Relative Impacts of Sea Ice Loss and Atmospheric Internal Variability on the Winter Arctic to East Asian Surface Air Temperature Based on Large-Ensemble Simulations with NorESM2

To quantify the relative contributions of Arctic sea ice and unforced atmospheric internal variability to the “warm Arctic, cold East Asia”(WACE) teleconnection, this study analyses three sets of large-ensemble simulations carried out by the Norwegian Earth System Model with a coupled atmosphere–land surface model, forced by seasonal sea ice conditions from preindustrial, present-day, and future periods. Each ensemble member within the same set uses the same forcing but with small perturbations to the atmospheric initial state. Hence, the difference between the present-day(or future) ensemble mean and the preindustrial ensemble mean provides the ice-loss-induced response, while the difference of the individual members within the present-day(or future) set is the effect of atmospheric internal variability. Results indicate that both present-day and future sea ice loss can force a negative phase of the Arctic Oscillation with a WACE pattern in winter. The magnitude of ice-induced Arctic warming is over four(ten) times larger than the ice-induced East Asian cooling in the present-day(future) experiment;the latter having a magnitude that is about 30% of the observed cooling. Sea ice loss contributes about 60%(80%) to the Arctic winter warming in the present-day(future) experiment. Atmospheric internal variability can also induce a WACE pattern with comparable magnitudes between the Arctic and East Asia. Ice-lossinduced East Asian cooling can easily be masked by atmospheric internal variability effects because random atmospheric internal variability may induce a larger magnitude warming. The observed WACE pattern occurs as a result of both Arctic sea ice loss and atmospheric internal variability, with the former dominating Arctic warming and the latter dominating East Asian cooling.

CAS-ESM2.0 Successfully Reproduces Historical Atmospheric CO_(2) in a Coupled Carbon−Climate Simulation

The atmospheric carbon dioxide(CO_(2))concentration has been increasing rapidly since the Industrial Revolution,which has led to unequivocal global warming and crucial environmental change.It is extremely important to investigate the interactions among atmospheric CO_(2),the physical climate system,and the carbon cycle of the underlying surface for a better understanding of the Earth system.Earth system models are widely used to investigate these interactions via coupled carbon-climate simulations.The Chinese Academy of Sciences Earth System Model version 2(CAS-ESM2.0)has successfully fixed a two-way coupling of atmospheric CO_(2)with the climate and carbon cycle on land and in the ocean.Using CAS-ESM2.0,we conducted a coupled carbon-climate simulation by following the CMIP6 proposal of a historical emissions-driven experiment.This paper examines the modeled CO_(2)by comparison with observed CO_(2)at the sites of Mauna Loa and Barrow,and the Greenhouse Gases Observing Satellite(GOSAT)CO_(2)product.The results showed that CAS-ESM2.0 agrees very well with observations in reproducing the increasing trend of annual CO_(2)during the period 1850-2014,and in capturing the seasonal cycle of CO_(2)at the two baseline sites,as well as over northern high latitudes.These agreements illustrate a good ability of CAS-ESM2.0 in simulating carbon-climate interactions,even though uncertainties remain in the processes involved.This paper reports an important stage of the development of CAS-ESM with the coupling of carbon and climate,which will provide significant scientific support for climate research and China’s goal of carbon neutrality.

Basalt Petrology, Water Chemistry, and Their Impact on the CO_(2) Mineralization Simulation at Leizhou Peninsula Sites, Southern China

Mineral carbonation, which precipitates dissolved carbon dioxide(CO_(2)) as carbonate minerals in basaltic groundwater environments, is a potential technique for negative emissions. The Leizhou Peninsula in southwest Guangdong province has extensive basalt, indicating a promising potential for CO_(2) storage through rapid mineralization. However, understanding of the basic geological setting, potential, and mechanisms of CO_(2) mineralization in the basalts of the Leizhou Peninsula is still limited. The mineralization processes associated with CO_(2)storage at two candidate sites in the area are investigated in this paper: Yongshi Farm and Tianyang Basin(of the dried maar lake). Petrography,rock geochemistry, basalt petrophysical properties, and groundwater hydrochemistry analyses are included in the study. Numerical simulation is used to examine the reaction process and its effects. The results show that basalts in the study areas mainly comprise plagioclase, pyroxene, and Fe–Ti oxides, revealing a total volume fraction exceeding 85%. Additionally, small amounts of quartz and fayalite are available, with volume fractions of 5.1% and 1.0%, respectively. The basalts are rich in divalent metal cations, which can form carbonate minerals, with an average of approximately 6.2 moles of metal cations per 1 kg of rock. The groundwater samples have a pH of 7.5–8.2 and are dominated by the Mg–Ca–HCO3 type. The basalts demonstrate a porosity range of 10.9% to 28.8%, with over 70% of interconnected pores. A 20-year geochemical simulation revealed that CO_(2) injection dissolves primary minerals, including anorthite, albite, and diopside, while CO_(2)mineralization dissolves precipitation secondary minerals, such as calcite, siderite, and dolomite. Furthermore, a substantial rise in pH from 7.6to 10.6 is observed in the vicinity of the injected well, accompanied by a slight reduction in porosity from 20% to 19.8%. Additionally, 36.8% of the injected CO_(2) underwent complete mineralization within five years, revealing an increasing percentage of 66.1% if the experimental period is extended to 20 years. The presence of abundant divalent metal cations in basalts and water-bearing permeable rocks in the Leizhou Peninsula supports the potential for mineral carbonation in basalts, as indicated by the geochemical simulation results. Additional research is necessary to identify the factors that influence the CO_(2) mineralization, storage, and sensitivity analysis of basalt in the Leizhou Peninsula.

Numerical Simulation of Asphaltene Precipitation and Deposition during Natural Gas and CO_(2) Injection

Asphaltene deposition is a significant problem during gas injection processes,as it can block the porous medium,the wellbore,and the involved facilities,significantly impacting reservoir productivity and ultimate oil recovery.Only a few studies have investigated the numerical modeling of this potential effect in porous media.This study focuses on asphaltene deposition due to natural gas and CO_(2) injection.Predictions of the effect of gas injection on asphaltene deposition behavior have been made using a 3D numerical simulation model.The results indicate that the injection of natural gas exacerbates asphaltene deposition,leading to a significant reduction in permeability near the injection well and throughout the reservoir.This reduction in permeability strongly affects the ability of gas toflow through the reservoir,resulting in an improvement of the displacement front.The displacement effi-ciency of the injection gas process increases by up to 1.40%when gas is injected at 5500 psi,compared to the scenario where the asphaltene model is not considered.CO_(2) injection leads to a miscible process with crude oil,extracting light and intermediate components,which intensifies asphaltene precipitation and increases the viscosity of the remaining crude oil,ultimately reducing the recovery rate.

Investigation of gravity influence on EOR and CO_(2) geological storage based on pore-scale simulation

Gravity assistance is a critical factor influencing CO_(2)-Oil mixing and miscible flow during EOR and CO_(2)geological storage.Based on the Navier-Stokes equation,component mass conservation equation,and fluid property-composition relationship,a mathematical model for pore-scale CO_(2) injection in oilsaturated porous media was developed in this study.The model can reflect the effects of gravity assistance,component diffusion,fluid density variation,and velocity change on EOR and CO_(2) storage.For nonhomogeneous porous media,the gravity influence and large density difference help to minimize the velocity difference between the main flow path and the surrounding area,thus improving the oil recovery and CO_(2) storage.Large CO_(2) injection angles and oil-CO_(2) density differences can increase the oil recovery by 22.6% and 4.2%,respectively,and increase CO_(2) storage by 37.9% and 4.7%,respectively.Component diffusion facilitates the transportation of the oil components from the low-velocity region to the main flow path,thereby reducing the oil/CO_(2) concentration difference within the porous media.Component diffusion can increase oil recovery and CO_(2) storage by 5.7% and 6.9%,respectively.In addition,combined with the component diffusion,a low CO_(2) injection rate creates a more uniform spatial distribution of the oil/CO_(2) component,resulting in increases of 9.5% oil recovery and 15.7% CO_(2) storage,respectively.This study provides theoretical support for improving the geological CO_(2) storage and EOR processes.

A review of interaction mechanisms and microscopic simulation methods for CO_(2)-water-rock system

This work systematically reviews the complex mechanisms of CO_(2)-water-rock interactions,microscopic simulations of reactive transport(dissolution,precipitation and precipitate migration)in porous media,and microscopic simulations of CO_(2)-water-rock system.The work points out the key issues in current research and provides suggestions for future research.After injection of CO_(2) into underground reservoirs,not only conventional pressure-driven flow and mass transfer processes occur,but also special physicochemical phenomena like dissolution,precipitation,and precipitate migration.The coupling of these processes causes complex changes in permeability and porosity parameters of the porous media.Pore-scale microscopic flow simulations can provide detailed information within the three-dimensional pore and throat space and explicitly observe changes in the fluid-solid interfaces of porous media during reactions.At present,the research has limitations in the decoupling of complex mechanisms,characterization of differential multi-mineral reactions,precipitation generation mechanisms and characterization(crystal nucleation and mineral detachment),simulation methods for precipitation-fluid interaction,and coupling mechanisms of multiple physicochemical processes.In future studies,it is essential to innovate experimental methods to decouple“dissolution-precipitation-precipitate migration”processes,improve the accuracy of experimental testing of minerals geochemical reaction-related parameters,build reliable characterization of various precipitation types,establish precipitation-fluid interaction simulation methods,coordinate the boundary conditions of different physicochemical processes,and,finally,achieve coupled flow simulation of“dissolution-precipitation-precipitate migration”within CO_(2)-water-rock systems.

无与伦比的音乐体验 Yamaha雅马哈R-N2000A流媒体高保真功放与NS-2000A旗舰落地音箱

说起日本的Hi-Fi音响产品,相信有一定资历的发烧友还记得当年“百花齐放”的那番景象。当CD唱片发明后,日本的Hi-Fi产品进入爆发式增长时期,除了常见的索尼、雅马哈、先锋、松下、建伍、三洋等等大家熟悉品牌之外,就连三菱、东芝等品牌也曾推出Hi-Fi产品,可想而知当年的火爆程度。时代的步伐不断往前,当铅华洗尽后,到现时依旧推出Hi-Fi产品的日本品牌也所剩无几,雅马哈便是其中之一。

宽负荷下切圆燃煤锅炉H_(2)S分布特性的数值模拟

锅炉采用空气分级燃烧降低NO_(x)排放的同时也提高了主燃区H_(2)S体积分数。炉墙壁面过高的H_(2)S体积分数是加剧水冷壁高温腐蚀的重要因素。为保障新能源并网发电,大型燃煤机组灵活调峰的需求增加,不同负荷下的水冷壁近壁面H_(2)S分布特性值得关注。通过正交试验分析了切圆燃煤锅炉运行参数对水冷壁近壁面H_(2)S体积分数分布的影响。选取一台超临界600 MW切圆燃煤锅炉建立数值模型,设计L_(16)(4^(5))正交工况,覆盖100%BMCR、75%THA,50%THA以及35%BMCR四种负荷。建立了自定义SO_(x)生成模型以确定燃料硫的析出和转化路径,模型包含多表面反应子模型以描述焦炭与O_(2)/CO_(2)/H_(2)O等3种气体的异相反应,并确定焦炭气化反应消耗量占总消耗量的比例,进而对炉膛H_(2)S空间分布进行了模拟计算。研究表明,近壁面高体积分数H_(2)S区域主要位于投运燃烧器层中最下层燃烧器以下以及最上层燃烧器以上至SOFA层之间,烟气切圆沿炉膛高度增加逐渐增大是造成后一区域H_(2)S体积分数较高的重要原因。35%BMCR负荷下水冷壁重点区域的H_(2)S平均体积分数为364μL/L,明显低于其他负荷。锅炉运行参数对重点区域H_(2)S体积分数影响程度的排序为:锅炉负荷>一次风率>主燃区空气过量系数>假想切圆直径>燃烧器竖直摆角。

基于AMPK/PFK-2对经皮穴位电刺激“内关”穴防护模拟失重大鼠心肌损伤的效应机制研究

目的:观察经皮穴位电刺激(TEAS)对模拟失重大鼠心功能、心肌病理组织形态、心肌能量代谢和糖酵解相关因子腺苷酸活化蛋白激酶α1(AMPKα1)、磷酸果糖激酶2(PFK-2)蛋白和mRNA表达的影响,探讨TEAS防治模拟失重诱发大鼠心肌损伤的效应和机制。方法:将36只SPF级Wistar大鼠随机分为空白组、模型组和经皮电组,每组各12只;采用尾部悬吊法制备模拟失重大鼠模型,持续30 d。于造模后第2天对经皮电组选用双侧“内关”穴进行干预,疏密波,频率2 Hz/100 Hz,强度1 mA,1次/2 d,每次30 min,共14次。每周记录大鼠体质量变化,4周后测量大鼠心脏、右肢比目鱼肌质量和胫骨长度;采用小动物超声心动图检测大鼠心脏功能;HE染色观察心肌组织病理形态改变;比色法和化学发光法分别检测心肌组织ATP和AMP含量;Western blot和Real-Time PCR法检测心肌组织中AMPKα1、PFK-2蛋白和mRNA表达水平。结果:与空白组比较,模型组大鼠体质量、比目鱼肌湿重及与体质量的比值、左心室质量和心胫比均显著降低,差异具有统计学意义(P<0.01),心脏功能下降,心肌纤维排列稀疏、断裂和溶解,心肌组织ATP含量显著降低,差异具有统计学意义(P<0.01)和AMP含量升高(P>0.05),心肌组织中AMPKα1、PFK-2蛋白和mRNA表达显著降低,差异具有统计学意义(P<0.01)。与模型组比较,经皮电组体质量增加,左心室质量、心胫比显著升高,差异具有统计学意义(P<0.05),心脏功能上升,心肌纤维肌排列整齐,无明显坏死、溶解,心肌组织ATP含量显著升高和AMP显著降低,差异具有统计学意义(P<0.05),心肌组织中AMPKα1、PFK-2蛋白和mRNA表达水平显著升高,差异具有统计学意义(P<0.01或P<0.05)。结论:经皮穴位电刺激“内关”穴可改善模拟失重大鼠心脏功能和结构损伤,提高心脏能量代谢水平,其机制可能与上调心肌组织AMPKα1、PFK-2表达水平进而增强心肌糖酵解过程来防护模拟失重引起的心肌损伤有关。

无定形TiO_(2)的F、La共掺杂及光催化脱硫性能

将钛酸四丁酯直接水解制备了无定形TiO_(2)〔TiO_(2)(Am)〕,将钛酸四丁酯在硝酸镧溶液或氟化铵溶液或其混合溶液中水解,分别制备了La掺杂型、F掺杂型以及F、La共掺杂型光催化剂,分别记为La-TiO_(2)(Am)、F-TiO_(2)(Am)和F-La-TiO_(2)(Am)。采用XRD、FTIR、XPS、UV-Vis DRS、SEM、PL及VB-XPS对其进行了表征,比较了其对模拟柴油〔二苯并噻吩(DBT)的正十二烷溶液〕的催化脱硫性能。结果表明,F、La共掺杂提升了TiO_(2)(Am)的吸光度和光吸收边缘红移程度,F的电负性使F-La-TiO_(2)(Am)的禁带宽度变窄,La—O键的生成为F-La-TiO_(2)(Am)提供了更多的氧空位,促进了杂质能级的生成,有效抑制了电子-空穴的复合。在以H_(2)O_(2)为氧化剂、无水甲醇为萃取剂、V(无水甲醇)∶V(模拟油)=1.0∶1、F-La-TiO_(2)(Am)用量为模拟柴油质量的1.0%、n(双氧水中O原子)∶n(DBT中S原子)=15∶1、反应时间3.0 h的条件下,模拟柴油脱硫率为94.10%。F-La-TiO_(2)(Am)使用4次后,脱硫率仍可达85.40%。在脱硫过程中,超氧自由基和空穴为主要活性物种,可将DBT转化成极性更强的亚砜和砜类物质,经由无水甲醇溶解后实现脱除。

原油-CO_(2)相互作用机理分子动力学模拟研究

CO_(2)的众多驱油机理已经被广泛认同,但受油藏因素影响,不同油藏条件下CO_(2)驱的效果差异较大。因此,需要进一步深化研究CO_(2)与原油的微观相互作用机理,明确不同油藏条件下CO_(2)的驱油方式,最大限度挖潜CO_(2)驱的潜力。利用分子动力学模拟方法研究了组分、温度、压力对油滴-CO_(2)相互作用的影响。求取动力学参数,量化表征油滴-CO_(2)间的相互作用,厘清了不同条件下二者的微观相互作用规律。模拟结果显示,色散力是主导CO_(2)-烷烃分子相互作用的主要作用能,二者相互作用主要包含两方面:一是CO_(2)分子克服烷烃分子间的位阻作用向油滴内部溶解扩散,二是CO_(2)分子对油滴外层分子的萃取吸引作用。随着烷烃分子链长减小、温度降低和压力增加,油滴溶解度参数和CO_(2)配位数增加,油滴外层分子的弯曲度减小,二者的相互作用增强。研究结果认为,在温度较低、压力较高的轻质和中轻质油藏中,应尽可能地实现CO_(2)混相驱和近混相驱,在温度较高、压力较低的中质和重质油藏中,应充分发挥CO_(2)非混相驱的溶解降黏、膨胀原油体积和补充能量的优势。研究结果能够为室内研究和现场实施CO_(2)驱油提供理论指导。

川芎嗪抑制ROCK的表达降低模拟失重大鼠血管Ca^(2+)敏感性

研究失重条件下血管平滑肌收缩性、Ca^(2+)敏感性及其调控通路RhoA-ROCK蛋白表达的变化,以及川芎嗪干预对其的影响。大鼠尾部悬吊模拟失重,在机体前、后部分别选取颈总动脉和肠系膜上动脉。在模拟失重大鼠颈总动脉中,由苯肾上腺素(PHE)或KCl诱发的血管收缩性和Ca^(2+)敏感性增强,RhoA激酶2(ROCK II)的表达、肌球蛋白磷酸酶靶亚基1(MYPT1)和肌球蛋白调节轻链(MLC)的磷酸化水平均上升,血管孵育Y-27632(ROCK特异性抑制剂)后可降低以上变化。模拟失重大鼠灌饲川芎嗪亦可降低以上变化。模拟失重后,大鼠肠系膜上动脉的收缩性和Ca^(2+)敏感性、ROCK II的表达、MYPT1和MLC的磷酸化水平降低,血管孵育Y-27632对以上变化无明显作用。模拟失重大鼠灌饲川芎嗪亦对以上变化无明显作用。结果表明,由RhoA-ROCK调控的血管平滑肌Ca^(2+)敏感性的变化可能是失重条件下机体前后部血管收缩性发生区域性重塑的关键因素。川芎嗪可抑制ROCK蛋白的表达,降低血管平滑肌升高的Ca^(2+)敏感性,从而纠正失重条件下机体前部血管收缩性的增强,但对失重条件下机体后部血管收缩性的减弱无恢复作用。

CO_(2)-EOR过程中油藏储层构造封存能力的模拟

为应对日益严峻的能源危机和温室效应,CO_(2)提高采收率技术脱颖而出,因此CO_(2)提高采收率后的地质封存安全性和相应的封存能力评估引起了广泛关注。借助数值模拟方法,基于吉林油田某区块油藏的实际储层条件,构建了注入CO_(2)含量为10%~90%的9个模型,分别探究了含水饱和度为30%,50%和90%以及储层压力为10 MPa,20 MPa和30 MPa时油藏各相组分的分布规律;基于前人对封存CO_(2)安全储存状态划分的研究,最终明确了CO_(2)的安全封存量。结果表明:1)当含水饱和度(30%)和压力(10 MPa)一定时,增加CO_(2)含量(10%~90%)可大幅提高CO_(2)的有效封存体积分数(26%~93%);2)压力的提升(10~30 MPa)促进了CO_(2)在油相中的溶解,从而略微降低了储层的封存能力(18%~7%);3)含水饱和度对储层封存CO_(2)的能力的影响微乎其微。该研究旨在阐明不同条件下CO_(2)的构造埋存量,为相关研究提供借鉴。

高速S-CO_(2)向心透平几何参数优化及变工况特性分析

透平是热力循环中实现热功转换的核心设备,优化透平几何参数以改善气动性能,是提升系统热效率的关键。该文以面向某船舶主机烟气余热利用的超临界二氧化碳布雷顿循环透平设计参数为基础,给出向心透平主要几何参数,采用耦合CO_(2)真实物性参数的CFX仿真方法,分析几何参数动、静叶包角以及叶轮出口几何角对透平性能的影响规律并进行参数优化,进一步研究非设计工况下的透平运行特性。结果表明:增大静叶包角会使动叶前缘出现扰动涡流并减少余速损失,增大叶轮出口几何角,动叶包角对透平效率的影响规律不变,但效率峰值点会沿动叶包角减小的方向移动;动、静叶包角和叶轮出口几何角分别为49°、21.5°、25°时透平设计点总-静等熵效率高达87.99%,相比优化前,提高0.54个百分点;透平偏离设计点±20%工况下等熵效率大于80%。结果可为超临界二氧化碳高速向心透平设计提供一定参考。

非均匀电场条件下CO_(2)等离子体流注的模拟研究

CO_(2)等离子体中存在大量电子碰撞反应和化学反应,对CO_(2)流注放电进行深入仿真相当困难。建立针-平板电极非均匀电场模型,采用等离子体流体模型和自适应网格细化方法,对CO_(2)等离子体流注进行数值模拟研究。研究了外加电压、放电气压等参数对CO_(2)流注中的空间场强变化、流注中荷电粒子分布、流注速度等参数的影响。文章有助于深入理解CO_(2)等离子体利用技术中流注的形成过程。

非均质多孔介质超临界CO_(2)非混相驱替特征及机理研究

为深入理解超临界CO_(2)在非均质储层中的非混相驱替过程,探索其流动特性及对多孔介质流体动力学的影响,为CO_(2)增强油气采收率和地质碳储存技术提供科学依据,采用基于Navier-Stokes方程与Cahn-Hilliard方程耦合的微观两相流模型,结合Voronoi多边形构造技术建立了具有真实孔隙结构特征的非均质多孔介质模型。通过模拟计算,详细描述了不同条件下CO_(2)驱替过程中的流体动力学行为和界面特征,研究了流体界面形态的演变和驱替效率的影响因素。结果表明:超临界CO_(2)注入后,不同模型内均出现了指进特征和复杂的非混相界面;孔道结构特征决定了毛细力大小,影响CO_(2)驱替前缘的稳定性,大孔道易形成指进现象,而狭窄孔道受毛细阻力与黏滞力影响,促使CO_(2)渗流路径转向或分叉,并导致孔隙压力不均匀分布;孔道内的黏滞力阻碍CO_(2)推进,适度调节CO_(2)的黏度和密度有助于提高驱替效率;高毛管数条件下,驱替压力导致流体相界面变得不稳定,CO_(2)优势渗流通道数量增多,指进渗流通道宽度拓宽,在黏滞力作用下出现了非连续的卡断现象;长时间的驱替过程显著提高CO_(2)饱和度,但伴随高能耗损失,驱替效率在CO_(2)突破后期逐渐下降。因此,调控超临界CO_(2)的物理性质、优化控制注入速率,能有效改善CO_(2)在地层中的分布和驱替路径,是提高CO_(2)驱替效率和优化地层开发的重要手段。

纳米TiO_(2)对NH_(3)-H_(2)O-LiBr工质降膜吸收性能的影响

为了探讨纳米TiO_(2)对三元NH_(3)-H_(2)O-LiBr工质降膜吸收的影响,本文利用数值分析建立了三元工作流体薄膜吸收的连续方程、能量方程和组分质量平衡方程,采用Matlab软件进行编程和计算纳米流体的降膜吸收性能,将其与实验数据进行对比验证,并进一步分析了纳米TiO_(2)质量分数、初始氨浓度、初始温度、冷却水进口温度、吸收压力和下降薄膜管长度对薄膜吸收性能的影响。研究表明:添加纳米TiO_(2)可以增强降膜吸收的传质速率,主要原因为液膜中氨的扩散系数增加。当纳米TiO_(2)质量分数从0%增加到0.1%、0.3%和0.5%时,扩散系数分别增加了3.44倍、6.42倍和11.76倍。此外,增加初始氨浓度、降低初始温度、提高冷却水进口温度或降低吸收压力都可以提高最终溶液的饱和度。

基于PHREEQC模拟分析Na_(2)S_(2)O_(4)对退役铀矿山采区地下水生态的修复

酸法原位地浸采铀作为回收铀资源首选工艺,不可避免会存在部分铀进入地下水污染生态环境,而采用还原剂Na_(2)S_(2)O_(4)将游离的铀还原固定可高效解决此类问题。为此,针对某酸法地浸采铀退役铀矿山地下水铀污染,采用PHREEQC模拟分析Na_(2)S_(2)O_(4)还原固定地下水中可溶性铀的机制,讨论NaHCO_(3)在Na_(2)S_(2)O_(4)还原固定可溶性铀的影响。模拟结果表明:1)该区域地下水中铀以U(Ⅵ)为主,其中UO_(2)SO_(4)、UO_(2)^(2+)和UO_(2)(SO_(4))_(2)^(2-)为优势物种,分别占63.60%、32.35%和3.89%;2)Na_(2)S_(2)O_(4)还原固定可溶性铀时,会降低地下水Eh值和Fe(Ⅲ)浓度,增强地下水还原性,促进沥青铀矿和黄铁矿沉淀,但会造成地下水酸化和高SO_(3)^(2-)浓度;3)NaHCO_(3)+Na_(2)S_(2)O_(4)在还原固定可溶性铀时,减轻了地下水酸化,增强了对U(Ⅵ)和SO_(3)^(2-)的去除,对Na_(2)S_(2)O_(4)还原固定可溶性铀的影响较小,在Na_(2)S_(2)O_(4)和NaHCO_(3)浓度比为1∶1至1∶1.5时修复效果最佳。

页岩油注CO_(2)重有机质沉积机理的分子模拟

页岩油注CO_(2)过程中的重有机质沉积风险不容忽视,明确页岩油注CO_(2)过程中重有机质沉积的微观作用机理是准确预测重有机质沉积风险的关键。采用平衡分子动力学(EMD)和巨正则蒙特卡洛(GCMC)模拟方法,基于页岩基质纳米孔隙结构特征,通过建立代表性的有机质孔隙模型,探究了页岩油烃类组分在页岩基质纳米孔隙中的分布规律、影响因素及CO_(2)注入对烃类组分分布规律的影响。模拟结果表明,有机质孔隙中的重质组分主要以吸附态的形式存在,轻质组分主要以游离态的形式分布在孔隙中央区域;CO_(2)注入会抽提页岩油中的轻质组分,破坏胶质—沥青质分子的稳定结构,重有机质分子在芳核结构间的π-π堆积作用下发生缔合、沉积,并最终吸附在页岩基质纳米孔隙壁面。此外,CO_(2)注入会能置换出部分吸附态的甲烷和乙烷,干酪根基质内的微孔空间是主要的CO_(2)地质封存空间。研究结果揭示了页岩油注CO_(2)过程中的重有机质沉积的微观作用机理。

Ti_(2)AlNb合金粉末热等静压成形的组织和性能

分别采用等离子旋转电极雾化法(Plasma rotating electrode process,PREP)和无坩埚感应熔炼超声气体雾化法(Electrode induction melting gas atomization,EIGA)制备了Ti_(2)AlNb洁净预合金粉末,并对预合金粉末进行了表征。通过热等静压(Hot isostatic pressing,HIP)工艺制备了Ti_(2)AlNb合金,研究了制粉工艺对Ti_(2)AlNb合金显微组织与力学性能的影响。试验结果表明,与PREP法相比,EIGA法制备的Ti_(2)AlNb粉末振实密度更高;基于粉末热等静压近净成形技术,在1030℃/140 MPa/3 h的条件下开展了Ti_(2)AlNb叶轮的成形研究,有限元模拟结果显示,粉末振实密度越高,部件热等静压后变形程度越小,综合考虑构件成形,优选振实密度更高的EIGA制粉工艺制备Ti_(2)AlNb粉末合金复杂部件。