水污染治理K_(2)CO_(3)-尿素活化毛竹制备分级多孔炭及其对RhB的吸附作用

以毛竹粉为原料,低腐蚀性K_(2)CO_(3)和尿素作为活化剂,制备毛竹基活性炭(PAC),分别利用SEM和N_(2)物理吸附仪(Autosorb-iQ)表征活性炭的表面形态和微观孔结构特点,研究不同p H值、时间和PAC用量等因素对PAC吸附RhB性能的影响,并分析其吸附规律。结果表明,当毛竹粉、K_(2)CO_(3)和尿素的质量比为4∶2∶1,热解温度为600℃,活化时间为60 min时,PAC具有微-介孔共存、高比表面积(2 554.85 m^(2)/g)和总孔容大(0.98cm^(3)/g)的特点。PAC对Rh B表现出良好的吸附效果,45℃时最大静态平衡吸附量达到707.29mg/g,且准二级动力学模型对PAC吸附RhB具有更好的拟合性,即吸附过程以化学吸附为速度控制步骤;吸附等温线试验则表明,Langmuir和Freundlic这2种模型与吸附过程均有较高的拟合度,但Langmuir模型的R^(2)更接近1,属于以单层吸附为主同时存在非均匀多层吸附的行为;热力学结果分析表明,PAC对RhB吸附过程的△G°<0,△H°>0,△S°>0,说明吸附行为是自发进行,且以化学吸附为主。

K_(2)CO_(3)/KOH协同醇解废弃涤纶纺织品及其制备再生DMT的研究

废弃涤纶纺织品囤积量逐年上升,而对废弃涤纶纺织品的综合利用回收率却较低。化学法回收中乙二醇醇解-甲醇酯交换法是一种回收废弃涤纶纺织品的方法,然而乙二醇醇解-甲醇酯交换工艺过程中存在对苯二甲酸双羟基乙酯(BHET)单体产率低、低聚物含量高的问题。文章采用K_(2)CO_(3)/KOH协同醇解废弃涤纶纺织品,并结合响应面法优化了醇解工艺参数,通过甲醇酯交换法制得再生对苯二甲酸二甲酯(DMT),研究了K_(2)CO_(3)/KOH协同醇解对乙二醇醇解-甲醇酯交换产物的影响。结果表明,随着KOH添加量的增加,醇解产物中BHET含量呈现先增加后下降的趋势。当KOH的添加量达到2%时,BHET含量达到最高70.2%。同时,优化后的醇解工艺参数为:反应温度210℃、反应时间120 min、K_(2)CO_(3)质量分数2.0%、KOH质量分数2.4%。此时BHET的收率为73.1%;醇解产物与甲醇酯交换得到再生DMT产率为80.1%,通过减压升华纯化后得到再生DMT含量高于99%以上。

Na_(2)CO_(3)-K_(2)CO_(3)-NaVO_(3)熔盐结构的拉曼光谱和理论计算

NaVO_(3)在Na_(2)CO_(3)-K_(2)CO_(3)熔盐体系中可原位催化电还原CO_(2)制备高附加值碳材料,对Na_(2)CO_(3)-K_(2)CO_(3)-NaVO_(3)体系熔盐结构进行研究有助于明晰电极过程机理和优化反应条件.本文采用拉曼光谱学和量子化学计算(基于Gaussian和Molclus程序)相结合的方法探究了1073 K下Na_(2)CO_(3)-K_(2)CO_(3)-NaVO_(3)熔盐体系的离子结构.结果表明,在该熔盐体系中,除了存在CO_(3)^(2-)以外,还存在由CO_(3)^(2-)和VO_(3)^(-)发生反应生成的VO_(4)^(3-),而不存在VO_(3)^(-);VO_(4)^(3-)所属C1空间点群,其中V-O键的对称伸缩振动模对应的拉曼特征峰位于802 cm^(-1)处;随着体系中NaVO_(3)质量分数由5%增加至15%,熔盐中VO_(4)^(3-)的相对含量急剧增加,而CO_(3)^(2-)的相对含量相应地减少.

K_(2)CO_(3)添加剂细水雾作用下高压氢气喷射火特性研究

为更好地抑制高压氢喷射火,研究了K_(2)CO_(3)添加剂细水雾作用下欠膨胀氢气喷射火特性。试验采用实心锥形细水雾喷嘴,考察细水雾在不同K_(2)CO_(3)添加剂质量分数、水平施加位置和施加压力下,对欠膨胀氢气喷射火火焰形态、火焰水平长度、羽流区温度及辐射的影响。试验采用摄像机、热电偶、辐射热流计分别测量火焰形态、空间指定点温度和辐射强度。结果表明,在含有K_(2)CO_(3)添加剂的细水雾作用下,氢气喷射火焰更明亮。细水雾压力较低(0.5 MPa)且施加位置位于火焰抬升位置时,氢气喷射火出现明显的火焰膨胀现象。通过与纯水细水雾进行对比发现,K_(2)CO_(3)添加剂细水雾对氢气喷射火稳定火焰长度、羽流区温度及热辐射的抑制效果明显,并且抑制效果随着K_(2)CO_(3)添加剂质量分数的增大而增大。

K_(2)CO_(3)-水蒸气催化活化制备兰炭基活性炭的实验研究

选取粒度小于6mm的低价值兰炭末,以K_(2)CO_(3)为催化剂,采用溶液浸渍-水蒸气高温活化技术制备兰炭基活性炭,通过计算收率,碘吸附和亚甲基蓝吸附实验,低温N_(2)等温吸附/脱附实验以及扫描电子显微镜(SEM)表征活性炭孔结构特征,重点考察了催化剂溶液浓度、催化活化温度对孔隙结构的影响。研究表明,相比于常规水蒸气高温活化,K_(2)CO_(3)催化作用能缩短活化时间,活化30min已经十分充分。随着活化温度的上升和催化剂浓度的增加,亚甲基蓝吸附值先增大后减小,碘吸附值持续降低。当催化剂浓度为0.6mol·L^(-1),亚甲基蓝吸附值最高,为234.12mg·g^(-1)。催化活化过程的最佳温度是500℃,此时兰炭基活性炭比表面积和孔容积分别为579.32m^(2)·g^(-1)和0.309cm3·g^(-1),材料中孔和微孔均较为发达。用扫描电镜观察了催化活化制备的兰炭基活性炭的表面形貌,其已经没有规整且丰富孔隙形态,表面不再平整,整体杂乱无序,刻蚀痕迹明显。

K_(2)CO_(3)催化煤炭不完全气化联产高强度颗粒炭及富氢合成气研究

煤气化技术是煤炭清洁高效利用的重要技术。然而,煤气化过程气化碳转化率无法达到100%并产生大量废渣,而细渣中高含量且孔隙发达的残炭提取困难,使得大量堆积的细渣很难资源化利用。从细渣产生的源头出发,采用低灰煤圆柱状成型煤颗粒在K_(2)CO_(3)催化下进行不完全气化(在碳转化率达到70%~80%时终止气化)联产高性能活性炭及富氢合成气,并研究气化气体产物组分和所制备K掺杂活性炭AC-Kx的CO_(2)吸附性能及K对CO_(2)吸附性能的影响。结果表明:在纯水蒸气气氛下,外部热源供热气化终温950℃条件下,Kx催化不完全气化气体产物中H_(2)/CO体积分数比值在2.20~6.29,氢碳比f在1.37~2.32。与未掺杂钾的样品相比,K_(2)CO_(3)催化气体产物的氢碳比显著提高;气化后期产生的气体中CO和CO_(2)体积分数偏高,说明不完全气化及时终止气化反应可提升合成气的氢碳比,同时降低煤气化工艺的碳排放;当K_(2)CO_(3)掺配量为原料煤的5%时,所制备活性炭AC-K5的BET比表面积达到1051 m^(2)/g,亚甲基蓝吸附值达到215 mg/g,耐磨强度95.8%。在200℃中温条件下,AC-K5的CO_(2)吸附量较未掺杂活性炭提升1.63倍。通过K催化煤颗粒不完全气化在生产富氢合成气的同时可联产用于CO_(2)捕集的高强度颗粒炭,提升了煤催化气化的经济性。

K_(2)CO_(3)辅助钯催化C-H活化反应的理论研究

K_(2)CO_(3)是一种常见的碱金属碳酸盐,在有机合成中常被用作碱性添加剂,以加快过渡金属尤其是钯催化C-H活化反应的速率或提高反应产率。因此,研究K_(2)CO_(3)辅助的钯催化C-H活化反应成为近年来有机合成和理论计算领域的热点之一。本文对近十年来K_(2)CO_(3)辅助钯催化C-H活化反应的最新理论研究进展进行分类总结,重点对钯催化C-H活化反应的微观机理、K_(2)CO_(3)的作用机制等进行了深入探讨,并对该领域的发展前景进行展望。

K_(2)CO_(3)-CuZn/UiO-66材料制备及其烟气碳捕集与转化研究

采用溶剂热法制备UiO-66母体材料,然后采用浸渍法制备耦合材料,用K、Cu和Zn的盐溶液真空浸渍UiO-66后再还原,构筑K_(2)CO_(3)-CuZn/UiO-66耦合材料,实现活性组分和助剂的高分散负载,用于CO_(2)捕集与催化加氢合成甲醇研究。结果表明:K_(10)Cu_(5)Zn_(20)@UiO-66具有较大的比表面积(464 m^(2)/g)、较大的孔径(1.3 nm)和较大的孔体积(0.44 cm^(3)/g)。在一定反应条件下,浸渍法构筑的K_(2)CO_(3)-CuZn/UiO-66耦合材料,CO_(2)转化率为11.5%,甲醇选择性为74.2%的K_(15)Cu_(5)Zn_(20)@UiO-66,具有最高催化活性。

大豆油制备生物柴油K_(2)CO_(3)/SiO_(2)固体碱催化剂性能研究

采用浸渍法制备了K_(2)CO_(3)/SiO_(2)固体碱催化剂,运用X射线粉末衍射仪对催化剂进行了分析表征。探究了反应时间、K_(2)CO_(3)负载量、醇油物质的量比、焙烧温度、催化剂用量和焙烧时间6个因素对生物柴油产率的影响。探究结果显示,在大豆油制取生物柴油时,最优的条件是:K_(2)CO_(3)负载量70%、焙烧温度600℃、焙烧时间4 h、反应时间是4 h、催化剂用量3%、醇油物质的量比9∶1。此时产物的产率是94.7%。

柠檬酸用量对浸渍法制备K_(2)CO_(3)/Al_(2)O_(3)吸附剂脱除CS_(2)性能的影响

以K_(2)CO_(3)/Al_(2)O_(3)吸附剂为载体,采用浸渍法制备不同含量柠檬酸改性的CA-K_(2)CO_(3)/Al_(2)O_(3)吸附剂,用于脱除C_(5)馏分油中CS_(2),利用N_(2)吸附-脱附、CO_(2)-TPD和FTIR等方法对不同含量柠檬酸改性的CA-K_(2)CO_(3)/Al_(2)O_(3)吸附剂进行表征。以C_(5)馏分油为原料,采用静态吸附法考察不同含量柠檬酸改性CA-K_(2)CO_(3)/Al_(2)O_(3)吸附剂对C_(5)馏分油中CS_(2)的脱除性能。实验结果表明,当柠檬酸含量为0.07g/mL时,脱硫性能最好,能够在1h内将C_(5)馏分油的硫含量由1200μg/mL降至375μg/mL;添加柠檬酸改性能够增大吸附剂的比表面积和孔体积,减小平均孔径,改变碱性强度,并改变活性组分—OH、—COO和—C=O在吸附剂表面的分布,有助于脱硫活性的提高。

CA_(6)、MA和β-Al_(2)O_(3)质浇注料抗K_(2)CO_(3)侵蚀研究

采用碱蒸气法,对不同温度(800、1000、1200和1350℃)热处理后的3种材质(六铝酸钙、镁铝尖晶石和β-Al_(2)O_(3))的浇注料试样,在对应温度(800、1000、1200和1350℃)下进行抗K_(2)CO_(3)侵蚀试验,然后检测其抗K_(2)CO_(3)侵蚀试验后的显气孔率变化率、体积密度变化率和常温耐压强度变化率,并分析其抗K_(2)CO_(3)试验后的物相组成。结果表明:1800℃时,3种浇注料的抗K_(2)CO_(3)侵蚀性能都很好。21200℃时,六铝酸钙浇注料与K_(2)CO_(3)反应生成大量β-Al_(2)O_(3),抗K_(2)CO_(3)侵蚀性能较差;尖晶石浇注料与K_(2)CO_(3)反应生成的β-Al_(2)O_(3)较少,抗K_(2)CO_(3)侵蚀性能较好;β-Al_(2)O_(3)浇注料与K_(2)CO_(3)反应最弱,抗K_(2)CO_(3)侵蚀性能最好。

介孔K_(2)CO_(3)/SBA-15固体碱催化大豆油制备生物柴油性能研究

采用浸渍法制备了固体碱K_(2)CO_(3)/SBA-15催化剂,通过单因素试验考察了焙烧温度、焙烧时间、K_(2)CO_(3)负载量、催化剂用量和反应时间对利用大豆油制备生物柴油产率的影响。通过X射线衍射(XRD)、扫描电镜(SEM)和透射电镜(TEM)等方法对催化剂进行了表征。结果表明:催化剂通过焙烧产生了新的活性中心K_(2)O;K_(2)CO_(3)/SBA-15催化剂能够很好地保持SBA-15原有的二维六方相有序介孔结构。对催化剂性能进行测试表明:当催化剂的焙烧温度为500℃、焙烧时间为3 h、K_(2)CO_(3)负载量为40%、催化剂用量为大豆油质量的3%、反应时间为4 h时,生物柴油的产率最高,为88.6%。

Raman and infrared spectroscopic quantification of the carbonate concentration in K_(2)CO_(3)aqueous solutions with water as an internal standard

Carbonate-bearing fluids widely exist in different geological settings,and play important roles in transporting some elements such as the rare earth elements.They may be trapped as large or small fluid inclusions(with the size down to<1μm sometimes),and record critical physical-chemical signals for the formations of their host minerals.Spectroscopic methods like Raman spectroscopy and infrared spectroscopy have been proposed as effective methods to quantify the carbonate concentrations of these fluid inclusions.Although they have some great technical advantages over the conventional microthermometry method,there are still some technical difficulties to overcome before they can be routinely used to solve relevant geological problems.The typical limitations include their interlaboratory difference and poor performance on micro fluid inclusions.This study prepared standard ion-distilled water and K_(2)CO_(3)aqueous solutions at different molarities(from 0.5 to 5.5 mol/L),measured densities,collected Raman and infrared spectra,and explored correlations between the K_(2)CO_(3)molarity and the spectroscopic features at ambient P-T conditions.The result confirms that the Raman O-H stretching mode can be used as an internal standard to determine the carbonate concentrations despite some significant differences among the correlations,established in different laboratories,between the relative Raman intensity of the C-O symmetric stretching mode and that of the O-H stretching mode.It further reveals that the interlaboratory difference can be readily removed by performing one high-quality calibration experiment,provided that later quantifying analyses are conducted using the same Raman spectrometer with the same analytical conditions.Our infrared absorption data were collected from thin fluid films(thickness less than~2μm)formed by pressing the prepared solutions in a Microcompression Cell with two diamond-II plates.The data show that both the O-H stretching mode and the O-H bending mode can be used as internal standards to determine the carbonate concentrations.Since the IR signals of the C-O antisymmetric stretching vibration of the CO32ion,and the O-H stretching and bending vibrations from our thin films are very strong,their relative IR absorbance intensity,if well calibrated,can be used to investigate the micron-sized carbonate-bearing aqueous fluid inclusions.This study establishes the first calibration of this kind,which may have some applications.Additionally,our spectroscopic data suggest that as the K_(2)CO_(3)concentration increases the aqueous solution forms more large water molecule clusters via more intense hydrogen-bonding.This process may significantly alter the physical and chemical behavior of the fluids.

Recovery of vanadium and tungsten from waste selective catalytic reduction catalysts by K_(2)CO_(3) roasting and water leaching followed by CaCl_(2) precipitation

Waste selective catalytic reduction(SCR)catalysts are potential environmental hazards.In this study,the recovery of vanadium and tungsten from waste SCR catalysts by K_(2)CO_(3)roasting and water leaching was investigated.The roasting and leaching conditions were optimized:the leaching efficiencies of vanadium and tungsten were 91.19%and 85.36%,respectively,when 18 equivalents of K_(2)CO_(3)were added to perform the roasting at 900℃ for 2 h,followed by leaching at 90°C for 1 h.Notably,in the described conditions,the leaching rate of silicon was only 28.55%.Titanates,including K_(2)Ti_(6)O_(13)and KTi8017,were also produced.Si removal was achieved in 85%efficiency adjusting the pH to 9.5,and the Si impurity thus isolated was composed of amorphous Si.Tungsten and vanadium were precipitated using CaCl_(2).At pH 10 and following the addition of 0.10 mol of H_(2)O_(2)and 16 equivalents of CaCl_(2),the precipitating efficiencies of tungsten and vanadium were 96.89%and 99.65%,respectively.The overall yield of tungsten and vanadium was 82.71%and 90.87%,respectively.

Effect of K_(2)CO_(3) doping on CO_(2) sorption performance of silicate lithium-based sorbent prepared from citric acid treated sediment

In this paper,a low-cost and environmental-friendly leaching agent citric acid(C_(6)H_(8)O_(7))was used to treat the sediment of Dianchi Lake(SDL)to synthesize lithium silicate(Li_(4)SiO_(4))based CO_(2)sorbent.The results were compared with that treated with strong acid.Moreover,the effects of preparation conditions,sorption conditions and desorption conditions on the CO_(2)sorption performance of prepared Li_(4)SiO_(4)were systematically studied.Under optimal conditions,the Li_(4)SiO_(4)sorbent was successfully synthesized and its CO_(2)sorption capacity reached 31.37%(mass),which is much higher than that synthesized from SDL treated with strong acid.It is speculated that the presence of some elements after C_(6)H_(8)O_(7)treatment may promote the sorption of synthetic Li_(4)SiO_(4)to CO_(2).In addition,after doping with K_(2)CO_(3),the CO_(2)uptake increases from the original 12.02%and 22.12%to 23.96%and 32.41%(mass)under the 20%and 50%CO_(2)partial pressure,respectively.More importantly,after doping K_(2)CO_(3),the synthesized Li_(4)SiO_(4)has a high cyclic stability under the low CO_(2)partial pressure.

K_(2)CO_(3)和CaCO_(3)对低温制备SiC多孔陶瓷性能的影响

采用固相反应法制备SiC多孔陶瓷,通过添加二元复合烧结助剂KCO和CaCO与SiC在空气气氛下氧化生成的SiO在较低温度下生成低共融相,促进SiC多孔陶瓷在1100℃-1200℃温度下烧成。研究烧成温度、KCO和CaCO添加量对SiC多孔陶瓷的抗弯强度、显气孔率、气体渗透率、相组成和显微结构的影响。结果表明:当KCO和CaCO添加量分别为1wt%和1wt%,在空气气氛下1100℃保温3h制备的样品综合性能较佳,抗弯强度为33.6MPa,显气孔率为36.3%,气体渗透率为728m~3/(m^(2)·h·KPa)。

梨木炭蒸汽气化制取富氢燃气的试验研究

生物质气化技术已得到广泛的应用,但气化过程产生的焦油会影响设备稳定运行。为了大幅减少焦油的干扰,以梨木的热解炭为原料,在管式炉中进行水蒸气气化制取富氢燃气试验研究,探究了反应温度、K_(2)CO_(3)添加量及利用次数对气化特性的影响。结果表明:900℃时H_(2)的产气量为2.19 L/g,合成气中H_(2)含量超过58%;K_(2)CO_(3)添加量为10%时产气效果最佳,此时合成气中H_(2)+CO含量达到了88.5%。当K_(2)CO_(3)催化剂在第三次利用时,仍有较好的催化效果。

轻质碳酸镁纤维的制备

以MgSO_(4)·7H_(2)O和K_(2)CO_(3)为原料、PEG为结构导向剂,采用共沉淀法合成出轻质碳酸镁纤维,其废液为K_(2)SO_(4)/K_(2)Mg(SO_(4))_(2)溶液。通过XRD、SEM和TG-DTA对样品进行表征,探究了影响轻质碳酸镁组成和形貌的因素及活性碳酸镁纤维形成机理。结果表明:在室温,搅拌速率为300 rad·min^(-1)、Mg SO_(4)浓度为1.0 mol·L^(-1)、Mg SO_(4)与K_(2)CO_(3)摩尔比为1∶1.1、PEG添加量为MgSO_(4)·7H_(2)O质量的30%的条件下,可制备分散性良好、晶须平均长度约为15.89μm、直径0.97μm、长径比为16.38的轻质碳酸镁纤维。

碳酸钾-二乙烯三胺复合溶液吸收烟气中CO_2实验研究

热钾碱溶液在工业脱除二氧化碳中已获得较广泛的应用,但存在吸收速率差、再生负荷高等缺点.开发新型热钾碱溶液成为目前研究热点.采用搅拌实验装置,研究碳酸钾溶液及不同配比的碳酸钾-二乙烯三胺(DETA)复合溶液对烟道气中二氧化碳的吸收和解吸性能,揭示了吸收速率、吸收容量和酸碱度与时间之间的内在联系;对CO2初始逸出温度,试液再生温度,试液再生率,再生pH下降率进行了细致记录分析.实验结果表明,碳酸钾-DETA二元复合体系吸收效果优于单组份碳酸钾的吸收效果.碳酸钾-DETA复合溶液配比为0.6:0.4时吸收效果最佳,吸收量约为0.80mol·L-1;再生温度最低,为107℃;再生率最高,为95.5%.同时与相同配比的碳酸钾-一乙醇胺(MEA)、碳酸钾-二乙醇胺(DEA)相比具有较大再生优势.实验结果还表明碳酸钾-DETA复合体系在二氧化碳吸收过程中存在正交互作用.

金属盐掺杂介孔二氧化硅SBA-15的湿敏特性研究

用模板法合成了介孔二氧化硅SBA-15,为了改善其湿敏特性进行了金属盐掺杂。通过扫描电子显微镜(SEM)和XRD对纯质介二氧化硅SBA-15以及不用金属盐掺杂材料的形貌和结构进行了表征。在11%RH到95%RH的范围内研究了纯SBA-15和不同金属盐掺杂SBA-15材料的湿敏特性。结果表明:适量的金属盐掺杂能很好的提高了介孔硅SBA-15材料的湿敏特性。不同金属盐掺杂SBA-15材料的响应恢复时间也比较迅速,响应时间都在60 s以内,而恢复时间都在180 s以内,能够满足湿度传感器的应用需要。