Miscibility of light oil and flue gas under thermal action

The miscibility of flue gas and different types of light oils is investigated through slender-tube miscible displacement experiment at high temperature and high pressure.Under the conditions of high temperature and high pressure,the miscible displacement of flue gas and light oil is possible.At the same temperature,there is a linear relationship between oil displacement efficiency and pressure.At the same pressure,the oil displacement efficiency increases gently and then rapidly to more than 90% to achieve miscible displacement with the increase of temperature.The rapid increase of oil displacement efficiency is closely related to the process that the light components of oil transit in phase state due to distillation with the rise of temperature.Moreover,at the same pressure,the lighter the oil,the lower the minimum miscibility temperature between flue gas and oil,which allows easier miscibility and ultimately better performance of thermal miscible flooding by air injection.The miscibility between flue gas and light oil at high temperature and high pressure is more typically characterized by phase transition at high temperature in supercritical state,and it is different from the contact extraction miscibility of CO_(2) under conventional high pressure conditions.

保存条件对陆相中高熟页岩油富集与流动性保持的作用

陆相页岩烃源岩层系内部滞留烃数量与品质的控制因素除生烃母质类型、丰度、热成熟度与页岩储层储集空间外,烃源岩保存条件作为关键影响因素,在现阶段关注较少;针对该科学问题,以实例解剖为出发点,探讨保存条件在页岩油可动烃富集中的作用。研究表明,良好的保存条件主要有3方面的关键作用:①确保足够多的轻烃(C_(1)—C_(13))、中组分烃(C_(14)—C_(25))和小分子芳香烃(含1~2个苯环)留在地层中以增加页岩油流动性和流动量;②确保地层具有较高的能量场(异常高压),以推动页岩油最大量流出;③确保滞留烃保持多组分烃(轻烃、中质烃、重烃和含杂原子化合物)混相流动条件,使重烃(∑C_(25+))和重质组分(非烃和沥青质)有最佳流动度和最大流动量。经实例解剖证实,凡经济可采性较好的陆相页岩油除有机质类型、丰度与热成熟度及储集空间等有利条件外,页岩层系保存条件好,是页岩油经济成藏的关键因素,应纳入页岩油富集区/段评价标准,成为有利勘探靶体选择的必要条件。

Dual‑Donor‑Induced Crystallinity Modulation Enables 19.23% Efficiency Organic Solar Cells

Trap-assisted charge recombination is one of the primary limitationsof restricting the performance of organic solar cells. However, effectivelyreducing the presence of traps in the photoactive layer remains challenging.Herein, wide bandgap polymer donor PTzBI-dF is demonstrated as an effectivemodulator for enhancing the crystallinity of the bulk heterojunction active layerscomposed of D18 derivatives blended with Y6, leading to dense and orderedmolecular packings, and thus, improves photoluminescence quenching properties.As a result, the photovoltaic devices exhibit reduced trap-assisted charge recombinationlosses, achieving an optimized power conversion efficiency of over 19%.Besides the efficiency enhancement, the devices comprised of PTzBI-dF as athird component simultaneously attain decreased current leakage, improved chargecarrier mobilities, and suppressed bimolecular charge recombination, leading toreduced energy losses. The advanced crystalline structures induced by PTzBI-dFand its characteristics, such as well-aligned energy level, and complementaryabsorption spectra, are ascribed to the promising performance improvements.Our findings suggest that donor phase engineering is a feasible approach to tuning the molecular packings in the active layer, providingguidelines for designing effective morphology modulators for high-performance organic solar cells.

特低渗透砂岩油藏CO_(2)驱原油动用特征及埋存机理

以江苏油田特低渗透油藏L区块为例,基于CO_(2)-原油体系长细管驱替实验、注入能力测试和高温高压在线核磁共振驱替等实验,揭示特低渗透油藏CO_(2)驱油气传质规律和原油动用机理,明确CO_(2)驱替过程中CO_(2)埋存孔隙范围和混相程度对原油动用特征及CO_(2)埋存特征的影响规律。结果表明:CO_(2)驱油过程划分为CO_(2)顶替阶段、CO_(2)突破阶段和CO_(2)抽提阶段,原油膨胀和黏度降低是CO_(2)驱顶替阶段提高采收率的主要机制,CO_(2)突破后通过抽提、萃取原油中轻质组分进一步提高采收率;CO_(2)驱过程中,大孔内原油对提高采收率的贡献率达46%以上,中孔内原油为增油的接替储备,CO_(2)突破后小部分抽提的原油被CO_(2)裹挟进入纳米级孔隙成为较难动用的剩余油;随着混相程度的提高,CO_(2)前缘推进更稳定,波及范围更广,CO_(2)埋存范围和埋存量更大。CO_(2)完全埋存阶段对整体埋存量贡献最大,CO_(2)逸散阶段埋存机理为部分原油在初始赋存孔隙范围的原位埋存和CO_(2)裹挟原油进入更小孔隙从而增大埋存量,CO_(2)泄漏阶段随着原油产出CO_(2)大量泄漏,埋存率急剧降低。

Formation and evolution of supercritical geofluid

In this work,we provide a comprehensive review on the formation,evolution,properties,and effects of supercritical geofluid.In Earth's interior,enhanced miscibility between H_(2)O and silicate by the addition of special components or by the increase of pressure and temperature gives rise to supercritical geofluid with a significant amount of both H_(2)O and silicate solute.The formation of supercritical geofluid in magmatic-hydrothermal systems,typified by pegmatite system,is governed by meltfluid critical curve.The formation of supercritical geofluid in metamorphic systems,typified by subducted slab,is governed by the second critical end point.Experimental results suggest that the presence of boron and fluorine in pegmatite system makes it possible to form supercritical geofluid at crustal depths,but the release of supercritical geofluid from subducted slab is withheld until almost 100 km depth.A major presence of both H_(2)O and depolymerized structural units(monomers,dimers,etc.)endows supercritical geofluid with unique physical properties including low density,low elastic moduli,low viscosity,high diffusivity,and high electrical conductivity.Supercritical geofluid can effectively mobilize a variety of elements even including high field strength elements and heavy rare earth elements.The chemical signatures of supercritical geofluid can be inherited by metasomatized mantle and mantle-derived melts,and this could give an explanation of the oxidation of arc magmas.Phase separation of supercritical geofluid through the mechanism of spinodal decomposition leads to formation of a melt network.Multiphase fluid inclusions recovered from subduction zone rocks and pegmatites are possible relics of supercritical geofluid.Supercritical geofluid can cause electrical anomaly and low seismic velocity near the top of subducted slab,and can be linked with intermediate-focus earthquakes.Supercritical geofluid may have played a crucial role in the formation of pegmatites and associated ore deposits.

砾岩油藏CO_(2)混相驱提高采收率实验及应用评价

为了研究砾岩油藏水驱后CO_(2)混相驱提高采收率机理及现场应用效果,以新疆油田M井区克下组砾岩油藏为例,通过开展细管、核磁共振、岩心驱替实验,对CO_(2)-原油最小混相压力、孔隙尺度下CO_(2)混相驱微观特征、岩心尺度下CO_(2)混相驱影响因素开展研究,并对现场注气试验效果进行评价。结果表明:M井区克下组砾岩油藏CO_(2)驱最小混相压力为24.1 MPa;油藏水驱后的CO_(2)混相驱主要动用孔隙半径大于0.5μm的中孔、大孔内的剩余油,分别提高采收率8.52、26.03百分点;在混相条件下,CO_(2)注入速度为0.5 m L/min时提高采收率最高,可达35.89百分点,推荐矿场单井注气速度为18 t/d;采用段塞尺寸0.3 PV分4轮次水气交替注入,最终采收率最高为79.25%。现场试验评价显示:M井区克下组砾岩油藏注气适应性强,储层视吸气指数升高至1.0 t/(d·MPa),油井见效比例超过60%,其中45%的见效井初步实现混相驱;油井压裂引效措施增产效果明显,累计增油量为4 174 t,平均单井日增油量为3.5 t。研究成果可为M井区后续CO_(2)混相驱工业化开发提供有效指导。

热塑性纤维素与PVA混溶性的分子动力学模拟

首次提出了将氧化还原改性纤维素(Oxidation-reduction modified cellulose,ORC)与聚乙烯醇(Poly(vinyl alcohol),PVA)共混进行制备复合材料,并采用分子动力学模拟研究了ORC与PVA的混溶性.对分子链间相互作用能和氢键数量分析发现,随着改性程度增加,ORC与PVA会产生更强烈的相互作用,这促进了组分间的混溶.当ORC的改性程度达到40%后,ORC与PVA的溶解度参数差值为2.02(J/cm^(3))^(1/2),达到混溶条件.根据Flory-Huggins理论确定了醇解度为88%和99%的PVA与ORC的混溶性,结果表明PVA(88%)与ORC的混溶性更好.对共混体系中形成氢键原子的径向分布函数分析发现,醋酸乙烯酯重复单元上的羰基更倾向与ORC形成分子链间氢键,而乙烯醇重复单元上的羟基更倾向形成分子链内氢键,这促使PVA(88%)/ORC共混体系中形成更多的分子链间氢键,从而混溶性更好.研究结果可为ORC/PVA复合材料的制备提供理论指导.

混相性与重力作用对CO_(2)驱提高采收率及储存潜力的影响

为了搞清楚系统混相性与重力作用对CO_(2)驱油效率及储存潜力的影响,设计了一系列驱替实验,通过对比混相性与重力作用多种组合方式下的驱替结果,明确CO_(2)驱提高采收率的最佳驱替方式。为了充分体现重力的作用,选择长岩心开展水平注气(重力无作用)、顶部注气(重力为驱替动力)及底部注气(重力为驱替阻力)驱油实验。结果表明:对于采收率而言,非混相时顶部注气的效果最佳,水平注气次之,底部注气最差。当压力增大至驱替系统内流体可以混相时,重力作用对CO_(2)驱的采收率几乎没有影响。因而在进行CO_(2)非混相驱时,在储层厚度与倾角合适的情况下,应优先考虑采用重力主导的注气方式;对于混相驱,储层厚度与注气方向不再是影响CO_(2)驱替结果的关键因素。对于CO_(2)埋存量而言,非混相时,充分发挥重力作用的顶部注气可以获得最高的CO_(2)埋存量。随着压力的增大,重力作用对CO_(2)储存量的影响减弱。混相时,无论哪种注气方向,CO_(2)的储存潜力都非常高。研究成果为CO_(2)驱提高采收率技术优化与矿场实践提供了依据。

三塘湖油田NJH区块中黏油CO_(2)近混相驱实验及应用

三塘湖油田NJH区块属于中黏油砂岩油藏,地层原油黏度为20.8 mPa·s,处于中含水期,预测水驱采收率为22.70%,提高采收率空间小。为了探索提高采收率技术,检验中黏油CO_(2)近混相驱可行性,揭示CO_(2)近混相驱相间传质规律及增油机理,开展了CO_(2)驱油室内实验及矿场试验。结果表明:CO_(2)驱前缘主要发挥溶胀作用,后缘萃取抽提作用强于前缘,降黏作用及提高剩余油驱油效率是主要的增油机理,地面原油黏度降幅为55%,C_(2)—C_(15)含量升高18.3%,驱油效率提高4.6倍;渗透率级差是影响波及体积的主要因素,渗透率级差达到6,低渗透层采收率仅为13.84%。矿场试验阶段累计注气量为2.66×10^(4) t,累计产油量为0.78×10^(4) t,换油率达到0.29,证实中黏油CO_(2)近混相驱具备良好的推广应用前景。

Miscibility, Crystallization, and Rheological Behavior of Solution Casting Poly（3-hydroxybutyrate）/poly（ethylene succinate） Blends Probed by Differential Scanning Calorimetry, Rheology, and Optical Microscope Techniques

The miscibility and crystallization of solution casting biodegradable poly（3-hydroxybuty- rate）/poly（ethylene succinate） （PHB/PES） blends was investigated by differential scanning calorimetry, rheology, and optical microscopy. The blends showed two glass transition temperatures and a depression of melting temperature of PHB with compositions in phase diagram, which indicated that the blend was partially miscible. The morphology observation supported this result. It was found that the PHB and PES can crystallize simultaneously or upon stepwise depending on the crystallization temperatures and compositions. The spherulite growth rate of PHB increased with increasing of PES content. The influence of compositions on the spherulitic growth rate for the partially miscible polymer blends was discussed.

MISCIBILITY,CRYSTALLIZATION AND MECHANICAL PROPERTIES OF PPC/PBS BLENDS

In this paper, melt blends of poly（propylene carbonate） （PPC） with poly（butylene succinate） （PBS） were characterized by dynamic mechanical analysis （DMA）, differential scanning calorimetry （DSC）, tensile testing, wide-angle X-ray diffraction （WAXD）, polarized optical microscopy and thermogravimetric analysis （TGA）. The results indicated that the glass transition temperature of PPC in the 90/10 PPC/PBS blend was decreased by about 11 K comparing with that of pure PPC. The presence of 10% PBS was partially miscible with PPC. The 90/10 PPC/PBS blend had better impact and tensile strength than those of the other PPC/PBS blends. The glass transition temperature of PPC in the 80/20, 70/30, and 60/40 PPC/PBS blends was improved by about 4.9 K, 4.2 K, and 13 K comparing with that of pure PPC, respectively; which indicated the immiscibility between PPC and PBS. The DSC results indicated that the crystallization of PBS became more difficult when the PPC content increased. The matrix of PPC hindered the crystallization process of PBS. While the content of PBS was above 20%, significant crystallization-induced phase separation was observed by polarized optical microscopy. It was found from the WAXD analysis that the crystal structure of PBS did not change, and the degree of crystallinity increased with increasing PBS content in the PPC/PBS blends.

Miscibility of Semi-flexible Thermotropic Liquid Crystalline Copolyesteramide with Polyamide 66

Liquid crystalline polymer-polyamide 66 (LCP/PA66) blends were compounded by using a Brabender mixing followed by compression moulding. The LCP employed was a semi-flexible liquid crystalline copolyesteramide based on 30% (molar fraction ) of p-amino benzoic acid (ABA ) and 70% (molar fraction) of poly (ethylene terephthalate) (PET). The LCP/PA66 blends were investigated in terms of the thermal and dynamic mechanical properties. It was found that PA66 and LCP components of the blends are miscible in the molten state, but are partially miscible in the solid state. The inclusion of the semi-flexible LCP into PA66 retards the crystallization rate of PA66. Furthermore, the melting temperature and the degree of crystallinity of PA66 are reduced considerably due to the LCP addition.

The impacts of gas impurities on the minimum miscibility pressure of injected CO_2-rich gas–crude oil systems and enhanced oil recovery potential

An effective parameter in the miscible-CO_2 enhanced oil recovery procedure is the minimum miscibility pressure(MMP)defined as the lowest pressure that the oil in place and the injected gas into reservoir achieve miscibility at a given temperature. Flue gases released from power plants can provide an available source of CO_2,which would otherwise be emitted to the atmosphere, for injection into a reservoir. However, the costs related to gas extraction from flue gases is potentially high. Hence, greater understanding the role of impurities in miscibility characteristics between CO_2 and reservoir fluids helps to establish which impurities are tolerable and which are not. In this study, we simulate the effects of the impurities nitrogen(N_2), methane(C_1), ethane(C_2) and propane(C_3) on CO_2 MMP. The simulation results reveal that,as an impurity, nitrogen increases CO_2–oil MMP more so than methane. On the other hand, increasing the propane(C_3)content can lead to a significant decrease in CO_2 MMP, whereas varying the concentrations of ethane(C_2) does not have a significant effect on the minimum miscibility pressure of reservoir crude oil and CO_2 gas. The novel relationships established are particularly valuable in circumstances where MMP experimental data are not available.

Microstructure Evolution in a Rapidly Solidified Cu85Fe15 Alloy Undercooled into the Metastable Miscibility Gap

A model has been developed to describe the microstructure evolution in the atomized droplets of Cu-Fe alloy during cooling through the metastable miscibility gap. Calculations have been performed for Cu85Fe15 alloy to investigate the process of liquid-liquid phase transformation. The numerical results indicate that the minority phase droplets are nucleated in a temperature region around the peak of the supersaturation. The average radius of the Fe-rlch droplets decreases and the number density of the minority phase droplets increases with decreasing the atomized droplet size. The simulated results were compared with the experimental ones. The kinetic process of the liquid-liquid phase transformation was discussed in detail.

STUDY ON THE MISCIBILITY OF DYNAMICALLY VULCANIZED EPDM/PP BLEND BY POSITRON ANNIHILATION SPECTROSCOPY

Positron annihilation spectroscopy (PAS) was utilized to investigate the relationship between the free-volume hole properties and miscibility of dynamically vulcanized EPDM/PP blend. The results showed that the noncrystalline region of PP and EPDM in the blend was partially miscible and the miscibility of the blend became worse when the weight percent of EPDM was <50%. This was also demonstrated by DMTA and mechanical properties of the blends with various compositions.

Miscibility of Poly(hydroxybutyrate)/Poly(vinyl alcohol)Melt Blends Plasticized With Glycerol

Poly(hydroxybutyrate)/poly(vinyl alcohol)(PHB/PVA)blends plasticized with glycerol were prepared by melt blending of PHB and glycerol plasticized PVA.The PHB/PVA-glycerol compositions were 90:10,75:25 and 50:50 w/w,being the concentration of glycerol in the PVA mixture of 10 wt%.The blends were characterized by infrared spectroscopy,dynamic-mechanical thermal analysis,and scanning electron microscope of the fragile fractured surface.The results showed one single phase blend,indicating miscibility corroborated by the presence of a single glass transition temperature.The blending method proved to be an efficient way to tune PHB properties keeping its biodegradable nature since both PVA and glycerol are fully biodegradable materials.

STUDIES ON MISCIBILITY OF POLY (ε-CAPROLACTONE) AND ALIPHATIC POLYCARBONATE BLENDS AND DETERMINATION OF THEIR INTERACTION PARAMETER

In this paper the miscibility of poly (ε-caprolactone) (PCL) and aliphatic polycarbonate (APC) is studied by using DSC. The results show that PCL and APC are miscible in all ranges of composition. The interaction parameter between the polymers is calculated from the melting point depression data. Using optical microscope, the shapes of the PCL spherulites in the blends are observed.

Study on the Miscibility and Phase Behavior of Polyoxymethylene with Novolak

The miscibility and phase behavior of the blends of polyoxymethylene (POM)/Novolak were investigated by the cloud point method, which showed that the POM/Novolak blends exhibited a lower critical solution temperature. The melting point of POM decreased when diluted with Novolak. From the melting temperature depression of POM, a negative interaction parameter (x) between POM and Novolak was obtained. The IR spectrum revealed that the miscibility between POM and Novolak was caused by the specific interaction between the OH groups of Novolak and the ether oxygen atoms of POM. The morphology of the blends investigated by polarized light microscopy showed that the size of spherulites of POM was sharply decreased by its mixing with Novolak. This suggests that Novolak be used as a compatibilizer for POM.

Investigation of the stable and the metastable liquidus miscibility gaps in Fe–Sn and Fe–Cu binary systems

Two kinds of experimental methods were tried in the present work:(i)the powder metallurgy method combined with differential thermal analysis(DTA)to determine the metastable liquidus miscibility gap for a Fe–Cu binary system and(ii)the high-temperature melting method combined with isothermal treatment to determine the stable liquidus miscibility gap for a Fe–Sn binary system.The experimental method was adopted according to the characteristics of the liquidus miscibility gap of the specific system.Using the powder metallurgy method,a uniform microstructure morphology and chemical composition was obtained in the DTA specimen,and the phase-separation temperature of the supercooled metastable liquid was measured.The isothermal treatment was applied for the samples inside the stable liquidus miscibility gap;here,equilibrated compositions were reached,and a layered morphology was formed after rapid cooling.The liquid miscibility gaps of the Fe–Cu and Fe–Sn binary systems were measured,and the peak temperatures of the corresponding miscibility gaps were determined to be about 1417°C at x(Cu)=0.465 at%and 1350°C at x(Sn)=0.487 at%,respectively.On the basis of the experimental results,both the Fe–Cu and the Fe–Sn binary systems were thermodynamically assessed.

TIME-TEMPERATURE-MISCIBILITY AND MORPHOLOGY OF POLYOLEFIN BLENDS

Miscibility and crystallization have been studied for polypropylene-polyethylene and polyethylene-polyethyleneblends. In the case of the polypropylene blends the composition of interest is 20% polypropylene. At this composition thepolypropylene has been found to be soluble in linear low density polyethylene but insoluble in high, low and very lowdensity polyethylenes. The miscibility has been concluded from the crystallization kinetics and polarised optical microscopywith a hot stage. Polyethylene-polyethylene blends have been formed from polymers with similar average branching contentbut where they have different melting temperatures. Important consequences are to introduce long branches into apolyethylene that only has short branches, and to modify the morphology of a polyethylenes so that haze, gloss and strainhardening are improved. Polyethylene blends must be developed after careful consideration of the branch content anddistribution within each of the constituents. It is not sufficient to simply blend polyethylenes, with the desired range ofproperties, without regard to the miscibility of the blend composition.