Page 162 - CW E-Magazine (29-7-2025)

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News from Abroad

GREEN AVIATION
Syzygy’s Uruguay SAF project gets Velocys Bharat Jyoti Impex

as Fischer-Tropsch technology licensor AVAILABLE REGULARLY

Syzygy Plasmonics, the US-based “This project proves that proﬁ table  2 Acetyl ButyroLactone Acetophenone  Acetyl Acetone  Acrylonitrile  Methyl Iso Propyl Ketone  Methyl Propyl Ketone
 Adipic Acid  Allyl Alcohol  Allyl Chloride  Allylamine
 Methyl Salicylate  Methyl Stearate  Methyl Stearate / Palmitate
electriﬁ ed biogas-to-SAF technology SAF production doesn’t have to wait on  Alpha-Methyl Styrene  4 Amino Phenol  Amino Ethyl Ethanol Amine  2 Methyl THF  Methyl Tin Mercaptide  Mono Cyclohexylamine
developer, has taken on board Fis- future infrastructure,” said Trevor Best,  Amino Guanidine Bicarbonate  Anisole  Antimony Trioxide 99.8%  Mono Ethyl Amine 70%  Mono Isopropylamine 70% / 99%
cher-Tropsch technology supplier CEO of Syzygy Plasmonics. “With  Azelaic Acid  Barium Carbonate  Barium Nitrate 99%  Monoglyme  N Butyraldehyde  N Ethyl Pyrrolidone
Velocys, for its sustainable aviation Velocys, we are bringing in a complete,  1,2,3-Benzotriazole  1,2,3 Benzotriazole 99.5%  N Pentane 95%  N Vinyl Pyrrolidone
 N,N Dimethyl Cyclohexylamine  N,N-Dicyclohexyl Carbodiimide
 Benzoyl Chloride [99.5%] China  Biphenyl
fuel (SAF) project in Uruguay. modular solution that drives down  Boron Trifluoride Etherate  1,3-Butane Diol  N,O-Bis (Tri Methyl Silyl) Acetamide
overall production costs and is ready  1,4 Butane Diol [DAIREN]  2 Butyne 1,4 Diol  NACOL 10-99% (N Decanol) SASOL Germany
The ‘NovaSAF 1’ facility will con- to scale. Uruguay is only the start,”  Caproic Acid  Cerium Oxide  Cesium Carbonate  NACOL 6 99% (N Hexanol)  NACOL 8 99% (N Octanol)
vert dairy waste and biogas into drop- he remarked.  Cetyl Chloride  CIS-2-Butene-1,4-Diol  Crotonic Acid  N-Amyl Alcohol (N-Pentyl Alcohol)  N-Butyl Amine
in jet fuel with a nameplate capacity of eliminates the need for water-intensive  Cyanuric Chloride  Cyclohexanol  Cyclopentanone  N-Decanol  N-Heptane 99%  N-Hexane 99%
 Cyclopropylamine  D - Tartaric Acid  D-Camphor Sulphonic Acid
 N-Hexyl Alcohol (99% & 98%)  Nitro Ethane
500,000 gallons annually, using only steam reforming or expensive electro- The ﬁ nal investment for the  Di Cyclohexylamine  Di Ethyl Ketone  Di Ethyl Malonate  Nitro Methane  N-Methyl 2 Pyrolidone  N-Methyl Piperazine
renewable electricity and waste gas – lysers, radically simplifying the SAF ‘NovaSAF 1’ project is expected in Q4  Di Ethyl Sulphate  Di Iso Butyl Ketone [DIBK]  N-Pentane 99%  1-Octanol (C8)  1-Octene
without green hydrogen and complex value chain. 2025, with the start of operations some  Di Methyl Acetamide [Henan Junhua]  Di Methyl Malonate  Ortho Chloro Benzaldehyde  Para Benzoquinone
gasiﬁ cation. time in Q1 2027.  Di Phenyl Carbonate  Di Sodium Phosphate Anhydrous  Para Chlorobenzaldehyde  Para Cresol
To convert that syngas into high-  2,4 Di Tertiary Butyl Phenol  Dibasic Ester  Para Hydroxybenzaldehyde  Paraformaldehyde 96%
 Pelargonic Acid  Perchloric Acid
 DIBOC (Di Tert. Butyl Dicarbonate)
At the heart of the project is yield jet fuel, Syzygy has selected “With its modular design and feed-  Dibromomethane (Methylene Di Bromide)  Dicyclopentadiene  Petroleum Ethers 40-60 / 60-80 / 80-100 / 100-120 etc.
Syzygy’s light-driven GHG e-Reforming Velocys and its microFTL technology, stock ﬂ exibility, NovaSAF 1 is built for  Di-Ethyl Carbamyl Chloride  Diethyl Hydroxylamine  Phenyl Ethyl Alcohol  Phenyl Ethyl Amine [ R+ ; DL ]
technology, which produces the ideal known for reliability and for maximis- replication across 50,000+ untapped  Diethyl Oxalate  Diglyme  Diisobutylene  Diisopropylamine  Phosphorous Pentoxide  Pivaloyl Chloride  Potassium Bi Carbonate
2:1 syngas ratio for Fischer-Tropsch ing fuel output, both critical factors in biogas sites worldwide - unlocking a  Diisopropyl ethylamine  Diisopropyl Succinate  Potassium Persulphate  Potassium Tertiary Butoxide
 Potassium Thioacetate  Propionaldehyde  Propionic Anhydride
 2,2-Dimethoxy Propane  Dimethyl Oxalate  Di-N-Propyl Amine
(FT) synthesis directly from biogenic driving down the total cost required to new era of proﬁ table, policy-aligned  DL Alfa Phenyl Ethyl Amine  D-Ribose  DMSO (Hubei Xingfa)  Pyrogallol  2-Pyrrolidone  Quinoline
methane and CO₂. This breakthrough produce synthetic fuel. SAF production,” Syzygy said.  Ethyl Benzene  Ethyl Cyclo Hexane  2 Ethyl Hexyl Bromide  Resorcinol (China)  R Phenyl Ethylamine
 2-Ethylhexyl Thioglycolate  Ethyl Nicotinate  Ethyl Silicate  Salicylic Acid Technical / Pure  Secondary Butanol (China)
WATER TREATMENT  Ethylene Glycol Diacetate (EGDA)  Fluorobenzene  Formamide  Sodium Dichloroisocyanurate (56%) Granule
Toray’s reverse osmosis membranes to be used  Formic Acid 99%  Fumaric Acid  Furfuraldehyde  Furfuryl Alcohol  Sodium Diethyldithiocarbamate  Sodium Ethoxide
 Furfurylamine  Gamma Amino Butyric Acid (4 Amino Butyric Acid)
 Sodium Ethoxide solution in Ethanol / Methanol
in desalination plant in Saudi Arabia  Gamma Butyrolactone  Glutaraldehyde 50%  Glycine  Sodium Methoxide  Sodium Sulphite (Aditya Birla -Thailand)
 Sodium Sulphite 98%  Sodium Sulphite Tech 90%
 Glycolic Acid 70%  Glyoxal 40%  Glyoxylic Acid 50%
 Guanidine Carbonate  Guanidine HCl  Guanidine Thiocyanate  Sodium Tertiary Butoxide  Sorbitol Powder  Stearyl Bromide
Japanese chemicals ﬁ rm, Toray In-  Guanine  Heptane [mix]  1,6-Hexane Diol  Hippuric Acid  Stearyl Palmitate  Strontium Carbonate  Succinic Acid
dustries, t has supplied reverse osmosis  12 Hydroxy Stearic Acid  Imidazole  Isobutylamine Isopropyl Palmitate  Succinic Anhydride  Sulfolane Anhydrous

(RO) membranes to the Shuaibah 3  Iso Octa Decyl Alcohol  Isovaleraldehyde  Itaconic Acid  Tert. Butyl Amine  Tertiary Amyl Alcohol
 L + Tartaric Acid  Lactic Acid  Lanthanum Carbonate
 Tertiary Butyl Acetate  Tetraglyme (Tetra Ethylene Glycol)
IWP seawater desalination plant in  Lauric / Myristic / Palmitic / Oleic / DCFA / Caprylic Acid  Tetra Hydro Furfuryl Alcohol  THF (Dairen, Nan Ya)
Saudi Arabia through Dammam-based  Lithium Aluminium Hydride  Lithium Amide  Thioacetamide  Thiocyanates: Ammonium / Sodium / Potassium
subsidiary Toray Membrane Middle  Lithium Carbonate  Lithium Carbonate [Equivalent to I.P.]  Thioglycolic Acid 80%  TMOF / TEOF / TMO Acetate
East LLC. The plant’s daily potable  Lithium Hydroxide  Lithium Hydroxide Anhydrous  Tolyl Triazole  Tolyltriazole Granular  Tri Ethyl Citrate
 Lithium Hydroxide Monohydrate LIOH : 57.7% Min
 Tri Fluoro Acetic Acid  Tri Fluoro Acetic Anhydride
water production capacity is 600,000  Lithium Metal 99% / 99.9%  L-Proline  M. P. Diol  2,2,2 Tri Fluoro Ethanol  2,2,2-Tri Fluoro Ethylene
cubic metres. This facility provides  Malonic Acid  Malononitrile  Maltol  Meta Cresol 99.5%  Tri Isodecyl Stearate  Triacetin (Glycerine Triacetate)
stable supplies of drinking water to  Meta Hydroxy Benzoic Acid  Meta Para Cresol [Meta 60%]  1,2,4-Triazole & its Sodium Salt
Mecca, Jeddah, Taif, and Bahah, where bon dioxide emissions through regular 22-million barrels per year. Toray  Methyl Amyl Ketone  Methallyl Chloride  1 Methoxy Propanol  Trichloroisocyanuric Acid 5-8 Mesh,100-120 Mesh
demand for this vital resource has risen evaporation into an eco-friendly setup develops and manufactures everything  1-Methoxy Propyl Acetate  Methyl Cellosolve  Methyl Cyclohexane  Triethyl Ortho Acetate  Triethylsilane
 Triisobutyl Phosphate  Tri-N-Butyl Phosphate
 Methyl Glycol  1-Methyl Imidazole  2-Methyl Imidazole
owing to population and inbound employing advanced RO membrane from RO and ultraﬁ ltration membranes  Methyl Iso Butyl Carbinol [MIBC]  Methyl Isoamyl Ketone  Triphosgene  Triss Buffer  2,6-Xylidine
tourism growth. technology. A solar power system to membrane bioreactor modules.
supplies the equivalent of 65 mega- It oﬀ ers solutions for an array of Bharat Jyoti Impex
The Shuaibah 3 IWP project has watts peak to the plant. This project needs, with its applications including “Jasu”, Ground Floor, 30, Dadabhai Road, (Near CNM School), Vile Parle (West), Mumbai 400 056.
converted a conventional seawater is expected to cut annual emissions by drinking water, industrial, agricultural, Phone: +91 91528 33394 & +91 91524 33394  Whats App:. +91 99300 51288
desalination facility consuming a lot of around 45-mt of carbon dioxide and and wastewater treatment, and waste- Email: info@bharatjyotiimpex.com  Website: www.bharatjyotiimpex.com
energy and producing signiﬁ cant car- reduce crude oil consumption by about water reuse. MORE THAN 2000 CHEMICALS IN SMALL PACKING

162 Chemical Weekly July 29, 2025

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