石油组分及其模型化合物的超分子化学作用

原油是最复杂的化学体系之一,人们对原油这种复杂的胶态分散体及其稳定性的研究兴趣与日俱增,尤其是与石油稳定性密切相关的沥青质超分子聚集体。但人们对形成沥青质超分子聚集体的主要作用力长期以来颇有争议。本文重点介绍了石油组分及其模型化合物在溶液中形成超分子聚集体的超分子化学作用研究进展。通过实验方法和理论计算证明沥青质聚集体是沥青质分子间通过氢键、π-π堆积、偶极-偶极相互作用等多种分子间弱相互作用力协同作用形成的热力学稳定结构;合成具有沥青质结构特点的纯化合物,研究它们在溶液中的行为,是提高对沥青质在液态相中自缔合行为认识的有效方法;结合现阶段的研究状况,对石油组分模型化合物的超分子化学作用研究的发展前景进行了展望。     

疏水改性聚丙烯酰胺对原油组分界面扩张流变性质的影响

利用悬挂滴方法研究了疏水改性聚丙烯酰胺(HMPAM)对胜利采油厂高温高盐油藏采出原油中酸性活性组分和沥青质界面膜扩张流变性质的影响,考察了不同活性组分浓度条件下的界面扩张流变行为.实验结果表明:1750mg·L-1HMPAM能够在界面上形成网络结构,界面扩张模量数值高达100mN·m-1左右;油相中的酸性组分随着老化时间增加吸附到界面上,与HMPAM分子的疏水改性部分形成聚集结构,一方面通过快速的扩散交换过程大大降低扩张模量,另一方面通过与疏水改性部分的相互作用加强HMPAM分子间的缔合强度,增强网络结构的弹性.沥青质分子尺寸相对较大,分子间存在氢键等较强的相互作用,造成沥青质界面聚集体和HMPAM形成的网络结构共同决定界面膜性质,混合膜的扩张模量较单独HMPAM体系仅略有降低.     

界面电场对血红蛋白在多孔金电极上的吸附和生物活性的影响(英文)

蛋白质的界面吸附及其生物活性因它在构建生物传感、生物电子器件和生物燃料电池等方面具有重要的作用而倍受关注.对此,界面电场是吸附的一个重要影响因素,它能明显地影响蛋白质分子在材料界面的吸附量、分子构象以及分子定向.本文应用电化学方法和红外光谱技术研究了血红蛋白在三维多孔金膜电极上的吸附动力学及其生物活性随界面电场的变化关系.结果表明,由界面电场产生的过量表面电荷可借助与蛋白质分子之间的静电作用加速蛋白质分子在电极表面的吸附,提高其吸附量;但是,过高的界面电场将破坏吸附蛋白质的构象以及降低它还原过氧化氢的催化活性;只有在零电荷电位下,吸附在电极表面的血红蛋白才能保持其天然的构象和生物催化活性.本研究将为生物传感器、生物电子器件和生物燃料电池的构建提供理论依据,加深对荷电生物界面上生物分子界面行为的认识.     

沥青质及其亚组分与烷基苯磺酸盐溶液在降低界面张力中的协同作用

利用混合溶剂沉淀法将原油中的沥青质分为4个亚组分, 研究了含有各组分的模拟油与烷基苯磺酸钠(p-S14-4, p为对二甲苯; 14表示烷基链上有14个碳原子; S表示表面活性剂; 4表示芳基在长链烷基的4号碳原子上)水溶液间的动态界面张力(DIFTs). 结果表明, 沥青质及其亚组分的分子尺寸、 浓度和极性对DIFTs有显著影响. 分子尺寸较大的沥青质亚组分与p-S14-4分子之间难以形成混合吸附膜, 协同作用较弱, DIFTs曲线呈“L”形, 最小界面张力(IFT_min)受浓度和极性的影响较小. 在高浓度时, 分子尺寸较小的沥青质及其亚组分快速扩散至界面与p-S14-4分子形成紧密的混合吸附膜, 能够快速降低界面张力(IFT); 随着时间的延长, 界面层的分子发生重排, 导致DIFTs曲线呈“V”形, 且在这种情况下沥青质及其亚组分的极性越高, 降低IFT的协同作用越明显, IFT_min越低.     

羟基取代的烷基苯磺酸盐在水/气和水/癸烷界面的结构特点（摘要）

驱油表面活性剂的分子设计是一项重要的研究课题.设计新型高效的驱油表面活性剂关键的问题在于如何洞察表面活性剂的结构和功能的关系.长线性烷基苯磺酸盐是一类非常流行的表面活性剂,广泛应用于工业和日常生活中.关于烷基苯磺酸盐的结构和功能研究已有大量的实验和理论工作报道.近来,结合分子设计的思想,实验上合成了新型的羟基取代的烷基苯磺酸盐表面活性剂,并研究了这类新型表面活性剂动态的界面行为.我们从理论上利用分子动力学模拟的方法研究了羟基取代的烷基苯磺酸盐单分子层在水/气和水/癸烷界面的结构特点.从液体密度剖面图、氢键、表面活性剂聚集结构和有序参数等方面,详细报道了2-羟基-3-癸基-5-辛基苯磺酸钠这种新型阴离子表面活性剂的界面特征.模拟结果表明随着表面活性剂分子数目的增加,每个表面活性剂在单分子层上形成分子内氢键的平均数目将下降,但形成分子内氢键的结构仍处于主导地位;烷基尾链的疏水部分,尤其是苯环3号位上取代的癸基随着表面活性剂覆盖度增大,向界面外延伸并且更加有序;二维径向分布函数描绘了表面活性剂聚集结构的特点并暗示了癸烷相将影响表面活性剂疏水部分的取向;表面活性剂分子容易形成长程氢键结构.我们的模拟结果是对实验研究的一个重要补充.此外,模拟中我们利用gromacs和ffamber程序,使用了全原子模型,这将为模拟烷基苯磺酸盐表面活性剂的界面行为提供新的方案.     

超声波处理对加氢反应前后沥青质单元分子结构的影响

以胜利减渣和沙轻减渣为原料,研究了超声波处理对加氢反应前后沥青质单元分子结构的影响,并结合¹H-NMR数据、沥青质单元分子参数变化和红外光谱分析等结果,用Chem Bio Draw Ultra 2012模拟出不同条件下两种沥青质单元分子的结构。结果表明,超声波处理减少了沥青质的缔合数,使沥青质单元分子发生开环反应和脱烷基侧链反应加剧,改变了沥青质单元分子的结构,对加氢后沥青质单元分子的结构和组成产生重要影响。沥青质单元分子模型可形象体现超声波处理对加氢反应前后沥青质单元分子化学结构的影响,有助于在分子水平上解释超声波处理影响沥青质单元分子的原因。     

气驱油油气混相过程的界面传质特性及其分子机制

油气混相过程的界面传质特性对气驱提高原油采收率技术非常重要。本文针对吉林某油田的实际油组分,采用分子动力学模拟研究了气驱油过程,分析了不同气体和驱替压力下油气两相的状态变化以及界面特性,获得不同驱替气体的最小混相压力(MMP)。结果表明,随着驱替气体压力的升高,气相的密度逐渐增大,油相膨胀密度降低,气相与油相的混合程度增强,油气两相界面厚度增加,界面张力随之减小。同时发现,驱替相中二氧化碳浓度越高,在同等气体压力下,油气界面更厚,油气混合程度更高。纯CO₂驱油得到的MMP远远小于纯N₂驱油,当这两种气体摩尔比为1 : 1混合时MMP介于两种纯气体之间,说明要达到同样的驱油效果二氧化碳需要的压力更小。最后,本文从分子微观作用力角度解释了驱替气体不同时影响油气混相程度的机制,通过分子平均作用势曲线发现油相分子对CO₂的吸引力要大于N₂分子,因此CO₂分子更容易与油相混合,驱替效果更明显。     

吡虫啉与人血清白蛋白相互作用热力学行为

在模拟人体生理条件下,综合利用荧光光谱、紫外吸收光谱、圆二色谱和分子模拟等方法,研究了吡虫啉(IMI)和人血清白蛋白(HSA)相互作用的热力学行为。荧光光谱和紫外吸收光谱的分析表明：吡虫啉能有效猝灭HSA的内源荧光,猝灭机制为静态猝灭;通过所获取的相互作用热力学参数,可知两者之间的相互作用是一个吉布斯自由能降低的自发过程,且二者之间的主要作用力为氢键和范德华力。位点竞争实验和分子模拟的结果表明：吡虫啉在HSA的主要结合位置为位点?。圆二色谱、同步荧光光谱和三维荧光的分析发现：吡虫啉引起HSA的构象发生改变,其α-螺旋含量降低,无规卷曲含量升高,肽链结构在吡虫啉的作用下有所伸展。     

表面电荷及外电场对液固界面热阻的影响

采用非平衡分子动力学方法模拟了外电场及固体表面电荷对水与固体间界面热阻的影响. 结果表明,外加电场平行于界面时, 其对界面热阻几乎没有影响, 而垂直于界面时, 界面热阻将随着电场强度的增大而减小. 壁面带正电荷或负电荷都将使得界面热阻减小. 界面热阻与表面电荷密度及电场强度均满足二次函数关系. 模拟结果表明施加外电场和表面电荷是控制液固界面热阻的有效方法.     

光谱法结合分子模拟分析乳铁蛋白与药物恩诺沙星的互作分子机理

利用光谱实验结合计算机模拟技术研究了药物恩诺沙星(Enrofloxacin,EFLX)与牛乳铁蛋白(Bovine lactoferrin,BLF)的相互作用机理。测定反应体系的结合参数、能量转移参数及热力学函数,考察EFLX对BLF分子构象的影响,并模拟EFLX-BLF结合反应的分子模型。结果表明,药物分子与牛乳铁蛋白的相互作用表现为动态结合过程,结合强度适中,EFLX与BLF分子的结合距离r值较小,说明发生了能量转移现象。EFLX影响BLF的结构域微区构象,降低结合位域的疏水性。荧光相图技术解析出EFLX与BLF反应构象型态的变迁为"二态模型"。EFLX-BLF的热力学参数表明两者间是以氢键和范德华力为主的分子间作用。分子建模结果显示,EFLX与BLF的相互作用主要为氢键和范德华力,兼有疏水作用力。计算机分子模拟与实验测试获得了一致性结果。     

Molecular Dynamics Simulation for the Demulsification of O/W Emulsion under Pulsed Electric Field

A bidirectional pulsed electric field (BPEF) method is considered a simple and novel technique to demulsify O/W emulsions. In this paper, molecular dynamics simulation was used to investigate the transformation and aggregation behavior of oil droplets in O/W emulsion under BPEF. Then, the effect of surfactant (sodium dodecyl sulfate, SDS) on the demulsification of O/W emulsion was investigated. The simulation results showed that the oil droplets transformed and moved along the direction of the electric field. SDS molecules can shorten the aggregation time of oil droplets in O/W emulsion. The electrostatic potential distribution on the surface of the oil droplet, the elongation length of the oil droplets, and the mean square displacement (MSD) of SDS and asphaltene molecules under an electric field were calculated to explain the aggregation of oil droplets under the simulated pulsed electric field. The simulation also showed that the two oil droplets with opposite charges have no obvious effect on the aggregation of the oil droplets. However, van der Waals interactions between oil droplets was the main factor in the aggregation.     

Progress in Molecular Dynamics and Hansen Solubility Parameters of Low Molecular Weight Gels北大核心CSCD

Recently,the use of computational methods such as Molecular Dynamics（MD）simulations and Hansen Solubility Parameters （HSPs）to study the behavior of small molecule gelators has attracted much attention. MD simulation is a computational method based on classical mechanics and is one of the preferred techniques for understanding the process of small molecule gelators. The MD simulation can more accurately analyze the gelation trend or assembly behavior of small molecule gelators,dynamically and graphically display the self-assembly process,effectively reveal the relationship between the structure of small molecule gelators and related gelation behavior,and quantitatively analyze non-covalent bond interactions such as hydrogen bonds,π-π stacking,van der Waals interactions,ionic bonding and solvophobic interactions. By performing molecular dynamics simulations on known gelators/non-gelators,parameters related to gelation behavior in the simulated data are extracted,and the linear correlation is measured by fitting the Pearson correlation coefficient to finally predict the gelation behavior of a certain class of small molecules. On the other hand,the empirical model developed according to the HSPs is the most representative,which consists of the energy of dispersion interaction（δd）,the energy of polar interaction（δp）and H-bonding energy（δh ）between molecules. These three parts determine the coordinate point of the three-dimensional space（Hansen space）. According to the range of the point,it can be determined whether the organic small molecule can form a gel in a specific solvent. In this paper,representative works published recently in the field of organic small molecule gels by using MD simulations and empirical models are reviewed. Some comments on the assembly behavior of gelators,the regulation and prediction of non-covalent bond interactions on gelation ability are made. © 2022, Science Press (China). All rights reserved.     

基于激光介导富集的表面增强拉曼分析

基于具有优异表面增强拉曼散射(SERS)性能的石墨烯隔离的金纳米晶(GIAN)能够在水-有机相界面自组装, 待测物分子在有机相中的分配系数较大以及GIAN能够通过π?π相互作用与待测物分子结合的优势, 构建了激光介导的待测物分子的高效富集策略, 进而实现了9,10-双苯乙炔基蒽(BPEA)分子的痕量SERS分析. 所构建的新型待测物分子高效富集策略在一定程度上避免了因“咖啡环效应”带来的信号波动, 有望为复杂体系中痕量待测物的SERS分析提供可靠的平台.     

Localized electric field induced transition and miniaturization of two‐phase flow patterns inside microchannels

Strategic application of external electrostatic field on a pressure‐driven two‐phase flow inside a microchannel can transform the stratified or slug flow patterns into droplets. The localized electrohydrodynamic stress at the interface of the immiscible liquids can engender a liquid‐dielectrophoretic deformation, which disrupts the balance of the viscous, capillary, and inertial forces of a pressure‐driven flow to engender such flow morphologies. Interestingly, the size, shape, and frequency of the droplets can be tuned by varying the field intensity, location of the electric field, surface properties of the channel or fluids, viscosity ratio of the fluids, and the flow ratio of the phases. Higher field intensity with lower interfacial tension is found to facilitate the oil droplet formation with a higher throughput inside the hydrophilic microchannels. The method is successful in breaking down the regular pressure‐driven flow patterns even when the fluid inlets are exchanged in the microchannel. The simulations identify the conditions to develop interesting flow morphologies, such as (i) an array of miniaturized spherical or hemispherical or elongated oil drops in continuous water phase, (ii) “oil‐in‐water” microemulsion with varying size and shape of oil droplets. The results reported can be of significance in improving the efficiency of multiphase microreactors where the flow patterns composed of droplets are preferred because of the availability of higher interfacial area for reactions or heat and mass exchange.     

理论研究晶体场效应和电荷转移效应对Co2+的2p电子X射线L2,3吸收边光谱的影响

运用多重态计算方法研究了在正八面体对称性的晶体场中Co²⁺离子的2p电子X射线L_2,3吸收边光谱, 研究了Co²⁺离子和周围的配位离子之间的正八面体(O_h)晶体场效应和相应的电荷转移效应对于吸收光谱的影响. 系统讨论了在多重态计算中起作用的所有物理参数对CoO和CoCl₂的X射线吸收光谱特性的特定影响及其物理机制. 将计算得出的光谱数据和同样具有O_h对称性结构Co²⁺离子的CoO和CoCl₂实验光谱数据进行了对比, 在实验光谱数据中发现的特征被确定为来自不同自旋态, 并且光谱强度的变化与晶体场的强度相关, 揭示了其中包含的电荷转移效应. 本文为低对称性复杂系统的多重态计算提供了一个基础的参考标准, 可以适用于含有钴元素或其它过渡金属的复杂体系的X射线吸收光谱的理论计算.     

Functionalized carbon black nanoparticles used for separation of emulsified oil from oily wastewater

Functionalized carbon black (F-CB) nanoparticles were synthesized by covalently grafting the polyvinyl alcohol on carbon black (CB) surfaces and used as demulsifier to separate the oil from the emulsified oily wastewater. The bottle test showed that the residual oil content in the separated water was as low as ～50?mg/L corresponding to a demulsification efficiency of about 99.90% at an optimal condition within a few minutes. It was believed that the surface wettability of the carbon black could be tuned by modifying with the PVA molecules, which enables the F-CB nanoparticles to be readily migrated to the oil/water interface and have the opportunity to interact with and/or displace the stabilizers of the emulsion. As a result, the demulsification process was accomplished with the coalescence of the oil droplets promoted by the F-CB nanoparticles. The interaction behavior between F-CB nanoparticles and asphaltenes was investigated by quantum chemical calculations. The results showed that the F-CB nanoparticles have strong interaction with the asphaltene molecules in form of π?π and θ?π forces. The findings in present study are significant for understanding the demulsification mechanism and also provide a novel demulsifier for the demulsification of emulsified oily wastewater.     

热改质过程中渣油结构及其重组分溶剂化变化规律研究

以委内瑞拉减压渣油为原料,采用微型反应釜,研究了其在410℃、2.0 MPa氮气初压下,不同反应停留时间的热改质过程生成油的化学结构组成及其重组分溶剂化变化规律。通过1H-NM R技术研究了热改质过程生成油中沥青质和重胶质不同化学位移归属氢的转化路径;并结合改进的Brown-Ladner法分析了热改质过程生成油中沥青质和重胶质的平均分子结构参数变化;采用蒸汽压渗透法考察了热改质过程生成油中沥青质和重胶质在甲苯溶液中所形成的复合超分子结构的平均相对分子质量。结果表明,随着热改质程度的加深,沥青质和重胶质的H/C原子比减小,供氢能力逐渐下降,沥青质和重胶质的芳香环共轭程度和fA在体系生焦后(45 min)显著提高;沥青质的聚集趋势相关值在热改质15 min前变化不大,15 min后显著增强,而重胶质在整个热改质过程中,其聚集趋势相关值的增势较为缓和;沥青质和重胶质的聚集趋势相关值差异逐渐增大,15 min时增加了1.5%、25 min时增加了50.8%、45 min时增加了142.3%,表明沥青质和重胶质的结构差异越来越明显;重胶质溶剂化沥青质的能力逐步减弱,体系的溶剂化参数从0时的32.9%逐步降到15 min时的29.5%、25 min时的14.1%和45 min时的9.6%;热改质生成油的斑点实验等级逐渐增加,体系的胶体稳定性逐渐降低。     

Numerical simulation of droplet coalescence behavior in gas phase under the coupling of electric field and flow field

The coalescence behavior of droplets in an electric field belongs to the important research contents of electrohydrodynamics. Based on the phase field method of the Cahn–Hilliard equation, the electric field and the flow field are coupled to establish the numerical model of twin droplet coalescence in a coupled field. The effects of flow rate, electric field strength, droplet diameter, and interfacial tension on the coalescence behavior of droplets during the coalescence process were investigated. The results show that the dynamic behavior of the droplets is divided into coalescence, after coalescence rupture, and no coalescence under the coupling of electric field and flow field. The proper increase of the electric field strength will accelerate the coalescence of the droplets, and the high electric field strength causes the droplets to burst after coalescence. Excessive flow rates make droplets less prone to coalescence. Under the coupling field, the larger the droplet interface tension, the smaller the droplet diameter, the smaller the flow rate, and the shorter the droplet coalescence time. The results provide a theoretical basis for the application of electrostatic coalescence in gas–liquid separation technology.     

利用基于Gouy-Chapman模型的离子有效电荷定量表征离子特异性效应

离子特异性效应在固-液界面反应中是普遍存在的.近期研究指出,在较低电解质浓度的某些体系中,离子特异性效应可能并非来源于色散力、经典诱导力、离子半径或水合半径的大小等,而是界面附近强电场中的离子极化作用.这种作用可使界面附近的吸附态反号离子被强烈极化(高达经典极化的104倍).强烈极化的结果将导致离子在界面附近受到的库仑力远远超过离子电荷所能产生的库仑力,这体现在离子的有效电荷将远大于离子的实际电荷.因此胶体体系中基于这种强极化的离子有效电荷可以用来定量表征离子特异性效应的强度.本研究在蒙脱石-胡敏酸混合悬液凝聚过程中发现了Na+、K+、Ca2+、Cu2+四种离子的离子特异性效应,提出了基于激光散射技术测定离子有效电荷的方法,并成功获得了被强烈极化后的离子有效电荷数值.实验测得的Na+、K+、Ca2+、Cu2+四种离子的有效电荷值分别为:ZNa(effective)=1.46,ZK(effective)=1.86,ZCa(effective)=3.92,ZCu(effective)=6.48.该结果表明:(1)离子在强电场中的极化将大大提高离子的有效电荷,从而极大地增强离子所受的库仑作用力;(2)离子的电子层数越多,离子极化越强烈,离子的有效电荷增加越多.     

Boosting Photocatalytic Oxygen Evolution: Purposely Constructing Direct Z-Scheme Photoanode by Modulating the Interface Electric Field

Ti-Fe₂O₃ photoanode has received widespread attention in photoelectrochemical(PEC) water spilling because of its optimized oxidative and reductive capability of composites catalyst. However, its low efficiency could limit its development. Herein, in order to improve the efficiency of PEC water spilling, the all-solid-state direct Z-scheme Ti-ZnFe₂O₄/Ti-Fe₂O₃(TZFO/Ti-Fe₂O₃) nanorod arrays composited with the ideal energy band structure are synthesized by modulating the Fermi level of TZFO for PEC water splitting. The photophysical methods in this work, including the Kelvin probe measurement and transient photovoltage spectroscopy(TPV) measurement, are applied to explore the migration behavior of electric charges at the enhanced interface electric field. Finally, the Z-scheme charge transfer mechanism of TZFO/Ti-Fe₂O₃ photoanode is proved successfully. Benefiting from the desirable charge transfer at interface electric field, the TZFO/Ti-Fe₂O₃ exhibits the outstanding photocatalytic oxygen evolution reaction(OER) performance, and the photocurrent of 60TZFO/Ti-Fe₂O₃ photoanode reaches 2.16 mA/cm² at 1.23 V vs. reversible hydrogen electrode(RHE), which is three times higher than that of pure Ti-Fe₂O₃ photoanode. This work provides a facile approach of modulating interface electric field to optimize the Z-scheme charge-transfer process.