以铅笔芯为吸附基质的顶空-固相微萃取法测定酒中的甲醇

固相微萃取(SPME)是以固相萃取(SPE)为基础发展起来的新方法。在多次实验后发现,主要成分为碳的铅笔芯在经过一定的物理,化学处理后对被分析物能产生定量吸附,因此可用作SPME的萃取基质。对该吸附基质,选择了其萃取、解吸的最佳条件如:萃取时间,水浴温度,搅拌速度,解吸时间及温度等。在选定的最佳条件下,以铅笔芯作吸附基质对甲醇进行顶空 固相微萃取测定,其线性范围是5×10-6～2×10-7g/mL,线性相关系数r=0.9975。富集20min后,检出限为0.5×10-7g/mL。使用该法测定了5种酒中的甲醇含量,回收率在95%～110%之间。在对同一样品的3次平行测定中,其相对标准偏差在6%以下。     

吸附/热脱附气相色谱分析痕量C1～C5烃

本文以活性炭、TDX-01、Tenax GC、Porapak Q和GDX-104为吸附剂，不经冷凝，在常温下吸附富集痕量C1～C5烃并直接引入毛细管柱。同时探讨了吸附剂的最佳热脱附温度、饱和吸附量、吸附富集回收率、热脱附直接进样的线性规律及方法的相对偏差．     

改性榛壳吸附剂固相萃取-紫外可见分光光度法分析水中孔雀石绿

合成改性榛壳生物吸附剂SCHFS,利用FTIR、SEM、XPS对结构进行表征。以此吸附剂为固相萃取剂,研究淡水鱼源性食品中孔雀石绿的吸附富集行为。探讨溶液p H、吸附时间、吸附温度对吸附性能的影响;考察解吸液种类、体积对解吸效率的影响。实验结果表明,室温下溶液p H 6.0、振荡吸附60min时能达到最佳吸附效果,此时吸附率大于98%;选用50%甲醇乙酸溶液为解吸液,在60min内解吸率超过95%,在最佳实验条件下,富集倍数为5。该方法的线性范围0.1~3mg·L~(-1),检出限为0.022mg·L~(-1),测定水样中孔雀石绿含量,加标回收率在95.7%~108.8%。     

大孔吸附树脂富集板蓝根中(R,S)-告依春工艺研究

采用静态吸附法考察了D101、AB-8、NKA-2、NKA-9、HPD 100、HPD600等6种大孔吸附树脂对(R,S)-告依春的吸附及解吸性能,筛选出效果最佳的AB-8树脂,并对其进行动态考察.最佳富集条件为:上样液pH 6,生药质量-体积浓度为0.200g/mL,解吸液为2BV量70％乙醇,在优化条件下(R,S)-告依春在浸膏中含量可从0.76％提高到12.48％.结果表明,AB-8型大孔吸附树脂可用来从板蓝根水提取液中富集(R,S)-告依春.     

SF_6分解产物的氦离子色谱分析方法

本发明公开了一种SF6分解产物的氦离子色谱分析方法,采用包括一根硅胶柱、一根第一Porapak Q柱、一根第二Porapak Q柱以及一根Gaspro毛细柱的4根色谱柱联用对样品进行组分分离,采用包括第1阀、第2阀、第3阀、第4阀在内的4个阀进行切割组分分离控制,采用第一PDD检测器和第二PDD检测器对分离后的样品分别进行分析测试。本发明分析方法能够同时准确检测传统分析方法不能准确检测的SF6分解产物,如H2,O2,N2,CO,CH4,CO2,COS,H2S,SOF2,CS2等化合物,通过全面准确的对SF6分解产物进行分析,从而准确判断SF6气体绝缘设备内部运行情况,保障电气设备安全运行。     

热解吸-气相色谱法测定植物源挥发性有机物

以Tenax-TA、Carboxen 1000和Carbosieve SⅢ为采样管填充料,将植物源挥发性有机物吸附于采样管内,样品通过二次热解吸仪解吸后,随载气进入气相色谱仪,采用氢火焰离子化检测器(FID)测定,建立了利用二次热解吸仪与气相色谱联用技术测定植物挥发性有机物的分析方法。载气N2流速为30 mL/min,60℃下吹扫吸附管2 min,然后在250℃下解吸吸附管5 min,冷却1 min后,在275℃下解吸聚焦管3 min,样品经传输线进入气相色谱。气相色谱载气N2压力为190 kPa,FID检测器温度280℃;进样口温度225℃;初始柱温40℃,停留5 min,以2℃/min升温至120℃,保留1 min,然后以20℃/min升温至200℃,保留10 min。方法重现性好,精密度高,线性相关系数大于0.99;检出限均低于9×10-9g/L;解吸效率大于96%,适用于植物源挥发性有机物的测定。     

含氰基聚合物微球对铜离子吸附性能的研究

以火焰原子吸收光谱法(FAAS)为检测手段,研究了聚丙烯腈微球(PANMS)对溶液中Cu2+的吸附及其影响因素,并建立了PANMS分离富集-FAAS法。实验结果表明,溶液pH为5、静态吸附时间为1.5 h、温度为20℃时,其对Cu2+的吸附达到饱和而稳定,吸附容量为30.2 mg/g,吸附率可达到87.5%。随着吸附时间的延长吸附率有所提高,但幅度不是很大。以0.1 mol/LHC l溶液作为解吸剂,解吸率可达到96.5%。经富集50倍后,测Cu2+工作曲线的回归方程为A=0.0025C(μg/L)-0.0026(r=0.9993),方法的检出限为1.68μg/L,相对标准偏差(RSD)小于2.9%。加标回收率为91.4%~97.0%。     

绿茶对水溶液中Pb2+和Cd2+吸附性能初步研究

研究了绿茶对溶液中Pb2 和Cd2 离子的吸附和解吸性质。考察了pH、温度、吸附时间对绿茶吸附性能的影响,得到吸附动力学曲线和吸附等温线。结果表明,茶叶在pH为4~6的弱酸性范围内对两种金属离子的吸附效果最佳,在30℃时,茶叶对Pb2 和Cd2 的饱和吸附量分别为46.66 mg/g和33.29mg/g,吸附符合Langmuir吸附等温方程,并对吸附机理进行了初步的探讨。对解吸条件研究发现,用0.1 mol/L HCl和EDTA作为解吸剂,对Pb2 和Cd2 的解吸效果较好,解吸率达80%以上,可有效回收重金属Pb2 和Cd2 。     

纳米Zr(OH)4及纳米ZrO2对Cu(Ⅱ)的吸附行为

对纳米Zr(OH)4粉体及其在不同温度(350～600℃)下的煅烧产物静态吸附Cu(Ⅱ)的行为进行了研究,并考察了影响静态吸附以及解吸的因素.试验结果表明,煅烧温度越高,样品的吸附效果越差.除了600℃煅烧的样品吸附性能较差外,纳米Zr(OH)4和其它样品在溶液pH》3时对Cu(Ⅱ)有很好的吸附效果,吸附率均大于96%.在实验范围内,吸附量最高可达到26400μg/g.被吸附的Cu(Ⅱ)在低浓度的盐酸(《2.0mol/L)中即可较好的被洗脱,100℃时解吸率可达到96%,同时也有很好的富集效果.     

顺丁烯二酸-co-苯乙烯微球对Cd(Ⅱ)的吸附行为研究

以火焰原子吸收光谱法(FAAS)为检测手段,研究了本实验室合成的顺丁烯二酸-苯乙烯共聚物微球对Cd(Ⅱ)的静态吸附性能,考察了影响吸附率的相关因素以及不同浓度的各种解吸剂对Cd(Ⅱ)的解吸效果.溶液pH为6、吸附时间为2h时吸附基本达到平衡,吸附率可达到95%以上.以3 mol/,L的HCI溶液作为解吸剂对Cd(Ⅱ)进...     

大气有机物预浓缩用吸附剂富集特性的气相色谱法研究

用气相色谱方法研究了吸附剂对大气有机物的富集特性,提出用吸附参数泄漏体积ＢＴＶ（最大采样体积）以及脱附参数最低脱附温度或最小吹扫体积作为富集指标的新思想,并用冲洗色谱法测定了一些有机物在ＧＤＸ－３０１上的特性参数。不同温度的特性参数由１ｏｇ（ＢＴＶ）与１／Ｔｃ的线性关系外推得到。实验表明,所研究的２０种有机物（除了甲醇外）在装有２ｇＧＤＸ－３０１的采样管和０．１４ｇＧＤＸ－３０１的聚焦管上的最大采样体积分别不小于０．８Ｌ（３５℃）和０．３Ｌ（０℃）。     

Separation and purification of flavonoid from Taxus remainder extracts free of taxoids using polystyrene and polyamide resin

An efficient separation process of flavonoid from Taxus wallichiana var. mairei remainder extracts free of taxoids was developed in this study. AB‐8 macroporous resin and polyamide resin offered the fine adsorption capacity, and its adsorption rate at 30°C fitted well to the Langmuir and Freundich isotherms. Resin dynamic adsorption and desorption experiments were conducted to optimize the separation process of total flavonoids from T. wallichiana var. mairei remainder extracts free of taxoids. The optimum parameters for adsorption by AB‐8 resin were as follows: (1) the concentration of flavonoids in a sample solution of 5.61 mg/mL with a processing volume of 2 bed volume (BV) (60 mL); (2) for desorption, ethanol–water (80:20, v/v), with 6 BV as an eluent at a flow rate of 2 BV/h. After a one‐run treatment with AB‐8 resin, the content of flavonoids was increased 5.10‐fold from 4.05 to 20.65%. The optimum parameters for adsorption by polyamide resin were as follows: processing volume of 2 BV (30 mL); for desorption, ethanol–water (70:30, v/v), with 8 BV as an eluent at a flow rate of 2 BV/h. After one‐run treatment with polyamide resin, the content of total flavonoids increased from 20.65 to 65.21%. The method will provide a potential approach for large‐scale separation and purification of flavonoid for its wide pharmaceutical use.     

CO_2 residual concentration of potassium-promoted hydrotalcite for deep CO/CO_2 purification in H_2-rich gas

Elevated-temperature pressure swing adsorption is a promising technique for producing high purity hydrogen and controlling greenhouse gas emissions. Thermodynamic analysis indicated that the CO in H_2-rich gas could be controlled to trace levels of below 10 ppm by in situ reduction of the CO_2 concentration to less than 100 ppm via the aforementioned process. The CO_2 adsorption capacity of potassiumpromoted hydrotalcite at elevated temperatures under different adsorption(mole fraction, working pressure) and desorption(flow rate, desorption time, steam effects) conditions was systematically investigated using a fixed bed reactor. It was found that the CO_2 residual concentration before the breakthrough of CO_2 mainly depended on the total amount of purge gas and the CO_2 mole fraction in the inlet syngas.The residual CO_2 concentration and uptake achieved for the inlet gas comprising CO_2(9.7 mL/min) and He(277.6 mL/min) at a working pressure of 3 MPa after 1 h of Ar purging at 300 mL/min were 12.3 ppm and0.341 mmol/g, respectively. Steam purge could greatly improve the cyclic adsorption working capacity, but had no obvious benefit for the recovery of the residual CO_2 concentration compared to purging with an inert gas. The residual CO_2 concentration obtained with the adsorbent could be reduced to 3.2 ppm after 12 h of temperature swing at 450 °C. A new concept based on an adsorption/desorption process, comprising adsorption, steam rinse, depressurization, steam purge, pressurization, and high-temperature steam purge, was proposed for reducing the steam consumption during CO/CO_2 purification.     

新型多级微/介孔固态胺吸附剂的制备及其CO2吸附性能研究

将HZSM-5与MCM-41按不同质量比混合得到复合分子筛载体,以四乙烯五胺(TEPA)为改性剂,采用浸渍法将其负载到复合分子筛上,制备了一系列新型的具有多级微/介孔结构的固态胺吸附剂。采用N₂吸脱附、傅里叶变换红外光谱(FT-IR)、热重分析(TGA)等手段对吸附剂进行表征。在固定床反应器中考察了HZSM-5和MCM-41的质量比、TEPA负载量、吸附温度、进气流量和CO₂分压等因素对CO₂吸附性能的影响。结果表明,当HZSM-5与MCM-41的质量比为1:1、TEPA负载量为30%、吸附温度为55℃、进气流量为30 mL/min时,平衡吸附量高达3.57 mmol/g,且经10次吸脱附循环后,吸附量仅下降8.1%。HZSM-5/MCM-41-30%TEPA对CO₂的吸附过程包括快速的穿透吸附和相对缓慢的逐渐平衡阶段,且穿透吸附量接近于平衡吸附量的80%。HZSM-5/MCM-41-30%TEPA对CO₂的吸附过程符合Avrami动力学模型,表明CO₂吸附是物理吸附和化学吸附的结果。     

离子交换树脂固态胺复合材料的制备、表征及CO2吸附

以离子交换树脂（D001）为载体,四乙烯五胺（TEPA）为改性剂,采用三种不同的方法制备了一系列固态胺吸附剂。采用N₂吸附-脱附、傅里叶变换红外光谱（FT-IR）、热重分析（TGA）等手段对吸附剂进行表征。在固定床反应器中考察了TEPA负载量、吸附温度、进气流量和CO₂分压等因素对CO₂吸附性能的影响。结果表明,配位法制得的固态胺吸附剂分散性和稳定性较好,且在TEPA负载量为40%,吸附温度为65℃,进气流量为40 mL/min时有最大CO₂吸附量达4 mmol/g。经过10次吸附-脱附循环实验后,CO₂吸附量下降3.98%。热力学、动力学研究结果表明,CO₂吸附是物理吸附和化学吸附的结果。     

Multi-layer cartridges filled with multi-walled carbon nanotubes for the determination of volatile organic compounds in indoor air.

A kind of new multi-layer adsorbent including Tenax TA/multi-walled carbon nanotubes (MWCNTs)/Carboxen 564 was developed for collecting volatile organic compounds. The adsorption and desorption efficiencies of 11 kinds of adsorbents (including Activated charcoal, Tenax TA, Carboxen 564, Chromosorb 101, Chromosorb 102, Chromosorb 103, Chromosorb 105, Porapak Q, GDX 301, XAD-2, and MWCNTs) were compared. By combining the advantages of Tenax TA, MWCNTs, and Carboxen 564, new type of multi-layer adsorbents was developed. The adsorption and desorption efficiency, the sampling reproducibility, and the effect of water were improved using multi-layer adsorbents, Tenax TA/MWCNTs/Carboxen 564. New multi-layer adsorbents were successfully applied to the determination of volatile organic compounds (VOCs) in ambient air.     

Application of a thermal desorption cold trap injector to multidimensional GC and GC-MS

The Thermal desorption Cold Trap injector (TCT) was used as a part of modified multidimensional GC (MDGC) or MDGC mass spectroscopy (MS) systems. These systems were based on a preparative GC (GC1), an analytical GC (GC2), or GC-MS and the TCT. The TCT was mounted on the GC2 or GC-MS. Analysis was carried out as follows: first, the volatile compounds heart-cut after separation on the GC1 column were adsorbed onto the Porapak Q column out of the GC1 oven. This Porapak Q column was then coupled to the TCT, and the volatile compounds adsorbed on the Porapak Q were thermally desorbed, cold trapped, and injected onto an analytical column in the GC2 or GC-MS. Repeatability of the retention time (RT) and area % of model samples consisting of citronellol, decanol, and geranyl acetate was examined. Also, the volatile compounds present at very low concentrations in ethanol solution were concentrated on the Porapak Q column. These were injected onto the analytical column by the same method as described above, and the repeatability of the RT and area % on the chromatogram was examined. In the two experiments, the standard deviation of the RT and area % for each compound was about 0.02 and less than 2.85, respectively. A commercial geranium oil was successfully analyzed by this technique. The results indicate that this modified MDGC and MDGC-MS system are very useful for detection and determination of compounds in complex mixtures.     

气相色谱法测定黑色PMMA燃烧产物中的一氧化碳和二氧化碳含量

利用气相色谱法检测黑色PMMA完全燃烧烟气中的常量二氧化碳和微量一氧化碳,建立了双气路双检测器的检测方法。恒定色谱柱温度,通过定量管进样,Poropak T色谱柱预分离后,采用阀切换及柱反吹技术使不同组分分别流入5A分子筛色谱柱和Poropak N色谱柱中。5A分子筛色谱柱用于分离一氧化碳,经Ni催化甲烷化转化后用FID检测器测定;Poropak N色谱柱分离二氧化碳后进入电导检测器测定。采用峰面积法建立标准曲线,一氧化碳和二氧化碳的线性相关系数分别为0.999 9和0.999 6。用该法测定标准气体,其测定值与标准值的相对误差小于2%,测定结果的相对标准偏差小于1%。该方法可用于烟气毒性的分析。     

聚丙烯腈微球预富集分离微柱与FAAS联用测定痕量Cd(Ⅱ)和Zn(Ⅱ)

将自制的聚合物微球填充到玻璃柱制备了2.5cm×4 mm i.d.预富集分离柱,并将其与火焰原子吸收光谱(FAAS)法联用,测定了其对Cd2和Zn2+的动态吸附,建立了测定溶液中痕量Cd2+和Zn2+的预富集分离-FAAS方法;优化了对Cd2+和Zn2+的吸附富集与洗脱条件,在室温下,溶液pH为5～6,上样和洗脱液流速...     

Optimisation of solvent desorption conditions for chemical warfare agent and simulant compounds from Porapak Q using experimental design. I. Methyl salicylate and di(propylene glycol) monomethyl ether

Factorial design (FD) was applied in order to develop an optimised method for the detection of chemical warfare (CW) agent simulant compounds on Porapak Q. Application of FD allowed study of the adsorption/desorption mechanism of analytes. Di(propylene glycol) monomethyl ether (DPM) and methyl salicylate (MS) were selected for study as both compounds are employed in agent simulation trials but are currently analysed by different methods. An analytical method for simultaneous determination of both compounds was developed using solvent desorption. The optimised method identified non-polar interactions as the primary adsorption/desorption mechanism. Steel tubes were shown to be more suited for sampling of simulants, due to lower variability in recovery compared to glass tubes. Atmospheric detection limits for both simulants were estimated to be 0.2 mg m(-3) allowing the trace analysis of these compounds by gas chromatography with flame ionisation detection (GC-FID).