| GHG
Handbook - Chemical Processes Covered |
| Process Names: A | B | C | D |E | F | H | I |M | N | O | P| S | T | U | V |X | |
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| ABS Resin by Emulsion/Mass Polymerization |
Acetaldehyde From Ethylene by One-Step Oxidation |
Acetic Acid From Methanol by the BP Cativa Process |
Acetic Anhydride From Acetic Acid Via Ketene |
Acetylene From Natural Gas by Partial Oxidation |
| Acrylic Acid, Ester Grade, by Nippon Shokubai Process |
| (Meth)Acrylic Resin Pellets by a Continuous Bulk Polymerization Process |
Acrylonitrile From Propylene by Ammoxidation |
| Adipic Acid From Benzene Via Cyclohexanol |
Adipic Acid From Cyclohexane |
Adipic Acid From Phenol Via Cyclohexanol |
Alcohols, Primary Linear, C6-C20, by Ethylene Oligomerization |
Ammonia From Natural Gas by Steam Reforming by ICI "AMV" Process |
Ammonia From Natural Gas by Steam Reforming (M. W. Kellogg's Improved
Process: KAAP-KRES) |
Aniline From Nitrobenzene by Vapor-Phase Reduction |
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Benzene [Mixed Xylenes By-Product] From Reformate Heart Cut by Sulfolane
Extraction and Distillation |
Bisphenol A, PC Grade From Acetone and Phenol by an Ion-Exchange
Catalyzed Process |
N-Butanol and 2-Ethylhexanol (2:1 Ratio) From Propylene Via N-Butyraldehyde,
RH Catalyst |
| N-Butyl Acrylate Process |
N-Butyraldehyde From Propylene (Water-Sol Rh Catalyst) |
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Caprolactam From Phenol by the Hydroxylamine Phosphate Oxime Process |
Carbon Black by the Oil-Furnace Process Using Air as the Oxidant Gas |
Carbon Black by the Oil-Furnace Process Using Oxygen as the Oxidant Gas |
Chlorine [Caustic Soda By-Product] by Electrolysis Of NaCl In Diaphragm Cells |
Cumene From Benzene and Propylene |
Cyclohexane From Benzene by Hydrogenation |
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Diammonium Phosphate Granular Fertilizer (18-46-0) |
| Dimethyl Ether by a Single-Step Process |
Dimethyl Terephthalate From P-Xylene by Successive Oxidations and Esterifications |
Dinitrotoluene From Toluene by Nitration |
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EPDM Rubber Containing Ethylidene Norbornene by a Gas Phase Process |
| EPTA Production by a Process Similar To Eastman Process |
Ethanol From Ethylene by Catalytic Hydration |
Ethanolamines From Ammonia and Ethylene Oxide, 20:1 Molar Reactor Feed Ratio |
Ethylbenzene From Benzene by Liquid-Phase Alkylation, AlCl3 Cat. |
Ethylbenzene From Benzene by Vapor-Phase Alkylation |
Ethylbenzene From Benzene by Liquid-Phase Alkylation, Zeolite Cat. |
Ethylene From Atomospheric Gas Oil by Millisecond(TM) Cracking/Demethanization |
Ethylene From N-Butane by Conventional Cracking With Front-End Deethanization |
Ethylene From Ethane by Conventional Cracking With Front-End Deethanization |
Ethylene From Ethane-Propane by Conventional Cracking/Front-End Deethanization |
Ethylene From Light Naphtha by Conventional Cracking/Front-End Deethanization |
Ethylene From Propane by Conventional Cracking With Front-End Deethanization |
Ethylene From Refinery Gas, Including Steam Cracking Of Ethane and Propane |
Ethylene From Vacuum Gas Oil by Millisecond(TM) Cracking/ Demethanization |
Ethylene From Wide-Range Naphtha by Millisecond(TM) Cracking/ High Severity |
Ethylene From Wide-Range Naphtha by Millisecond(TM) Cracking/ Mild Severity |
Ethylene Dichloride by Direct Chlorination: Liquid-Phase HTC Process (Oxy Vinyls) |
Ethylene Dichloride by Oxychlorination: Fluidized-Bed Reactor,
Oxygen-Based (Oxy Vinyls) |
Ethylene Glycol From Ethylene and Oxygen Via EO (All EO For EG) |
Ethylene Oxide From Ethylene by Air Oxidation (All Marketable Ethylene Oxide) |
Ethylene Oxide From Ethylene by Oxygen Oxidation (All Marketable Ethylene Oxide) |
Ethylene/Vinyl Acetate Copolymer Using a Tubular Reactor Process |
2-Ethylhexanol From Propylene, Cobalt Hydrocarbonyl Catalyst |
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Formaldehyde From Methanol, Ferric-Molybdate Catalyst |
Formaldehyde From Methanol, Silver Catalyst |
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Hexamethylenediamine From Acrylonitrile Via Adiponitrile by Electrohydrodimerization |
Hexamethylenediamine From Acrylonitrile by Electrohydrodimerization
In Undivided Cells(Emulsion) |
Hexamethylenediamine From Acrylonitrile Via Adiponitrile by Ammoniation
and Hydrogenation |
Hexamethylenediamine From Butadiene Via Dichlorobutene, Dicyanobutene, and ADN |
Hexamethylenediamine From Butadiene Via Adiponitrile by Hydrocyanation |
Hydrogen From Natural Gas by Steam Reforming |
Hydrogen Fluoride From Fluorspar |
Hydrogen Peroxide by the Anthraquinone Process |
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Isodecanol From Nonenes, Cobalt Catalyst |
Isononyl Alcohol From Octenes, Rhodium Catalyst |
| Isophthalic Acid From M-Xylene by Bromine-Promoted Catalytic Air Oxidation |
Isophthaloyl Chloride From M-Xylene |
Isopropanol From Chemical Propylene, Silicotungstate Catalyst |
Isopropanolamines From Propylene Oxide and Ammonia (NH3:PO=5:1) |
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Maleic Anhydride From Benzene, Fixed Bed Reactor, Direct Dehydration |
Maleic Anhydride From N-Butane, Fluid Bed Reactor, Direct Dehydration |
Maleic Anhydride From N-Butane, Fluid Bed Reactor, Organic Solvent Absorber |
Maleic Anhydride From N-Butane, Moving Bed Reactor |
Methanol From Coal by the SCGP and ICI/Synetix LPM Process |
Maleic Anhydride From N-Butenes, Fluid Bed Reactor, Direct Dehydration |
| Melamine From Urea by the Melamine Chemicals M-II Process |
Methanol From Natural Gas by the Lurgi Combined Reforming Process |
Methylamines From Methanol and Ammonia |
| Methyl Chloride From Methanol and Excess HCL In Liquid Phase |
Methyl T-Butyl Ether From a Cat-Cracked C4 Stream |
Methylene Diphenylene Isocyanate and Polymeric Form (PMPPI) by Phosgenation |
Methyl Methacrylate From Acetone, HCN, and Sulfuric Acid |
Methyl Methacrylate From T-Butanol Via Methacrolein and Methacrylic Acid |
P-Methylstyrene From Toluene and Ethylene Via P-Ethyltoluene |
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Nitric Acid, 60% From Ammonia by Catalytic Oxidation |
Nitrobenzene From Benzene by Conventional Nitration |
Nitrobenzene From Benzene by Adiabatic Nitration |
Nitrogen Of 95% Purity From Air by Pressure Swing Adsorption (PSA) |
Nylon 6 Melt From Caprolactam For Direct Spinning |
Nylon 66 Chips From Adipic Acid and Hexamethylenediamine |
Nylon Carpet Yarn From a Nylon Salt Aqueous Solution |
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Olefins, Linear Alpha, by Two-Stage Oligomerization-Displacement Process |
Oxygen Vapor Via Cryogenic Air Separation |
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Peracetic Acid From Acetaldehyde by Acid-Catalyzed Liquid-Phase Oxidation |
Phenol by Liquid Phase Oxidation of Toluene |
Phenol-Formaldehyde Resol Syrup, 50% Solids, Batch Process |
Phosphoric Acid by the Hemihydrate Wet Process |
| Phthalic Anhydride From O-Xylene In a Fixed-Bed Reactor (BASF) |
Polybutadiene by Lithium-Catalyzed Polymerization |
Polycarbonate by Batch Interfacial Process With C7 Antisolvent Polymer Recovery |
Polycarbonate by Batch Interfacial Process With Polymer Recovery From Aqueous Phase |
Polycarbonate by Batch Interfacial Process With Polymer Recovery From Toluene Phase |
Polycarbonate by Batch Interfacial Process With Recycle Of Saturated Salt Solution |
Polyethylene, HD, by Gas Phase Fluidized-Bed Process (UCC) |
Polyethylene, HD, by a Loop Reactor Process (Phillips) |
Polyethylene, HD, by a Medium Pressure Solution Process (Dupont) |
Polyethylene, HD, by a Stirred-Tank Heavy Diluent Prodess |
Polyethylene, LLD, by a Himont Type Process |
Polyethylene, LLD, by a Low Pressure Solution Process (Mitsui) |
Polyethylene, Very LD, by High Pressure Tubular Reactor Process Using Exxpol |
Polyethylene, Very LD, by High Pressure Autoclave Reactor Process Using Exxpol |
Polyethylene, Very LD, by High Pressure Autoclave Reactor Process (CDF) |
Polyethylene, Very LD, by Low Pressure Adiabatic Solution Process |
Polyethylene Terephthalate by Conventional Melt-Phase Plus Solid-State Polymerization |
Polyethylene Terephthalate by a Process Similar to the Eastman Chemical Process |
Polyethylene Terephthalate Pellets (IV=0.6) From Terephthalic Acid and EG |
Polypropylene by a Bulk Slurry Phase Loop Reactor Process |
Polypropylene Homopolymer by a Vertical Stirred Bed Gas Phase Process (BASF) |
Polypropylene Block Copolymer by a Gas Phase Process (Sumitomo) |
Polypropylene Copolymer by a Horizontal Stirred Bed Gas Phase Process (Amoco/Chisso) |
Polypropylene Copolymer by a Vertical Stirred Bed Gas Phase Process (BASF) |
Polypropylene Copolymer by a Himont Type Process |
Polystyrene, Expandable, by Batch Suspension Polymerization |
Polystyrene, General Purpose, by Continuous Bulk Polymerization |
Polystyrene, General Purpose, by the SDS Process |
Polystyrene, High Impact, by Continuous Bulk Polymerization |
Polystyrene, High Impact, by the SDS Process |
| Polytetramethylene Ether Glycol by Polymerization and Alcoholysis, Polyfluorosulfonic Cat. |
Polyurethane Foam Boardstock (Rigid) From Reduced CFC Formulation |
Polyvinyl Acetate Beads by Suspension Polymerization |
Polyvinyl Acetate Latex by Emulsion Polymerization |
Polyvinyl Acetate Pellets by Solution Polymerization |
Polyvinyl Chloride by Bulk Polymerization |
Propylene Oxide by the Conventional Chlorohydrin Process |
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Sodium Tripolyphosphate From Wet Process Phosphoric Acid |
Styrene From Benzene and Ethylene Via Vapor-Phase Alkyl. and Adiabatic Dehydro |
Styrene-Acrylonitrile Resin by Continuous Mass Polymerization |
Styrene-Butadiene Rubber by Emulsion Polymerization |
Sulfuric Acid From Sulfur |
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Terephthalic Acid (High Purity) From P-Xylene by Bromine-Promoted Air Oxidation |
| Terephthalic Acid, Purified, by the Conventional Catalytic Air Oxidation Process |
Tetrahydrofuran From Maleic Acid |
Toluene Diisocyanate by Phosgenation |
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Urea, Agricultural Grade, by the Stamicarbon Process |
Urea-Formaldehyde Molding Compound |
Urea-Formaldehyde Resin Syrup, 65% Solids Process |
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Vinyl Acetate From Acetylene and Acetic Acid |
Vinyl Chloride by a Balanced Process With Heat and HCL Recovery (Oxy Vinyls) |
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| P-Xylene From Heavy Reformate/MSTDP Xylene by Parex(R) Adsorption Process |
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