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Analysis of semi-volatile organic compounds in aqueous samples by microwave-assisted headspace solid-phase microextraction coupled with gas chromatography-electron.

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Presentation on theme: "Analysis of semi-volatile organic compounds in aqueous samples by microwave-assisted headspace solid-phase microextraction coupled with gas chromatography-electron."— Presentation transcript:

1 Analysis of semi-volatile organic compounds in aqueous samples by microwave-assisted headspace solid-phase microextraction coupled with gas chromatography-electron capture detection 指導教授:徐永源博士 報告者:曾培芬 學號: M9681322 ~Journal of Chromatography A,1140(2007)35-43 Yaping Huang, Yu-Chuan Yang, Youn Yuen Shu*

2 Introduction ◆ Sample pretreatment technology ◆ Liquid-liquid extraction (LLE) ● Drawback large amount of organic solvent time consuming labor intensive ◆ Solid-phase extraction (SPE) ● Advantage small amount of solvent relatively ● Drawback plugging channeling large sample size used

3 Introduction ◆ Solid-phase microextraction (SPME) ● first developed by Pawliszyn ● solvent free ● performed in two ways: - Direct immersion (DI-SPME) - Headspace (HS-SPME) ● Compare DI-SPME : influenced by sample matrix HS-SPME : reduce matrix interference for volatile compounds long sampling time relatively

4 Introduction ◆ Sample matrix heating before HS-SPEM ● water bath (WB) - slow and inefficient ● microwave-assisted (MA) - instantaneous localized superheating

5 Introduction ◆ MA-HS-SPME ● Advantage - quick - solvent-less - temperature monitoring (equipped with infrared sensor) - very good linearity and sensitivity

6 Introduction ◆ MA-HS-SPEM coupled with GC-ECD - Analysis of semi-volatile organic compounds ◆ Experimental purpose - Comparison WB-HS-SPME and MA-HS-SPEM - The optimum conditions for obtaining extraction efficiency - Application to the real sample

7 Experimental ◆ Reagents and materials ● 1,2-Dichlorobenzene ( 1,2DCB ) ● 1,3-Dichlorobenzene ( 1,3DCB ) ● 1,4-Dichlorobenzene ( 1,4DCB ) ● 2,4-Dinitrotoluene ( 2,4DNT ) ● 2,6-Dinitrotoluene ( 2,6DNT ) ● 1,2,4-Trichlorobenzene ( 1,2,4TCB ) ● Nitrobenzene ( NB ) ● Hexachlorobenzene ( HCB ) ● Hexachloro-1,3-butadiene ( HCBD ) ◆ Internal standards: . 1,3,5-TCB . 1,2,3,4-TeCB

8 Experimental SPME fiber:65μm PDMS-DVB ( conditioned by GC injector under N 2 stream for 1 hr at 250 ℃)

9 Experimental GC-ECD -Capillary column : HP-5, 30m×0.25mm I.D×0.5μm -The column was programmed as : 65 ℃ (4min) → 5 ℃ /min to 80 ℃ (2min) → 10 ℃ /min to 120 ℃ (2min) → 10 ℃ /min to 270 ℃ (5min) -Injector port : splitless -ECD:300 ℃ -Carrier gas: N 2,flow-rate:0.7ml/min

10 Results and discussion Optimization of PDMS-DVB fiber desorption conditions in GC injection port -3min desorption time -at 250 ℃ -the fiber depth of 4.0cm -another 5 min desorption time

11 Results and discussion ◆ Optimization of MA-HS-SPEM and WB- HS-SPEM procedure ● Extraction time Extraction time ● Temperature Temperature ● Effect of sample to headspace volume ratio Effect of sample to headspace volume ratio ● Addition of sodium Addition of sodium

12 Extraction time WB-HS-SPEMMA-HS-SPEM 30min 40min Better!!

13 Temperature MA-HS-SPEMWB-HS-SPEM 2,6DNT HCB

14 Effect of sample to headspace volume ratio MA-HS-SPEMWB-HS-SPEM 20/20

15 Addition of NaCl MA-HS-SPEMWB-HS-SPEM NB 2,4-DNT 2,6-DNT NB 2,4-DNT

16 Results and discussion ◆ Comparison of MA-HS-SPME and WB-HS- SPME

17 Results and discussion ◆ Validation of the MA-HS SPEM method --Correlation coefficient greater than 0.997

18 Results and discussion ◆ Application to the real sample - sample collected from university campus and Jen-Ai river

19 Results and discussion Standard solution Artificial solution

20 Results and discussion River sample Campus sample HCDB 2,6-DNT HCB 2,4-DNT HCB 2,6-DNT HCDB 1,2,4-TBC

21 Conclusion The optimum conditions: -30W microwave power for 30min at 70 ℃ -20ml aqueous sample in 40ml headspace -no addition of sodium MA-HS-SPEM coupled with GC-EDC technique -acceptable accuracy -precision -wide-rang linearity -high sensitivity with detection limits at ng/L level in the analysis of water samples. The microwave-assisted technique -viable -better extraction efficiency than conventional heating. This method -fast, simple, low-cost, hazardous organic solvent free

22 Thanks for your listening


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