Influence of MgO/MgCl_2 Molar Ratio on Phase Stability of Magnesium Oxychloride Cement

Formation, solution and phase change of hydration products in MgO-MgCl2-H2O system was studied with thermodynamics method, and resistance to water immersion and phase change of magnesium oxychloride cement with different MgO/MgCl2 molar ratio was experimented. The results show that pH value of immersion solution of cement paste has a remarkable influence on phase stability of hydration products. A higher pH value leads to a lower solubility and a better phase stability of hydration products. When the solution pH value is higher than 10.37, the precipitation of much Mg（OH）2 crystal induces a worse phase stability of hydration products. With the increasing MgO/MgCl2 molar ratio （lower than 6）, the more amount of MgO in the hydration products enhances the alkalinity of solution and the phase stability is improved. However, when the MgO/MgCl2 molar ratio is higher than 6 and the excessive MgO exsits in the hydration products, the cement paste may be damaged by the excessive crystallization stress of a great deal of Mg（OH）2 formation.

Optimization of Cr/Mo molar ratio in FeCoCrMoCBY alloys for high corrosion resistance

The corrosion behavior of bulk metallic glasses(BMGs)(Fe41Co7Cr15Mo14C15B6Y2)100-xCrx(x=0,4,8,12,molar fraction,%)was investigated in1mol/L HCl aqueous solution with electrochemical tests.The electrochemical measurements demonstrate that the passive current density of Fe-based amorphous alloy is reduced by about one order of magnitude,and meanwhile,the stability of passive film can be guaranteed by the Cr/Mo molar ratio.The Mott–Schottky(M–S)curves show that the passive film is the densest when the molar ratio of Cr/Mo is between1.37and1.69.X-ray photoelectron spectroscopy(XPS)analysis was performed to clarify chemical states of elements in the passive films.The results show that the corrosion resistance of the alloy is related to the molar ratio of Cr/Mo.The stability of passive film is determined by the synergistic action of Cr and Mo elements.The main component of the passive film is Cr3+oxide.When the potential is greater than0.5V(vs SCE),Mo6+ions play an important role in keeping the stability of the passive film.The appropriate molar ratio of Cr/Mo can reduce the dissolution rate of the passive film.

Silica-alumina molar ratio and some factors effect on the synthesis of zeolites from fly ash

In order to improve the activity and eliminate some impurities, pretreatment was used before hydrothermal synthesis. The fly ash was mixed with an aqueous NaOH solution, the alkali melted fly ash was also adopted, which is hydrothermally treated at about 104 ℃, and the liquid/solid ratio was controlled at 6：1. In order to control Si/Al molar ratio, SiO2 or Al2O3 powers were added to the fly ash. The results of XRD and SEM show that the alkali melted can activate fly ash and eliminate its quartz and mullite, along with the improvement of Si/Al molar ratio and alkalinity. In addition, zeolite Na-A changes into sodalite gradually, and nepheline is the synthesized intermediate product. Those results were discussed on the basis of a formation mechanism of zeolite from fly ash.

Effects of temperature and initial molar ratio of Na_2O to Al_2O_3 on agglomeration of fine Al(OH)_3 seed in synthetic Bayer solution

Fine Al（OH）3 crystals were aggregated from supersaturated aluminate solution in the batch reaction tanks. By means of laser particle size analyzer and scanning electron microscopy, the influences of temperature and initial molar ratio of Na2O to Al2O3 （aK） on agglomeration of fine seed in Bayer process were investigated. The results show that agglomeration is almost finished in 8 h, and seeds with size less than 2 μm are easily aggregated together, and almost disappear in 8 h under the optimal process conditions. In the aluminate solution with the same moderate initial aK, when the reaction temperature reaches 75 ℃, the secondary nucleation does not occur, and the effect of agglomeration is better. And at the same reaction temperature, when the initial aK is 1.62, the initial supersaturation of aluminate solution is moderate, the binders on the surfaces of the seed are enough to maintain the agglomeration process, and the agglomeration degree is better. From SEM images, agglomeration mainly occurs in the fine particles, the combinations among the fine particles are loose and the new formed coarse crystal shapes are irregular.

Influnce of Stoichiometry and Molar Ratio of Barium Ferrite Thin Film Synthesized by Sol-gel on Alumina Substrate

Amorphous gels were processed with a varying Fe/Ba ratio of 11/5, 28/2, 10.5/1 in water and Solvent. Iron and barium nitrites with specific molar ratio was solved in water and slovent at 60°C for 3 hours until! a dark brown solution was prepared . The sols were introduced to substrate dropwise and spinning with 2000 rpm in 3 min was applied ; the work was repeated for 10 times and the samples were dried and sintered . The TGA analysis was used to identify the heating rate of the samples; at temperature of 1150°c for one hour the final phase was attained . the thickness , uniformity , morphology and the composition were examined by SEM and XRD. The study shows that the fabrication barium ferrite film of the molar ratio of Fe/Ba = 10.5/1 is much more suitable than other ratios .

Molar ratio induced crystal transformation from coordination complex to coordination polymers

Coordination complex of a copper cyanurate(Cu(Ⅱ)-CA) was transformed into coordination polymers upon the stimulus of extra Cu(Ⅱ) through “directed Ostwald ripening”. By increasing the molar ratio of Cu(Ⅱ) to CA, we obtained two coordination polymers with selective coordination sites: Cu(Ⅱ)-κ N(HCA)κ NCu(Ⅱ) and Cu(Ⅱ)-κ N(HCA)κ O-Cu(Ⅱ), which display disparate magnetic interactions.

Efficient removal of Al(Ⅲ)and P507 from high concentration MgCl_(2)solution based on in-situ reaction strategy

For a highly efficient recycling of a wastewater containing a high concentration of MgCl_2,Al(Ⅲ)and P507 were scheduled to be removed in advance.In this study,the in-situ removal of Al(Ⅲ)and P507 from a high concentration MgCl_(2)solution at different pH values and Al/P molar ratios was investigated.The results showed that P507 formed organic complexes of Al_x(OH)_y~(Z+)-P507 at pH of 2.0-4.0.At pH of 4.0-5.0,Al(Ⅲ)precipitated and transferred into Al(OH)_(3)with a flocculent amorphous morphology.Active sites on the Al(OH)_(3)surface enhanced the removal efficiency of P507.At pH of 6.0-6.5,Al(Ⅲ)and Mg(Ⅱ)formed layered crystalline Al(OH)_(3)and MgAl_2(OH)_(8with)small pore channels and fewer active sites,resulting in a reduced removal efficiency of P507.When the Al/P molar ratio exceeded 13 and the pH was between 4.0 and 5.0,the removal rates of both Al(Ⅲ)and P507 were higher than98%,while the concentration loss of Mg(Ⅱ)was only 0.2%-0.9%.

Fractionation of residual Al in natural water treatment from reservoir with poly-aluminum-silicate-chloride (PASiC): Effect of OH/Al, Si/Al molar ratios and initial pH

An aluminum fractionation study was conducted for a surface reservoir water treatment to understand the performance of poly- aluminum-silicate-chloride （PASiC） in terms of the residual A1 fractions as a function of initial pH. The coagulation performance expressed as turbidity and organic matter removal was established as supporting data. Some extra data were evaluated in terms of the residual A1 ratio of the composite PASiC coagulant. The main residual A1 sources were the A1 fractions derived from the use of PASiC. The turbidity and organic matter removal ability was optimal at initial pH 6.00-7.00, while the concentrations of various residual A1 species and the residual A1 ratio of PASiC were minimal at an initial pH range of 7.00-8.00. Under the conditions of OH/AI molar ratio = 2.00 and Si/A1 molar ratio = 0.05, PASiC had superior coagulation performance and comparatively low residual A1 concentrations. The A1 fraction in the composite PASiC coagulant seldom remained under such conditions. Experimental data also indicated that the suspended （filterable） AI fraction was the dominant species, and organic-bound or organo-A1 complex A1 was considered to be the major species of dissolved A1 in water treated by PASiC coagulation. Additionally, the dissolved inorganic monomeric A1 species dominated the dissolved monomeric A1 fraction.

Circulating Fluidized Bed Gasification of Low Rank Coal：Influence of O2/C Molar Ratio on Gasification Performance and Sulphur Transformation

To promote the utilization efficiency of coal resources,and to assist with the control of sulphur during gasification and/or downstream processes,it is essential to gain basic knowledge of sulphur transformation associated with gasification performance.In this research we investigated the influence of O_2/C molar ratio both on gasification performance and sulphur transformation of a low rank coal,and the sulphur transformation mechanism was also discussed.Experiments were performed in a circulating fluidized bed gasifier with O_2/C molar ratio ranging from 0.39 to 0.78 mol/mol.The results showed that increasing the O_2/C molar ratio from 0.39 to 0.78 mol/mol can increase carbon conversion from 57.65%to 91.92%,and increase sulphur release ratio from 29.66%to63.11%.The increase of O_2/C molar ratio favors the formation of H_2S,and also favors the retained sulphur transforming to more stable forms.Due to the reducing conditions of coal gasification,H_2S is the main form of the released sulphur,which could be formed by decomposition of pyrite and by secondary reactions.Bottom char shows lower sulphur content than fly ash,and mainly exist as sulphates.X-ray photoelectron spectroscopy(XPS)measurements also show that the intensity of pyrite declines and the intensity of sulphates increases for fly ash and bottom char,and the change is more obvious for bottom char.During CFB gasification process,bigger char particles circulate in the system and have longer residence time for further reaction,which favors the release of sulphur species and can enhance the retained sulphur transforming to more stable forms.

The influence of molar ratios of Ce/Zr on the selective catalytic reduction of NO_x with NH_3 over Fe_2O_3-WO_3/Ce_xZr_(1-x)O_2(0≤x≤1) monolith catalyst

A series of CexZr1-xO2(0 B x B 1)with different molar ratios of Ce/Zr were syhthesized via coprecipitation method,and Fe2O3-WO3/CexZr1-xO2monolithic catalysts were prepared for selective catalytic reduction of nitrogen oxides by ammonia(NH3-SCR).The structural properties and redox behavior of the catalysts were comprehensively characterized by N2physisorption,X-ray diffraction(XRD),X-ray photoelectron spectra(XPS),H2-temperature programmed reduction(H2-TPR)and activity measurement for NH3-SCR.The results showed that the NH3-SCR activities of the catalysts were gradually enhanced by increasing the molar ratios of Ce/Zr,especially the lowtemperature catalytic activity and the reaction temperature window.Fe2O3-WO3/Ce0.68Zr0.32O2monolithic catalyst presented the best NH3-SCR activity among the investigated catalysts,more than 90%NOxcould be removed in the temperature range of 247–454°C on the catalyst under the gas hourly space velocities of 30,000 h-1.And it always held more than 99%N2selectivity and less than 20 ppm(1 ppm=10-6L/L)N2O generation concentration between 200 and500°C,the catalyst also displayed its strong resistance of H2O and SO2.Good textural and structural properties,more surface Fe,Ce and active oxygen were together contributed to the excellent NH3-SCR performance of Fe2O3-WO3/Ce0.68Zr0.32O2catalyst.

摩尔比对MMOS水泥力学性能和变形行为的影响及机理

研究了原材料摩尔比(n(MgO)∶n(MgSO_(4))∶n(H_(2)O))对改性硫氧镁(MMOS)水泥力学性能和变形行为的影响,并采用X射线衍射仪(XRD)、扫描电镜(SEM)、傅里叶变换红外光谱(FTIR)及热重分析(TG)等测试技术对其机理进行分析.结果表明:MMOS水泥的抗压强度和抗折强度随着水硫比和氧硫比的提高均呈提升趋势.其中原材料摩尔比为10∶1∶12时,水泥力学性能最优.不同摩尔比MMOS水泥在56d龄期内均呈膨胀变形,其中总变形随水硫比和氧硫比的提高呈减小趋势;自收缩变形随水硫比的提高而减小,随氧硫比的提高呈先增后减趋势.这主要是由于硬化后不同摩尔比MMOS水泥中的水化产物Mg(OH)_(2)和5·1·7相(5Mg(OH)_(2)·MgSO_(4)·7H_(2)O)含量各有不同.当Mg(OH)_(2)含量减少,而5·1·7相含量增加时,MMOS水泥的膨胀变形量降低,同时其抗折强度和抗压强度有所提升.

─NCO/─OH物质的量比对无外加溶剂聚氨酯预聚体的MMA溶液流变行为影响

无外加溶剂、自乳化丙烯酸酯改性水性聚氨酯复合乳液的绿色合成是聚氨酯(PU)工业的重要研究目标。以甲基丙烯酸甲酯(MMA)代替丙酮,会影响该预聚体溶液的流变行为,而调控其流变行为的主要方法是调控异氰酸酯基与羟基的物质的量比n。为了探究n值对其流变行为的影响,制备了不同n值PU预聚体的MMA溶液,采用旋转黏度计和流变仪进行测试。结果表明,不同n值PU预聚体的MMA溶液黏性占主导;随n值增大,PU预聚体的MMA溶液黏度下降、黏流活化能增加,剪切变稀的临界剪切速率增大,损耗模量与储能模量降低,Lissajous曲线偏离椭圆形的线性响应程度更严重。

无溶剂快速合成S-1和TS-1分子筛

Silicalite-1(S-1)和Titanium Silicalite-1(TS-1)沸石分子筛因其良好的疏水性、热稳定性和择形性等特点,作为环境友好的绿色催化剂在工业应用上极具优势和价值.采用无溶剂法成功合成了TS-1分子筛,并利用X-射线衍射仪、全自动比表面和孔隙分析仪、紫外可见光谱仪和扫描电镜等表征仪器研究了晶化时间和硅钛摩尔比对所制备TS-1分子筛的物化性质的影响.结果表明,合成的TS-1沸石分子筛具有较高的结晶度和纯度、均一的晶粒大小、高的比表面积和在分子筛骨架中四配位和六配位的钛物种.无溶剂合成TS-1沸石具有低成本、环境友好和高效的优点,研究将为工业上沸石的规模合成提供一定的理论借鉴.

海南石碌铁矿石氢基矿相转化——磁选试验研究

海南石碌铁矿石铁品位为52.45%,铁主要以赤(褐)铁矿形式存在,分布率达86.18%,少量以磁铁矿形式存在。为高效回收利用该矿石,采用氢基矿相转化(HMPT)—磁选工艺流程开展了系统的试验研究,并对适宜条件下的产品进行了化学成分、XRD和VSM分析。结果表明:试样在给矿粒度-0.074mm占89.41%、HMPT温度525℃、HMPT时间10min、总气体流量500m L/min、H_(2)浓度20%、HMPT产品磨矿细度-0.045mm占69.68%的适宜条件下,经磁选获得铁品位65.26%、铁回收率95.39%的铁精矿。试验所获铁精矿较原重磁联合工艺铁精矿品位提高了2.7个百分点,铁回收率增加了30个百分点。研究不仅为海南石碌铁矿氢基矿相转化—高效分选工业应用提供技术支撑,还为其他复杂难选铁矿资源的绿色高效分选提供了参考依据。

铁磷共沉淀去除水中磷酸根的效果及机制

【目的】探究环境条件改变对铁盐除磷的影响及潜在机理,为污水除磷方法的开发和应用提供理论基础。【方法】利用宏观除磷试验探明不同pH、铁磷摩尔比对水体磷酸根去除的影响;结合X-射线衍射(XRD)及热力学模型,探究化学沉淀和吸附过程中磷的去除机制。【结果】随着pH升高,磷去除率先上升后下降;随铁磷摩尔比升高,磷的去除率呈现上升趋势;当反应条件为pH=5、铁磷摩尔比3∶1时,磷的去除率最高,为89.42%。XRD和热力学模型结果表明,磷主要通过形成铁-磷沉淀,如FePO4,或被铁氧化物吸附,达到从水体中去除的目的。【结论】在铁盐除磷的过程中,共沉淀和吸附两种机制并存。pH对这两种机制均有影响,而铁磷摩尔比则主要通过调控磷的吸附过程来改变磷的去除效率。

Er_(2)SiO_(5)纳米粉体的并流共沉淀法合成

以Er_(2)O_(3)和正硅酸乙酯(TEOS)为原料,采用并流共沉淀法合成了纳米Er_(2)SiO_(5)粉体。研究了前驱体Si/Er摩尔比、煅烧温度以及反应体系pH值对Er_(2)SiO_(5)物相组成和显微结构的影响,并探讨了Er_(2)SiO_(5)粉体的合成机理。结果表明:前驱体Er/Si摩尔比为20∶12,煅烧温度为1300℃时,Er_(2)SiO_(5)粉体由X2-Er_(2)SiO_(5)纯相组成,具有近球形形貌特征。低Er/Si摩尔比可降低Er_(2)SiO_(5)的结晶温度并促进X2-Er_(2)SiO_(5)的生成,反应体系pH值的升高则对[Si—O—Er]结构的生成具有一定的促进作用。Er_(2)SiO_(5)前驱体是以[Si—O—Er]网络结构形式存在的,煅烧过程中通过分解和结构重组逐步生成Er_(2)SiO_(5),Er_(2)O_(3)杂质相的生成是高Er/Si摩尔比前驱体[Si—O—Er]网络结构中的Er^(3+)在Er_(2)SiO_(5)结晶过程中的析出造成的。

石灰铁盐法处理高砷废酸应用研究

选择工业具有代表性的高砷污酸,研究了石灰铁盐法控制性因素,如反应终点pH、Fe/As摩尔比、反应时间及氧化方式对除砷及固砷的影响。结合工业应用实际情况,在pH=1.2、石膏晶种比1∶1、反应时间2 h的条件下,优先产出合格石膏产品。再以H_(2)O_(2)为氧化剂,H_(2)O_(2)/As摩尔比1.5,反应终点pH=8,晶种比例1∶1,Fe/As摩尔比4.5,反应时间3 h进行除砷,除砷后液As浓度0.12 mg/L,小于标准值(0.5 mg/L),除砷率接近100%,除砷渣TCLP浸出毒性为2.25 mg/L,小于标准值(3 mg/L)。该工业应用工艺方法流程简单、操作方便、成本低廉,是一种可靠安全除砷固砷工艺。

基于ZnO/CuO敏感电极的NO_(2)传感器性能

二氧化氮(NO_(2))是最常见的空气污染物之一,主要来源于化石燃料的燃烧,需要研制性能优良的NO_(2)气体传感器来对其体积分数进行实时监测。采用氧化钇稳定的氧化锆(YSZ)为固体电解质、ZnO/CuO为敏感电极,制备了阻抗型NO_(2)传感器。采用分步浸渍法将敏感材料原位引入到YSZ多孔骨架中,通过调整敏感材料ZnO/CuO摩尔比来优化传感器的敏感性能。用X射线衍射仪(XRD)和扫描电子显微镜(SEM)对样品的组成和微观结构进行了表征。结果表明,ZnO/CuO颗粒均匀分散在YSZ多孔层中。以相角(Θ)作为响应信号来评价传感器敏感性能。实验结果表明,与单一氧化物ZnO相比,ZnO和CuO摩尔比为8∶2制备的传感器对NO_(2)气体具有更好的敏感性能。在400~500℃,Θ响应值与5×10^(-5)~5×10^(-4)NO_(2)体积分数呈良好的线性关系。450℃时,传感器有最低检测下限5×10^(-5)。此外,该传感器表现出最大响应值(5×10^(-4)NO_(2)的Θ响应值为18°)、最佳灵敏度(0.039°/10^(-6))、良好的稳定性以及对其他气体的抗干扰能力。

Laboratory-scale study of the suppression of PCDD/F emission during coal and MSW co-incineration

The experimental test of co-incinerating Chinese raw municipal solid waste （MSW） and coal in a laboratory-scale tubular reactor was first reported in present study, and the emission of normal gas components and the effects of the S/Cl molar ratio or coal mixing percentages on polychlorinated dibenzo-p-dioxins and dibenzofurans （PCDDs/Fs） emission were investigated and discussed. The results indicated that OCDD was the only PCDD homologues since others like TCDD-HpCDD was hardly detected, while as the categories of PCDF homologues were comparatively much more general. The amount of PCDD was much larger than that of PCDF in all operating conditions. Since ZPCDF/∑PCDD〈〈1, the dominant role of the precursor formation was proven in our experimental conductions. With increasing the coal addition to MSW （from 0 to 16%）, PCDD and PCDF were reduced considerably. Coal and MSW may suppress the PCDD/F emissions efficiently （over 95%） during the MSW incineration process. The PCDD/F suppression results of the present study could be helpful guidance to the industrial application of Chinese MSW and auxiliary coal co-incineration processes. The PCDD/F stack emission data of two industrial incinerators using co-incineration technology in China seem to have a great positive reduction of PCDDs/Fs.

高硅MCM-22分子筛的合成与催化性能

以六亚甲基亚胺(HMI)和N,N,N-三甲基-1-金刚烷基氢氧化铵(TMAdaOH)为复合有机结构导向剂合成高硅MCM-22分子筛,并负载钼制备不同SiO_(2)/Al_(2)O_(3)摩尔比的MCM-22催化剂,采用XRD、FT-IR、UV-Raman、SEM、NH3-TPD等手段对分子筛产品进行表征,并对负载型MCM-22催化剂进行重芳烃轻质化反应性能评价。结果表明:HMI和TMAdaOH复合协同作用能有效促进硅原子进入MCM-22分子筛骨架,抑制麦羟硅钠石的出现,提升分子筛的骨架结晶性和结构稳定性,其中SiO_(2)/Al_(2)O_(3)摩尔比80合成的MCM-22分子筛(S80)具有最高的微孔结晶度和丰富的中强酸分布;在反应温度为360℃、H_(2)/重芳烃原料摩尔比为3.0、反应压力为3.0 MPa、MHSV为3.0 h^(-1)的条件下,Mo/H-S80催化剂作用下碳九芳烃和碳十芳烃转化率分别为64.9%和62.7%,产物苯、甲苯和二甲苯的总选择性达到87.6%;对反应后Mo/H-S80催化剂的积炭分析结果表明,高硅MCM-22分子筛S80更易于扩散并转化重组分、控制副反应的发生,是高效轻质化的理想催化材料。