basic gas chroma

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Adrienne Paclipan

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Chromatography is a physical method of separation that distributes components in a mixture between two phases which moves in a definite direction
Chromatography 
Based on the principle of partition of solutes in a mixture between two phases
Separation Principle 
Differential affinities of the various components of the analyte towards the stationary and mobile phase
Affinity is dictated by adsorption and solubility of the molecules
Substances will move with the mobile phase at different rates depending upon their Partition or Distribution coefficients
The phases are chosen such that components of the sample have different solubilities in each phase
Purpose of Chromatography 
Analytical - to determine chemical composition of a sample mixture
Preparative - used to purify sufficient quantities of a substance
Chromatographic Terms 
Chromatograph - equipment that enables a sophisticated separation
Eluent - fluid entering column/solvent that carries the analyte
Eluate - mobile phase leaving the column
Stationary Phase - immobilized phase
Mobile Phase - moves in a definite direction (liquid (LC), gas (GC))
Retention time (tR) - time takes for a particular analyte to pass through the system
Dead or Void Time (tm) - the time between the sample injection and the appearance of the non retained solute peak or mobile phase that move through the column that reach the detector
Ts - time duration of the analyte retained in the stationary phase
Sample (Analyte) - substance analyzed in chromatography
Solvent - any substance capable of solubilizing another substance
Chromatogram 
Visual output of the chromatograph
Graphical presentation of detector response, concentration of analyte in the effluent, or other quantity used as measure of effluent concentration
Display series of peaks referred as chromatographic peaks
Peaks are described in terms of width, height, and area
Used to identify and quantify the solute
Classification of Chromatography 
Based on shape of chromatographic beds: Planar Chromatography, Column Chromatography
Based on the physical state of mobile and stationary phase: Liquid Chromatography, Gas Chromatography, Supercritical Fluid Chromatography
Based on mechanism of separation: Ion-exchange Chromatography, Partition Chromatography, Affinity Chromatography, Adsorption Chromatography, Size exclusion Chromatography
Planar Chromatography 
Stationary phase is present on a plane
The plane can be a paper (paper chromatography) or thin layer of a substance spread on a glass, metal or plastic plate (thin layer chromatography, TLC)
Known as open bed chromatography
Paper Chromatography 
Liquid partition chromatography
The end of the paper is dipped in solvent mixture consisting of aqueous and organic components
The solvent soaks in paper by capillary action because of fibrous nature of paper
Mechanism of Separation in Paper Chromatography
1. Mobile phase rises up by capillary action
2. Testing sample is concentrated as a minute spot at the bottom of the filter paper
3. Sample mixture gradually rises up with the mobile phase which is liquid
4. Compounds in the mixture will be separated according to their ability of solubility
5. More polar substances will move slower and less polar substances will travel faster
Procedure for Paper Chromatography
1. A small spot of sample is applied to a strip of chromatography paper about 2 cm away from the base of the plate
2. This sample is absorbed onto the paper and may form interactions with it
3. The paper is then dipped into a solvent, taking care that the spot is above the surface of the solvent, and placed in a sealed container
4. The solvent moves up the paper by capillary action and dissolved the sample mixture, which then travel up the paper with the solvent
5. Different compounds in the sample mixture travel at different rates
6. Analysis - spot corresponding to different compounds may be located by their color, UV light, Ninhydrin or by treatment with iodine vapors
Thin Layer Chromatography (TLC) 
Used to identify unknown compounds and determine the purity of the mixture
Stationary phase consists of a thin layer of adsorbent material, usually silica gel, aluminum oxide, or cellulose immobilized onto a flat carrier sheet
Mobile phase consisting of the liquid solution (volatile organic solvent) that is drawn up the plate via capillary action
Advantages of TLC over Paper Chromatography
TLC takes only 3-4 hrs for separation compared to 14-16 hrs for paper chromatography
TLC can use corrosive reagents like sulfuric acid which pose a limitation for paper chromatography
Easier to separate and visualize the components
Capacity to analyze multiple samples in a single run
Relative Front/Retention Factor Value (Rf value) 
The rate of migration of the various substances being separated are governed by their relative solubilities in the polar stationary phase and non polar mobile phase
Rf = distance travelled by the substance / distance travelled by the solvent front
Column Chromatography 
Stationary phase is held in a narrow tube through which the mobile phase is forced under pressure
Mobile phase may be gas (gas chromatography), liquid (liquid chromatography), supercritical fluid (supercritical fluid chromatography)
When the stationary phase in LC consists of small-diameter particles, the technique is High Performance Liquid Chromatography (HPLC)
Supercritical Fluid 
A highly compressed fluid that combines the properties of gas and liquid
Elution in Column Chromatography
1. Isocratic elution
2. Gradient elution
Chromatogram 
The position on time axis may serve to identify the components of the sample
The peak is symmetrical like a Gaussian Peak in statistics
The areas under the peaks provide quantitative measure of the amount of each component
Asymmetric Chromatographic Peaks 
Peak tailing
Peak fronting
Factors affecting clean separation or resolution in Column Chromatography
Migration rates of solutes
Band Broadening
Migration Rates of Solutes
Depends on the magnitude of the equilibrium constant (also known as distribution constant, partition constant, or partition coefficient, K) by which the solutes distribute between the mobile and stationary phases
Average rate of solute migration, v = u * (1 / (1 + k'))
Average rate of movement of the mobile phase molecule, u
Retention Time and Distribution Constant
Retention time = u * (1 / (1 + k'))
k' = KVs/Vm = u * (1 / (1 + k'))
Retention Factor or Capacity Factor, k'
The ratio between the adjusted retention time and the dead time
k'A = (tR - tM) / tM
Ideally, separation is performed at 1 < k' < 10
Selectivity Factor, α 
Also known as relative retention, ratio of the distribution constant of the strongly retained specie (KB) and the less retained specie (KA)
Describe the separation of two species (A and B)
�� 
Average velocity of the mobile phase
k' 
Retention factor or capacity factor of a solute
Selectivity factor, 𝜶 
Ratio of the distribution constant of the strongly retained specie (KB) and the less retained specie (KA)
Column Chromatography 
Widely used parameter in describing the migration rate of solutes on a column
The ratio between the adjusted retention time and the dead time
k' < 1 
Elution is fast; determination of retention time is difficult
k' > 10 
Elution takes a very long time
1 < k' < 10 
Ideal separation is performed
The longer A component is retained by the column, the greater is the capacity factor
Selectivity factor, 𝜶 
Also known as relative retention, ratio of the distribution constant of the strongly retained specie (KB) and the less retained specie (KA)
𝜶 = 1 
Solutes have identical retention time
𝜶 > 1 
Efficient separation
The greater the ratio of partition coefficient (K) between the mobile phase and stationary phases, the greater the separation between components
If t'RB will have a large value and t'RA will have a small value, the greater the separation between the two components
Band Broadening 
Term used to describe the overall dispersion or widening of a sample peak as it passes through a column (or separation system)
Theoretical Plate Theory 
Chromatographic column contains a large number of separate layers, called theoretical plates
It is important to remember that the plates do not really exist
Number of theoretical plate in a column, N 
The more plates, the better (Ideal value for N > 2000)