Coupling of high-performance liquid chromatography with capillary gas chromatography
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Cited by 118 publications
References 9 publications
The article contains sections titled: 1. Introduction 1.1. A Strategy Appropriate to Trace Analysis 1.2. Avoidance of Systematic Errors 1.2.1. Trace Losses and Contamination 1.2.2. Uncertainty 2. Sample Preparation and Digestion in Inorganic Analysis 2.1. Sample Treatment after the Sampling Process 2.1.1. Stabilization, Drying, and Storage 2.1.2. Homogenization and Aliquoting 2.1.3. Requirements with Respect to Materials and Chemicals 2.2. Sample‐Preparation Techniques; General Considerations 2.2.1. Special Factors Associated with Microwave‐Assisted Digestion 2.2.2. Safety Considerations 2.3. Wet Digestion Techniques 2.3.1. Wet Digestion at Atmospheric Pressure 2.3.2. Pressure Digestion 2.3.2.1. Thermally Convective Pressure Digestion 2.3.2.2. Microwave‐Assisted Pressure Digestion 2.4. “Dry” Digestion Techniques 2.4.1. Combustion in Air 2.4.2. Combustion in Oxygen 2.4.3. Cold‐Plasma Ashing 2.4.4. Fusion 2.5. Illustrative Examples 2.5.1. Sample Preparation as a Function of Analytical Method 2.5.2. Combined Use of Multiple Decomposition Techniques 2.5.3. Comparative Merits of the Various Sample‐Preparation Techniques 2.5.4. Decomposition Procedures for Determining Nonmetals 2.6. Evaluation Criteria 2.6.1. Completeness 2.6.2. Uncertainty 2.6.3. Time Factors 2.6.4. The Final Result 2.7. Concentration and Separation of Inorganic Trace Materials 2.8. Automation and Direct Analysis 2.8.1. Automation 2.8.2. Direct Analysis 2.9. Analysis of Element Species 3. Sample Preparation in Organic Analysis 3.1. Sample Treatment after the Sampling Process 3.1.1. Stabilization, Drying, and Storage 3.1.2. Homogenization and Aliquoting 3.1.3. Requirements with Respect to Materials and Chemicals 3.2. Separation of the Analyte 3.2.1. Hydrolysis 3.2.2. Liquid ‐ Liquid Extraction 3.2.3. Soxhlet Extraction 3.2.4. Microwave‐Assisted Solvent Extraction 3.2.5. Supercritical Fluid Extraction (SFE) 3.2.6. Solid‐Phase Extraction (SPE) 3.2.7. Solid‐Phase Microextraction (SPME) 3.2.8. Stir‐Bar Adsorptive Extraction (SBSE) 3.2.9. Miscellaneous Techniques 3.3. Headspace Techniques 3.3.1. Static Headspace Technique 3.3.2. Dynamic Headspace Technique (Purge and Trap) 3.4. Determination of Trace Organic Materials in Air Samples 3.5. Analyte Concentration 3.6. Derivatization 3.7. Coupled Techniques Trace analysis is a very relevant and applications‐oriented branch of analytical chemistry. The sample preparation for trace analysis must be custom‐tailored to the problem at hand. Systematic errors can arise by contact with vessel materials, reagents, or the ambient atmosphere, as well as any change in chemical or physical state. In inorganic analysis, sample preparation has to meet the requirements for a substantially trouble‐free determination of the analyte. Digestion of the matrix (microwave digestion, wet digestion, dry digestion techniques) and subsequent careful comparison of several decomposition techniques is therefore an essentially important step. Some separation and concentration techniques of the analytes are liquid –liquid extraction, solid‐phase extraction, special precipitation reactions, and electrolytic deposition. The introduction of laboratory robots should make it possible to incorporate a significant degree of automation into the time‐consuming, labor‐intensive area of sample preparation as well, leading to more efficient, reliable, and reproducible sample work‐up. The goal of sample preparation in organic trace analysis is to isolate the analyte from the sample matrix (e.g., liquid‐liquid extraction, Soxhlet extraction, microwave‐assisted solvent extraction, steam distillation) and then concentrate it and convert it into a form suitable for analysis by the selected method. Separation and concentration of an analyte must often be followed by some type of derivatization. Various coupled sample preparation and determination processes are increasingly utilized in trace organic analysis.
The article contains sections titled: 1. Introduction 1.1. A Strategy Appropriate to Trace Analysis 1.2. Avoidance of Systematic Errors 1.2.1. Trace Losses and Contamination 1.2.2. Uncertainty 2. Sample Preparation and Digestion in Inorganic Analysis 2.1. Sample Treatment after the Sampling Process 2.1.1. Stabilization, Drying, and Storage 2.1.2. Homogenization and Aliquoting 2.1.3. Requirements with Respect to Materials and Chemicals 2.2. Sample‐Preparation Techniques; General Considerations 2.2.1. Special Factors Associated with Microwave‐Assisted Digestion 2.2.2. Safety Considerations 2.3. Wet Digestion Techniques 2.3.1. Wet Digestion at Atmospheric Pressure 2.3.2. Pressure Digestion 2.3.2.1. Thermally Convective Pressure Digestion 2.3.2.2. Microwave‐Assisted Pressure Digestion 2.4. “Dry” Digestion Techniques 2.4.1. Combustion in Air 2.4.2. Combustion in Oxygen 2.4.3. Cold‐Plasma Ashing 2.4.4. Fusion 2.5. Illustrative Examples 2.5.1. Sample Preparation as a Function of Analytical Method 2.5.2. Combined Use of Multiple Decomposition Techniques 2.5.3. Comparative Merits of the Various Sample‐Preparation Techniques 2.5.4. Decomposition Procedures for Determining Nonmetals 2.6. Evaluation Criteria 2.6.1. Completeness 2.6.2. Uncertainty 2.6.3. Time Factors 2.6.4. The Final Result 2.7. Concentration and Separation of Inorganic Trace Materials 2.8. Automation and Direct Analysis 2.8.1. Automation 2.8.2. Direct Analysis 2.9. Analysis of Element Species 3. Sample Preparation in Organic Analysis 3.1. Sample Treatment after the Sampling Process 3.1.1. Stabilization, Drying, and Storage 3.1.2. Homogenization and Aliquoting 3.1.3. Requirements with Respect to Materials and Chemicals 3.2. Separation of the Analyte 3.2.1. Hydrolysis 3.2.2. Liquid ‐ Liquid Extraction 3.2.3. Soxhlet Extraction 3.2.4. Microwave‐Assisted Solvent Extraction 3.2.5. Supercritical Fluid Extraction (SFE) 3.2.6. Solid‐Phase Extraction (SPE) 3.2.7. Solid‐Phase Microextraction (SPME) 3.2.8. Stir‐Bar Adsorptive Extraction (SBSE) 3.2.9. Miscellaneous Techniques 3.3. Headspace Techniques 3.3.1. Static Headspace Technique 3.3.2. Dynamic Headspace Technique (Purge and Trap) 3.4. Determination of Trace Organic Materials in Air Samples 3.5. Analyte Concentration 3.6. Derivatization 3.7. Coupled Techniques Trace analysis is a very relevant and applications‐oriented branch of analytical chemistry. The sample preparation for trace analysis must be custom‐tailored to the problem at hand. Systematic errors can arise by contact with vessel materials, reagents, or the ambient atmosphere, as well as any change in chemical or physical state. In inorganic analysis, sample preparation has to meet the requirements for a substantially trouble‐free determination of the analyte. Digestion of the matrix (microwave digestion, wet digestion, dry digestion techniques) and subsequent careful comparison of several decomposition techniques is therefore an essentially important step. Some separation and concentration techniques of the analytes are liquid –liquid extraction, solid‐phase extraction, special precipitation reactions, and electrolytic deposition. The introduction of laboratory robots should make it possible to incorporate a significant degree of automation into the time‐consuming, labor‐intensive area of sample preparation as well, leading to more efficient, reliable, and reproducible sample work‐up. The goal of sample preparation in organic trace analysis is to isolate the analyte from the sample matrix (e.g., liquid‐liquid extraction, Soxhlet extraction, microwave‐assisted solvent extraction, steam distillation) and then concentrate it and convert it into a form suitable for analysis by the selected method. Separation and concentration of an analyte must often be followed by some type of derivatization. Various coupled sample preparation and determination processes are increasingly utilized in trace organic analysis.
Trace analysis of halocarbons in water; Direct aqueous injection with electron capture detection
Key Words:Gas chromatography Capillary, glass ECD Halocarbons in water, 0.1 -10 ppb 0.5-2 pI injected on-column SummaryInterest in monitoring halogenated organics in drinking water and natural surface and ground water in the low ppb range continues to grow. There is a tendency to include still more volatile halocarbons, the trace determination of which is known to be rather demanding. This prompted us to re-examine the feasibility of large-volume direct aqueous injection onto capillary columns, coupled with ECD. A primary problem was to avoid simultaneous elution of water with halocarbons, since water suppresses the ground current of the ECD. The following measures contributed to the solution of this problem. Apolar, extremely inert, columns are required to elute water completely, and even before very light halocarbons. Their coatings have to be far thicker (=5 pm) than commonly employed thick films since they must permit isothermal analysis at a column temperature around 100°C in order to ensure rapid and complete elution of water. Finally, it is essential that sampling be carried out on-column for two reasons: diffusion of water vapor in the injector, resulting in delayed elution, is then eliminated, and peak distortion during splitless injection is avoided.Although we now know that persilylated columns with immobilized coatings withstand routine water injections, more longterm experience is needed to provide detailed recommendations for the handling of these columns.
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