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Published bySuzan Hampton Modified over 9 years ago
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Basic Gas Chromatography
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History 1850 - Separation of dyes by Runge 1906 - Separation of plant pigments by Tswett 1941 - Theoretical gc (Martin & Synge) 1952 - First gc 1954 - TC detector
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Process Sample is vaporized (if it is not already a vapor) Passes through a column where interaction occurs - does analyte move with gas phase or stay with stationary phase (column coating) Separation occurs Detection - many types of detectors
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High purity! Source of mobile phase - He or H Detector gases - none or air/H (Flame ionization detector)
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Gas flow regulators Pressure regulators - stainless steel parts - not welding quality! Flow regulators - Determine gas flow rates through system (sensitive precision instruments)
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Injection port Introduce sample Vaporize sample Split sample (?)
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Injection ports - many versions Split - only a portion of injection goes on column Splitless - “all” material injected goes on column On-Column - cold injection (sensitive materials) Programmed temperature - sensitive materials (more durable method than OC) Large volume - Can inject 1 ml - solvent removal
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Columns Packed (hard to find) Capillary (generally open tubular but can be a wall coated PLOT type)
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Columns Generally fused silica - strong and inert Inner diameters - 0.10 - 0.53 mm Length - 1 - 60 m Coatings - several - range in thickness from 0.1 - 5 um
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Common Stationary Phase Coatings
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Phase selection PUBLISHED INFORMATION Kovats indices compilations Journal articles Internal work INTUITION like structures NO IDEA? Sample information Nonpolar column Change to polar if needed
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Separation theory 1.Adsorption 2.Molecular exclusion 3. Partition 4. Vapor pressure
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Adsorption chromatography Interaction with a granular support e.g. Tenax, charcoal, silica gel,
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Molecular exclusion Used for the separation of permanent gases e.g. Zeolites, Linde molecular sieves
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Partition chromatography Partitioning between mobile phase and carrier gas vapor pressure SEPARATION BASED ON THE BOILING PT
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Column coatings (stationary phases) Polar to nonpolar Polar - Carbowax Non Polar - silicone based phases
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Column ovens Usually heat ovens to help in separations Ovens can be controlled from about -60 - 400C
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Detectors Many types varying in sensitivity and selectivity Discuss most common types
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Thermal conductivity detector
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Characteristics of TC detector Specificity - very little - will detect almost anything including H 2 O - called the universal detector. Sensitivity to 10 -7 grams/sec - this is poor - varies with thermal condition of the compound. Linear dynamic range; 10 4 - this is poor - response easily becomes nonlinear.
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Flame ionization detector
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Characteristics of a Flame Ionization Detector (FID) Specificity - most organics. Sensitivity - 10 -12 g/sec for most organics -- this is quite good. Linear range 10 6 - 10 7 -- this is good. A special type of FID is called an alkali flame (AFID). Rubidium sulfate is burned in the flame and the detector becomes specific for N and P. Organics are not detected. Used for amines and nitrosoamines. (more commonly called the NPD)
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Electron Capture Detector
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Characteristics of an ECD Specificity - sensitive to halogens, conjugated carbonyls, nitriles, and a few others - no response with ordinary organics or H 2 O. Sensitivity 5 x 10 -14 g/sec - excellent Linear range 10 4 The radioactive detectors have definite temperature limits.
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Separation - terms
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RESOLUTION
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SELECTIVITY = relative interaction of column stationary phase with both compounds to be separated = tr’2 tr’1 CAPACITY = retention “time” of compounds to be separated k = tr - tm = tr’ tm tm THEORETICAL PLATES = column EFFICIENCY n = 5.545 (tr/Wh) 2
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Optimizing Gas Chromatography
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Key factors influencing efficiency in gas chromatography are column phase (nonpolar are most efficient) and column diameter.
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Carrier gas type and velocity
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Phase thickness: Capacity and Efficiency – influenced by column diameter and phase thickness Thick phase – capacity Thin Phase – less capacity
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Column length Longer means better separations but longer analysis times Time proportional to length Separation proportional to sq root of length Poor means of getting separation – costs too much in time. Use diameter, phase thickness or phase type
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