衍生化-手性毛细管色谱分离和测定水中的2,4-滴丙酸

建立了一种采用手性气相色谱分离、测定水中2,4-滴丙酸(DCPP)的分析方法。通过对样品的酯化处理降低了被测物的沸点,提高了其挥发性;利用手性气相色谱-ECD检测灵敏度高、量程宽的优点,实现了水中DCPP的手性分离、定量分析,平均回收率达90％。该方法安全、快速、准确,可用于水中2,4-滴丙酸和2,4-滴丙酸甲酯对映体定量分析。     

气相色谱法测定水中溴氰菊酯

采用气相色谱法-电子捕获检测器(GC- ECD)对水中溴氰菊酯进行检测.取10 mL水样,加入0.4g氯化钠,经环己烷萃取后,有机相干燥、氮吹浓缩,用带电子捕获检测器的气相色谱仪检测,外标法定量.结果表明,溴氰菊酯在2.0 ～40.0 μg/L范围内线性关系良好,相关系数为0.999 8.方法检出限为:0.40 μg/...     

气相色谱-氮磷检测法测定贝类产品中残留的三唑磷

建立了气相色谱-氮磷检测器测定贝类产品中三唑磷残留量的方法。采用HP-5毛细管色谱柱(30 m×0.25 mm×0.25 μm)分离。采用二氯甲烷提取、正己烷去脂和反萃取的方法处理样品。方法的线性范围为0.05~10 μg/L,检测限为10 μg/kg,回收率高于80%,相对标准偏差低于10%。     

固相萃取-气相色谱法测定水体中2,4-滴和灭草松的残留量

提出了固相萃取-气相色谱法测定水体中2,4-滴和灭草松残留量的方法。用硝酸将1.0 L水样酸度调至pH小于2,然后以6.0 mL·min^-1流量过活化好的HLB pro固相萃取柱，用10.0 mL水淋洗，再用10.0 mL乙酸乙酯洗脱。收集洗脱液，氮吹至近干，加入500μL N,N-二甲基甲酰胺二甲缩醛和1.0 mL正己烷，于160℃衍生50 min。衍生结束后，取出，冷却至室温，加入2.0 mL饱和氯化钠溶液，待分层后，取0.8 mL上层有机相过0.22μm有机相滤膜，滤液按照仪器工作条件进行测定。结果表明：2,4-滴和灭草松的衍生产物分别为2,4-滴甲酯和灭草松甲酯；2,4-滴和灭草松的质量浓度在0.01～0.50 mg·L^-1内与对应的衍生产物峰面积呈线性关系，检出限(3.143s)为0.003～0.010μg·L^-1;对实际加标样品进行精密度试验，测定值的相对标准偏差(n=6)均小于7.0%;生活饮用水、地表水、城镇污水和海水加标样品中，目标物回收率为81.3%～95.4%。     

高效阴离子交换色谱在易极化阴离子痕量分析中的应用

以45 mmol/L的 NaOH溶液作淋洗液,采用强亲水性的IonPac AS16阴离子交换分析柱和脉冲安培检测器,在15 min内分离检测了Br-,S2O2-3,I-和SCN-4种易极化阴离子,检测限(以3倍信噪比计)分别为0.5,0.2,0.05和2 μg/L (进样25 μL)。痕量离子的标准溶液平行9次进样测定的相对标准偏差为0.8%～3.7%。而在相同的色谱条件下,抑制型电导检测器对上述4种阴离子的检测限分别为1,1,2和10 μg/L,平行9次进样测定的相对标准偏差为0.9%～4.7%。通过实验比较可知,脉冲安培检测器的灵敏度是抑制型电导检测器的2～40倍。在测定上述易极化阴离子时,脉冲安培检测器具有选择性强、精密度好和灵敏度高等优点。     

气相色谱-微池电子捕获检测法同时检测饮用水中多种有机污染物

本文建立了气相色谱-微池电子捕获检测法(GC-μECD),同时测定生活饮用水中百菌清、七氯、滴滴涕、六六六、林丹、六氯丁二烯、溴氰菊酯、1,1-二-氯苯、1,2-二氯苯、三氯苯、六氯苯11种有机氯,马拉硫磷、对硫磷、甲基对硫磷、毒死蜱、乐果、敌敌畏6种有机磷,以及硝基苯、2,4,6-三硝基甲苯、1,3-二硝基苯、邻,间,对硝基氯苯、2,4-二硝基氯苯,2,4-二硝基甲苯6种硝基苯类有机物的分析方法.样品经萃取后,采用OV-1701色谱柱(30 m×0.25 mm×0.25μtm)程序升温进行分离,用微池电子捕获检测器(μECD)进行检测,通过保留时间定性,外标法定量.结果表明该方法分离效果好,灵敏度高,选择性强,简便、快速、准确,能够满足同时测定生活饮用水中上述23种有机化合物的需要.     

SDE-GC-μEGD分析水中挥发性卤代烃

运用微滴溶剂萃取-气相色谱-微池电子捕获检测器联用技术(SDE-GC-μECD)对水中挥发性卤代烃(vHH)的分析进行了可行性探讨,优化了微滴溶剂萃取技术的多种影响因素.方法在0.1～20μg/L之间呈线性,相关系数为0.999 1～0.999 8,相对标准偏差在1.2%～4.6%之间,加标回收率在83%～117%之间.该方法所用的有机溶剂很少(1～2 μL),装置简便,是值得推广的绿色环保、高效的前处理方法.     

全二维气相色谱-电子捕获检测器法分析土壤中毒杀芬同类物的残留

建立了全二维气相色谱-电子捕获检测器(GC× GC-μECD)检测土壤中毒杀芬同类物的分析方法.以非极性的DB- XLB(20 m×0.25 mm×0.25 μm)为第一色谱柱,中等极性的BPX-50(2 m×0.1 mm×0.1 μm)为第二色谱柱,对土壤中23种高关注毒杀芬同类物进行了分离鉴定,并采用基质曲线外标法进行定量分析.本方法在1～200,μg/L浓度范围内,毒杀芬同类物的线性相关系数(r2)均大于0.99,方法检出限(S/N=3)为0.039～0.482 μg/L,基质加标毒杀芬同类物的回收率为55％～115％,相对标准偏差(RSD)均小于30％(n=5).利用本方法对毒杀芬污染的土壤样品进行了测定,获得了较好的分离效果.     

气相色谱-电子捕获检测法测定食品包装材料中2,4-二氨基甲苯

建立了食品包装复合材料中2,4-二氨基甲苯的气相色谱-电子捕获检测(GCECD)方法。分析条件为:HP-5毛细管气相色谱柱(30m×0.32mm×0.25μm);载气流速0.8mL/min;进样口温度为260℃,分流比为5∶1;ECD检测器温度:300℃;柱温:170℃;进样量:1μL。2,4-二氨基甲苯浓度在0.02~1mg/L范围内与色谱峰面积线性良好,相关系数为0.9991,方法检出限(S/N=3)为0.001mg/L。     

大口径毛细管气相色谱柱测定茶叶中三氯杀螨醇的残留量

 报道了用大口径毛细管气相色谱柱测定茶叶中三氯 杀螨醇残留量的方法。用体积分数为20%的丙酮-正己烷提取茶样中的三氯杀螨醇,采用微 量化前处理方法,经弗罗里硅土-酸性硅藻土混合柱净化后,与氢氧化钾溶液进行碱解,以 大口径毛细管柱分离,艾氏剂为内标,电子捕获检测器(ECD)测定。经过对绿茶、红茶的添 加回收试验,平均回收率为94%,变异系数小于7.49%,检测低限为0.5 μg/kg。     

Stability of low levels of perchlorate in drinking water and natural water samples

Perchlorate ion (ClO₄⁻) is an environmental contaminant of growing concern due to its potential human health effects, impact on aquatic and land animals, and widespread occurrence throughout the United States. The determination of perchlorate cannot normally be carried out in the field. As such, water samples for perchlorate analysis are often shipped to a central laboratory, where they may be stored for a significant period before analysis. The stability of perchlorate ion in various types of commonly encountered water samples has not been generally examined—the effect of such storage is thus not known. In the present study, the long-term stability of perchlorate ion in deionized water, tap water, ground water, and surface water was examined. Sample sets containing approximately 1000, 100, 1.0, and 0.5 μg l⁻¹ perchlorate ion in deionized water and also in local tap water were formulated. These samples were analyzed by ion chromatography for perchlorate ion concentration against freshly prepared standards every 24 h for the first 7 days, biweekly for the next 4 weeks, and periodically after that for a total of 400 or 610 days for the two lowest concentrations and a total of 428 or 638 days for the high concentrations. Ground and surface water samples containing perchlorate were collected, held and analyzed for perchlorate concentration periodically over at least 360 days. All samples except for the surface water samples were found to be stable for the duration of the study, allowing for holding times of at least 300 days for ground water samples and at least 90 days for surface water samples.     

Sorption and transport of water in nylon-6 films

Sorption and transport properties of water through films of Nylon-6 were obtained at 5, 23, and 40°C. Commercially available films were used and a Cahn electrobalance was employed for measuring the water uptake by the polymer samples. Values of the water sorption isotherms are accurately described by the Langmuir/Flory-Huggins dual-mode sorption model. At water activity values below 0.15, the volume fraction of water described by the Langmuir portion of the model was greater than the Flory-Huggins population. Solubility and diffusion coefficients of water, as well as the diffusion activation energy and enthalpy of dissolution of water for Nylon-6, were determined from the sorption experiments. Values obtained support the hypothesis of a bimodal water sorption mode, and the formation of water clusters. © 1994 John Wiley & Sons, Inc.     

离子色谱-质谱联用技术测定饮用水及环境水样中的痕量高氯酸盐

建立了一种测定痕量高氯酸盐的离子色谱-质谱联用方法.选用高容量、强亲水性的阴离子交换柱IonPac AS20(2 mm)进行分离,以淋洗液自动发生器在线产生的KOH为淋洗液,采用等浓度淋洗.在不添加有机溶剂的情况下,淋洗液经过抑制器抑制后直接进入电喷雾-串联质谱(ESI-MS-MS),以负离子模式进行检测.同时采用多元反应监测(MRM)模式对高氯酸盐进行监控,以100.8/84.9、 98.8/66.9和100.8/68.9为监控离子对,以98.8/82.9离子对的峰面积进行定量.高氯酸盐质量浓度在0.05～50 μg/L范围内具有良好的线性(r＝0.9985),检出限(S/N=3)为0.01 μg/L.将该方法用于饮用水以及地下水、雪水等环境水样中高氯酸盐的分析,并进行了加标回收实验,回收率在86%～110%之间,将实际自来水样品连续11次进样,所得高氯酸盐的峰面积的相对标准偏差(RSD)为1.6%.     

Thermal analysis study on water freezing and supercooling

Water freezing and supercooling were experimentally studied by methods of thermal analysis in a water droplet of 5 mm in diameter depending on various temperatures and times of overheating and cooling rates. Degree of water supercooling was influenced by previous thermal treatment but only to a certain extent. It increased slightly with overheating temperature and time and decreased with cooling rate. Maximum found values of supercooling ranged between 12 and 13 K. Small degrees of supercooling and their changes indicate that water freezing was more controlled by heterogeneous nucleation (properties of container contact surface) than by previous thermal treatment and experimental conditions.     

Non-freezing water in protein solutions

Differential scanning calorimetric studies of protein solution provided the freezable water content as a function of concentration. Total water content was obtained by vacuum dehydration. The difference between the two gave the non-freezing water content in protein solutions. The values obtained by these techniques were 2–3 times larger than those obtained on the basis of NMR measurements on the same solutions.     

聚合氯化铝的制备及在微污染水处理中的应用

用酸溶法制备聚合氯化铝,对合成产品进行红外光谱分析,并应用于微污染原水的处理。处理微污染原水结果表明:当投加量为40.0 mg/L,pH值为6.0～9.0时,剩余浊度达到1.0NTU以下,总有机碳(Total Or-ganic Carbon,TOC)去除率达到41.2%。对比试验结果表明自制的聚合氯化铝的除浊效果优于一些常见工业聚合氯化铝。     

Degradation of benzoic acid and its derivatives in subcritical water

In this research, the stability of benzoic acid and three of its derivatives (anthranilic acid, salicylic acid, and syringic acid) under subcritical water conditions was investigated. The stability studies were carried out at temperatures ranging from 50 to 350 °C with heating times of 10–630 min. The degradation of the benzoic acid derivatives increased with rising temperature and the acids became less stable with longer heating time. The three benzoic acid derivatives showed very mild degradation at 150 °C. Severe degradation of benzoic acid derivatives was observed at 200 °C while their complete degradation occurred at 250 °C. However, benzoic acid remained stable at temperatures up to 300 °C. The degradation products of benzoic acid and the three derivatives were identified and quantified by HPLC and confirmed by GC/MS. Anthranilic acid, salicylic acid, syringic acid, and benzoic acid in high-temperature water underwent decarboxylation to form aniline, phenol, syringol, and benzene, respectively.     

17O-核磁共振法研究不同处理方法对液态水缔合结构的影响

水作为人类重要的生产要素,参与了卷烟生产的多个环节。水在自然条件下以分子簇的形式存在,多种处理方式可以改变水分子团簇的大小。本文以¹⁷O-核磁共振法为水分子团簇的表征手段,以自来水为水源,考察了氢气、远红外辐射陶瓷球、反渗透、磁场四种处理方法对水分子簇的影响。结果表明:四种处理方式均能使一定量水分子由氢键结合态变为自由态,从而使水分子簇变小。不同处理方法对液态水缔合结构的影响大小排序为氢气处理>远红外陶瓷球处理>反渗透处理>磁场处理。同时,对氢气处理效果的时效性进行了考察,随着放置时间增加,部分自由态水分子再次转变为氢键结合态,水分子簇尺寸变大,但三天后仍保留了一定处理效果。本研究表明氢气处理为四种处理方式中最优的水处理方式,具有提升烟草行业生产用水品质的潜在应用价值。     

A model study on the mechanism and kinetics for the dissociation of water anion

Quantum chemical computations using both density functional theory (B3LYP functional) and wavefunction (MP2 and CCSD(T)) methods, with the 6-311++G(3df,2p) and aug-cc-pVnZ (n = D,T,Q) basis sets, in conjunction with a polarizable continuum model (PCM) method for treating structures in solution, were carried out to look again at a series of small negatively charged water species [(H₂O)_n]^•–. For each size n of [(H₂O)_n]^•– in aqueous solution with n = 2, 3, and 4, two distinct structural motifs can be identified: a classical water radical anion formed by hydrogen bonds and a molecular pincer in which the excess electron is directly interacting with H atoms. In aqueous solution, both motifs have comparable energy content and likely coexist and compete for the ground state. Some water anion isomers can dissociate when interaction with a water molecule, [(H₂O)_n]^•– + H₂O → H^•(H₂O)_m + OH^–(H₂O)_n–m, through successive hydrogen transfers with moderate energy barriers. This reaction can also be regarded as a water-splitting process in which the H transfers involved take place mainly within a water trimer, whereas other water molecules tend to stabilize transition structures through microsolvation rather than direct participation. Calculated absolute rate constants for the reversed reaction H^•(H₂O)₂ + OH^–(H₂O)₂ → [(H₂O)₄]^•־ + H₂O with both H and D isotopes agree well with the experimentally evaluated counterpart and lend a kinetic support for the involvement of a tetramer unit.