,分析了Rayleigh对流的时空演化过程.根据模拟结果定义并计算了传质增强因子,其证明了Rayleigh对流能够有效地强化界面传质.

基于时变信号模型和归一化格型陷波器的科氏流量计信号处理方法

采用具有跟踪频率变化能力的自适应归一化格型陷波器,对频率、幅值和相位均按照随机游动模型变化的科氏流量传感器信号进行滤波,以求得其频率;再采用自适应谱线增强器从含有噪声的数据中提取所需要的信号;然后采用具有重叠窗的滑动Goertzel算法计算两路信号之间的实时相位差,并通过频率和相位差计算时间差,求得质量流量。仿真结果表明该方法是有效的。

基于格型陷波滤波器的科里奥利质量流量计信号处理方法

采用比IIR型计算更为简单的自适应格型陷波滤波器对科里奥利质量流量计的流量传感器的输出信号进行滤波并求得其频率;并应用自适应谱线增强器从含有噪声的信号中提取出流量管振动的基频信号;然后采用滑动Goertzel算法计算两路信号之间的实时相位差,再根据频率和相位差计算出时间差最终求得质量流量。

基于光照预处理与特征提取的纺织品瑕疵检测方法

针对光照对纺织品图像特征提取的影响以及传统完整局部二值模式(complete local binary pattern)算法的局限性,本文提出了一种基于局部对比度增强(local contrast enhancement)算法的改进CLBP特征提取方法并将其应用到纺织品瑕疵检测中。该方法采用局部对比度增强算法对受光照影响的纺织品图像进行预处理,使用改进CLBP算法对分块后(格分割)图像进行特征提取,计算每一格子特征值与标准特征值的KLD散度并与训练得到的阈值进行比较,大于阈值格子标记为瑕疵。使用本文方法在标准星形(star)数据库与箱形(box)数据库中实验结果表明,该方法与其他预处理方法相比有更加出色的处理效果,大部分检测结果的查全率均可达到0.99左右。

一种基于自适应谱线分离的大功率抑制干扰方法

基于有效抑制各种大功率窄带和宽带干扰这一目的,提出了一种利用自适应谱线增强器分离并抑制的方法。该方法通过多个IIR格型陷波器级联将干扰信号和有用信号完全分离,再通过减法器恢复出待处理的期望信号。讨论了基于相位一致性逼近准则对多个IIR格型陷波器级联系数的全局化设计,并通过一个跳频信号检测实例,分析了干扰信号的分离和消除程度。仿真结果表明,除同频干扰外该方法能将大功率窄带和宽带干扰几乎完全分离和抑制,为恶意干扰环境下的通信接收机增强免疫力提供了一种有效的解决方法。

伪势格子Boltzmann方法的汽化热阱效应模拟研究

采用伪势格子Boltzmann方法的气液相变模型对饱和状态下亲疏水壁面上单气泡的相变传热进行直接的数值模拟.从结果中观察到:加热初期,亲水壁面与发生相变的气液界面之间存在液体微层;疏水壁面的相变则紧贴壁面进行,即疏水壁面近壁处不存在气液界面.模拟亲水壁面在不同时刻热源与气液界面之间的温差变化曲线,以及不同时间段近壁处的热流密度变化曲线,模拟结果表明气液界面的存在对传热起到强化作用.模拟同一温度下不同重力加速度与气泡脱离直径大小的关系曲线,其结果符合Fritz理论,从而对伪势格子Boltzmann方法的气液相变模型进行定性验证.