固相萃取-高效液相色谱法测定地下水中多环芳烃的技术研究

建立了固相萃取结合高效液相法测定地下水中的15种多环芳烃.采用CLEAN-UP C18固相萃取小柱富集水样,系统考察了样品的流速和洗脱剂的强度、用量、有机改性剂加入的量以及氮气浓缩条件对测定的影响.15种多环芳烃的方法检出限为1～14ng/L,加标回收率在73.4%～105%之间.本实验方法简便快速、稳定可靠,适用于地下水中15种多环芳烃的测定.     

固相膜萃取-高效液相色谱法测定地下水中的多环芳烃

采用C18固相膜萃取对地下水中15种多环芳烃进行富集净化,以二氯甲烷作洗脱溶剂,高效液相色谱法,荧光检测器测定。对萃取、浓缩和色谱条件进行优化,在1．ooixg／L～40．0μg／L范围内测定标准系列溶液并绘制标准曲线,相关系数R2〉0．999;15种多环芳烃的仪器检出限为0．4ng／L～3．0ng／L;对地下水样品加标,平均回收率在75．7％～96．7％之间;标准溶液平行测定7次的RSD为3．1％～11．9％。     

多氯联苯Aroclor系列的弗罗里硅土小柱淋洗条件

使用商品化弗罗里硅土小柱对废水中的Aroclor进行净化。比较了不同极性洗脱溶剂和洗脱体积下弗罗里硅土小柱的净化效果。采用1 g/6 mL的弗罗里硅土小柱净化时,洗脱液体积大于8.0 mL,洗脱完全,未有目标物质被检出。淋洗溶剂的极性改变,对初始洗脱体积（0~3.0 mL）的洗脱效率会产生一定影响。随着极性的增加,目标物的回收率随之增加,但是共流出的干扰物也随之增加。     

土壤和沉积物中多氯联苯单体测定的净化方法研究

对浓硫酸净化、铜粉脱硫、氟罗里硅土柱、硅胶柱、石墨碳柱等净化方法在土壤和沉积物多氮联苯单体测定中的应用进行了研究.浓硫酸对多氯联苯单体的净化回收率达92.4％～109％;氟罗里硅土柱用正己烷/丙酮混合溶液淋洗,净化洗脱液体积为8 mL～10 mL时,回收率达85.7％ ～ 108％;硅胶柱用正己烷淋洗,净化洗脱液体积为...     

微波萃取-气质联用测定土壤中的16种多环芳烃

用丙酮-正己烷(1:1体积比)混合溶剂,通过微波萃取法提取土壤中的16种多环芳烃组分。萃取溶液经硅胶小柱净化,最后用气相色谱-质谱法分析。以石英砂为基体进行加标回收测定。16种多环芳烃的检测限为0.18～0.53μg/kg,经精密度试验,相对标准偏差均5%,回收率在75.5%～108%之间。     

有机氯农药和多氯联苯测定的样品净化方法

介绍了多氯联苯和有机氯农药环境样品的弗罗里硅土小柱、浓硫酸的分离、净化方法。经实际样品测定检验该方法,测定结果可靠。     

青岛市松针中多环芳烃污染状况研究

松针、苔藓类等植物可有效的监测环境空气中多环芳烃等有机污染物。为了解青岛市松针中多环芳烃的污染状况,本文使用索氏提取、氧化铝-硅胶净化柱净化、气相色谱-质谱（GC-MS）分析的方法,研究了青岛市6个不同区域的松针中多环芳烃的含量。该方法的提取净化效率在70．8％以上。在6个采样点中,1号采样点松针中的多环芳烃含量最低,平均为7．54ng/g（湿重含量）,5号和6号采样点最高,分别为41．0ng/g和39．6ng/g。多环芳烃浓度季节变化规律为春季〉冬季〉夏季;松针中三、四环多环芳烃占总量的82％～90％,苯并（a）芘与多环芳烃总量具有较好的相关性。     

加速溶剂萃取-高效液相色谱法测定土壤中16种多环芳烃

研究了土壤中的16种多环芳烃的提取和测定方法.结果表明,用加速溶剂提取仪在100℃,二氯甲烷和丙酮(1:1)提取5min,再经硅胶柱净化,正己烷和二氯甲烷(3:2)洗脱,25℃氮吹浓缩后用高效液相色谱测定可以得到很好的效果,方法回收率在58%～106%之间,检测限为1.4×10-4～3.6×10-2mg/kg,且重现性好.     

气相色谱法测定土壤和沉积物中12种有机磷农药

建立了索氏提取-固相萃取（SPE）小柱净化-GC-NPD测定土壤和沉积物中的12种有机磷农药的方法。用正己烷-丙酮（9：1）进行索氏提取,SPE硅胶小柱净化,15 mL乙酸乙酯洗脱。适用于土壤和沉积物的干样和湿样中12种有机磷农药的测定,取样量为10 g时,方法检出限为0.304~1.469 μg/kg,样品加标平均回收率为67.10%~109.8%,相对标准偏差为3.39%~14.7%。     

加压流体萃取-气相色谱法测定土壤中酞酸酯类化合物

建立了土壤中15种酞酸酯的加压流体萃取-弗罗里硅土柱净化-气相色谱测定方法。就萃取条件探讨了溶剂、温度、时间和循环次数对萃取效率的影响,就净化条件探讨了净化柱和洗脱溶剂对萃取效率的影响。根据研究结果,确定萃取条件以二氯甲烷为萃取溶剂,在萃取温度120℃、压强1 500 psi时,预热5 min,静态提取5 min,循环萃取2次,用体积为60%萃取池体积的萃取溶剂冲洗萃取池,之后用氮气吹扫萃取池90 s;净化条件为萃取溶液过弗罗里硅土固相萃取柱净化后,以正己烷∶丙酮(体积比为5∶1)洗脱。15种酞酸酯类化合物加标回收率为67.1%~124%,方法检出限为0.017~0.048 mg/kg。     

气相色谱-质谱法测定废酸油渣中的16种多环芳烃

建立了废酸油渣中16种多环芳烃超声萃取、Florisil萃取柱净化、气相色谱-质谱测定的方法。笔者对提取方式、提取剂类型和体积、提取时间和次数、净化方式等进行研究,采用无水硫酸钠分散,二氯甲烷作为提取剂超声40 min,提取液经纯水清洗、离心后取适量有机相经过3 g Florisil萃取柱净化,采用气相色谱-质谱选择离子模式(SIM),加入内标进行定量分析。结果表明:二氯甲烷提取效率比正己烷好,丙酮可能引起酸性样品中多环芳烃的降解,丙酮超声萃取时加入无水硫酸钠能在一定程度上防止目标物降解,但萃取效率不可控制,宜采用二氯甲烷作为萃取剂。分散提取能有效减少提取时间,超声清洗仪超声40 min提取效率为86.2%～104%。3g Florisil萃取柱净化比1 g Florisil萃取柱净化和GPC净化效果略好。方法检出限为0.4～1.3 mg/kg,6次空白加标的相对标准偏差为2.3%～15.3%,6个实际样品测定结果的相对标准偏差为1.2%～27.3%,基体加标回收率为51.3%～126%,连续校准稳定。该方法适用于废酸油渣样品中16种多环芳烃的检测,比直接溶解有效,比加速溶剂萃取、索氏提取、微波萃取和超声探头萃取简单、快捷,能有效减少设备污染和腐蚀,净化方法有效,测定结果准确可靠,是实现大批量样品检测的可行方法。     

加速溶剂同时萃取和净化-气相色谱-三重四极杆串联质谱测定土壤和沉积物中8种多溴联苯醚

建立了土壤和沉积物中8种多溴联苯醚(PBDEs,BDE-28、BDE-47、BDE-99、BDE-100、BDE-153、BDE-154、BDE-183和BDE-209)加速溶剂同时萃取和净化-气相色谱-三重四极杆串联质谱(ASE-GC-MS-MS)的分析方法。通过优化加速溶剂萃取与弗罗里硅土在线净化和串联质谱多反应监测模式的条件,较好地去除基质干扰,并提高了三重四极杆串联质谱定性的准确性及定量的灵敏性。该方法采用改进的色谱柱能同时分析包括高溴代联苯醚BDE-209在内的8种PBDEs,其浓度范围为1～100 ng/mL(BDE-209为10～1 000 ng/mL),线性良好,线性回归系数均大于0.997。方法检出限为0.004～0.1 ng/g,方法回收率为75%～110%,方法精密度为2.4%～15.6%。适于批量处理土壤和沉积物中含有多组分痕量PBDEs的样品。     

超声波萃取-GC/MS法测定土壤中多氯联苯

建立了超声波萃取、氟罗里硅土柱净化、气相色谱/质谱联用选择离子扫描模式测定土壤样品中多氯联苯Arochlor系列的方法.方法线性良好,灵敏度高,RSD为9.5%～12.2%,加标回收率为65.0%～105%,标准土壤样品的测定结果也符合要求.     

底质农残测定中固相柱净化体系的选择

使用固相柱对底质中的7种农残进行净化。结果表明,在相同淋洗条件下,使用氟罗里硅土柱比硅胶柱净化效果好。比较了不同溶剂体系、不同溶剂配比下2种萃取柱的净化效果,选择乙醚-正己烷(体积比1∶2)或丙酮-正己烷(体积比1∶4)作为净化溶剂,较小的收集体积都可满足所有目标化合物的回收率要求;相比较而言,丙酮-正己烷(体积比1∶4)作为净化溶剂,洗脱液的杂质干扰更小,净化效果更好。使用氟罗里硅土柱和丙酮-正己烷(体积比1∶4)对样品净化,方法简单,快速,净化效果好,适合大批量底质样品的前处理净化过程。     

Simultaneous determination of malachite green, enrofloxacin and ciprofloxacin in fish farming water and fish feed by liquid chromatography with solid-phase extraction

An effective and sensitive method for simultaneous analysis of malachite green (MG), enrofloxacin (ENFLX) and ciprofloxacin (CPFLX) by liquid chromatography-diode array detection with solid-phase extraction (SPE) is developed. The conditions of SPE and LC were investigated and optimised. The effective separation of these compounds was achieved using a ZY1104 C18 column (250 × 4.6 mm, 5 μm) with 20 mM tetrabutyl ammonium bromide (pH 3.0)-acetonitrile as mobile phase and gradient elution. The diode array detection was used at 278 nm for ENFLX and CPFLX and at 613 nm for MG. Under the optimal conditions, the method LOD values of MG, ENFLX and CPFLX were 0.01, 0.07 and 0.10 μg L(?-1) for fish farming water samples and 1.5, 10.5 and 15 μg kg(?-1) for fish feed samples, respectively. The relative recoveries of the three analytes were achieved to be 76.7-82.3% with the RSDs (n = 5) of 3.2-4.6% for spiked fish farming water samples and 78.8-93.7% with the RSDs (n = 5) of 3.1-4.8% for spiked fish feed samples.     

超高效液相色谱-串联质谱法测定水中痕量双酚A

采用超高效液相色谱-串联质谱法测定水中痕量双酚A,水样经预处理后,以BEH C18超高效液相色谱柱分离,在质谱电喷雾离子源负离子多反应监测模式下测定.方法在0.200μg/L～10.0μg/L范围内线性良好,相关系数r为0.9992,方法检出限为0.06μg/L,空白及实际样品加标回收率为87.4% ～114%,RSD为3.6% ～7.4%.     

Polychlorobiphenyls and polycyclic aromatic hydrocarbons in the sea-surface micro-layer and the water column at Gerlache Inlet, Antarctica

The enrichment of PCBs (polychlorobiphenyls) and PAHs (polycyclic aromatic hydrocarbons) in the sea-surface micro-layer and depth profile of these pollutants in the water column were investigated at Gerlache Inlet, Terra Nova Bay, Antarctica. Depth profile samplings were repeated three times during the Antarctic summer (from November to February). PCBs and PAHs showed a concentration range in the water column of 30-120 pg l(-1) and 150-400 pg l(-1), respectively, and these values were very much dependent on the suspended matter content. A nearly two-fold decrease in the pollutant concentration was also observed in the depth profile obtained in February, i.e. late summer, which might be correlated both with the high content of suspended matter and the reduction of the pollutant input. Moreover, isomer ratios of PAHs, such as LMW/HMW and PHE/ANT, highlight that the main PAH source might be petrogenic in nature, whereas the pyrolytic source seems to be less important. Sea surface micro-layer (SML) and sub-surface sea water (SSW) samples were simultaneously collected in the same site by a remote controlled rotating drum-based sampling system, a prototype named MUMS (Multi-User Micro-layer Sampler). Sea surface micro-layer samples showed a total content of PCBs and PAHs in the range 400-450 pg l(-1) and 2000-3000 pg l(-1), respectively, whereas the mean content of the sub-surface sea water samples was 48 pg l(-1) and 325 pg l(-1), respectively. The mean enrichment factors of PCBs and PAHs in sea-surface micro-layer were about 10 and 7, respectively. The surface excess concentrations of PCBs and PAHs were about 35 000 and 200 000, respectively. A fairly good correlation was observed between the concentration of pollutants and water solubility. Based on the assumption that POPs are confined in a very thin top layer of the SML about 0.01-0.001 microm thick, namely the sea-surface nano-layer, and also on an estimated thickness of the sampled sea-surface layer of about 100 microm, an enrichment factor of 10(5)-10(6) for the sea-surface nano-layer was calculated. Such a very high concentration increase was related to the two-fold increase of PAH concentration observed in the underlying 20 cm of the water column in late summer.     

高效液相色谱-串联质谱法同时测定地表水中33种药物

采用固相萃取-高效液相色谱-串联质谱法(SPE-HPLC-MS/MS)建立了地表水中25种抗生素类药物和8种非抗生素类药物的分析方法。通过重点优化质谱参数、色谱条件、样品pH、洗脱溶剂组成及用量等确定了最佳分析条件。水样经过滤、固相萃取柱富集净化后,选择Shim-pack XR-ODS为色谱柱,以乙腈和0.2%甲酸-2 mmol/L乙酸铵-水溶液为流动相进行梯度洗脱,采用电喷雾电离源,在多反应监测模式下(MRM)分析测定,内标法定量。33种药物的仪器定量限为0.012～4.68 ng/L,方法检出限为0.011～7.60 ng/L,地表水加标回收率为53.7%～122%,相对标准偏差为1.22%～32.1%(n=6)。方法成功应用于北京市凉水河12个地表水样分析,共检出32种药物,检出质量浓度为未检出～239 ng/L。利托那韦(RTV)作为新型冠状病毒诊疗方案中推荐的药物在凉水河检出率为100%。     

Study on determination of iron,cobalt, nickel,copper, zinc and manganese in drinking water by solid-phase extraction and RP-HPLC with 2-(2-quinolinylazo)-5-diethylaminophenol as precolumn derivatizing reagent

A new method for the determination of iron, cobalt, nickel, copper, zinc and manganese in drinking water by the reversed-phase high-performance liquid chromatography (RP-HPLC) with 2-(2-quinolinylazo)-5-diethylaminophenol (QADEAP) as precolumn derivatizing reagent was studied in this paper. The iron, cobalt, nickel, copper, zinc, and manganese ions react with QADEAP to form color chelates in the presence of cetyl trimethylammonium bromide (CTMAB) and acetic acid-sodium acetic buffer solution medium of pH 4.0. These chelates were enriched by solid-phase extraction with a Waters Nova-Pak C18 cartridge and eluted the retained chelates from the cartridge with tetrahydrofuran (THF). The enrichment factor of 100 was achieved. Then the chelates were separated on a Waters Nova-Pak C18 column (3.9 x 150 mm, 5 microm) by gradient elution with methanol (containing 0.2% of acetic acid and 0.1% of CTMAB) and 0.05 mol L(-1) acetic acid-sodium acetic buffer solution (containing 0.1% of CTMAB) (pH 4.0) as mobile phase at a flow rate of 0.5 ml min(-1), and monitored with a photodiode array detector from 450 approximately 700 nm. The detection limits (S/N = 3) of iron, cobalt, nickel, copper, zinc and manganese are 0.8, 1.1, 0.9, 1.1, 1.5 and 2.0 ng L(-1), respectively, in the original sample. This method can be applied to determination at the microg L(-1) level of iron, cobalt, nickel, copper, zinc and manganese in drinking water with good results.