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Using Innovative Technology to Transform Emissions and Effluentsto usable forms of energy & material.
We work with customers across Industriesto ensure that all emissions are capturedcompletelyand are converted online to usable Energy & Materials.
We build circularityand have running commercial solutions for the Metals & Metal ProcessingPetroleum & Gas RefineriesChemical & Polymer ManufacturingMobility – Shipping & AutomotiveHuman Ingestion – FoodPharmaceuticals and Supplement Manufacturing.
CO2 and CH4 are major greenhouse gases emitted globally from fossil fuel burning and industrial processes
In order to meetthe NDCs targets as per Paris declaration 2015India has committed in COP 26 that it would be a “Net Zero" GHG emission country by 2070.
UNDOABLE!!
Global Warming
Climate Change
Extreme Weather Events
Melting Ice
Ocean Acidification
Impacts on Ecosystems
Global Warming
Climate Change
Extreme Weather Events
Melting Ice
Ocean Acidification
Impacts on Ecosystems
Global Warming
Climate Change
Extreme Weather Events
Melting Ice
Ocean Acidification
Impacts on Ecosystems
Global Warming
Climate Change
Melting Ice
Extreme Weather Events
Impacts on Ecosystems
Ocean Acidification
We have the power today to change tomorrow.
Emissions Conversion
Entity1's reactors utilize renewable electricity to power the electrochemical conversion process.
Value Added Products
The Value Added Products produced as an end product can be used for multiple industrial uses.
Environmental Impact
A renewablelow-carbon method to reduce greenhouse gas emissions while also generating usable productsimproving sustainability.
Taking a step ahead of carbon capturewhich involves investment into storage for carbon & separation of carbon based & other gasesour reactors ingest the entire green house gas from the outlets and converts them to usage energy & materialsleaving behind no residue. With an impressive conversion efficiency exceeding 80%we are leading the charge towards a sustainable future.
Indicative Industries Which Can Benefit From Our Technology
Electrocatalytic conversion of GHG emissions from petrochemical industries
The electrocatalytic conversion of GHG emissions to Value Added Products (VAPs) including ethanol is carried out employing electrochemical reactor at ambient of 28oC1 atms pressure and flow rate of emissions from petrochemical industry roughly 500ml/min. The initiator solution is acidified with 50 ml of conc. HCl. The acidified solution generates in-house hydrogen gas to facilitate the reduction of GHG emissions with carbon in the form of CO2COCH4ethaneN2SOxNOxSH2S etc into ethanolacetates and 5-methyl –phenylazothiophene – 2 – azo dye.
Thusfrom the HR-MS spectra of liquid and solid products of the GHG emissions electrocatalytic reduction as ethanolMg acetoethoxideCupric ethoxidecuprous ethoxide5-methyl-phenyl azo thiophene-azo dye. Depending on the variation in constituents and composition of the input GHG emissionseither ethanol or 5-methyl-phenyl azo thiophene-azo dye or acetic acid can be fine-tuned to be the major product.
Electrocatalytic conversion of GHG emissions from petrochemical industries
Electrochemical separation and agglomeration of iron ore in steel slag
Steel slag is a by-product obtained in the steel production plants and also presents huge challenge in the solid waste disposal. The steel slag although considered as solid waste also possess several valuable elements such as titaniumnickelZincironaluminumsilica so on and so forth. These elements or compounds when extracted by chemical or physical process results in value addition in diverse fields of applications such as wastewater treatment to semiconductor devices. It can be understood from the literature that the leaching technique was the most widely used in the resource recovery domain followed by other techniques like fusionhydrothermal treatment. As iron is the major constituent of steel productionany Fe content in the slag can be recovered electrochemically and utilize the silica content in the slag to encapsulate the same to avoid from environmental reactions and corrosion. The major advantage of Entity1 solution is that it can separate the minerals or elements at concentrations as low as parts per million (ppm) or parts per billion (ppb) (Ref: 202341000490).
Silicon Ingots From Refractory Bricks and Steel SludgeSlag Industrial Wastes
Steel slag is a by-product obtained in the steel production plants and also presents huge challenge in the solid waste disposal. The steel slag although considered as solid waste also possess several valuable elements such as titaniumnickelZincironaluminumsilica so on and so forth. These elements or compounds when extracted by chemical or physical process results in value addition in diverse fields of applications such as wastewater treatment to semiconductor devices. It can be understood from the literature that the leaching technique was the most widely used in the resource recovery domain followed by other techniques like fusionhydrothermal treatment.
Refractory bricks from steel plants are mostly silicon dioxide (> 70-98%). These refractory
bricks are rich source of semiconductor materials like Si and SiC upon proper processing. In
additionsteel sludge a waste material from steel industries possesses > 70% of SiO 2 that can be processed to Si or SiC.
Thusfrom the HR-MS spectra of liquid and solid products of the GHG emissions electrocatalytic reduction as ethanolMg acetoethoxideCupric ethoxidecuprous ethoxide5-methyl-phenyl azo thiophene-azo dye. Depending on the variation in constituents and composition of the input GHG emissionseither ethanol or 5-methyl-phenyl azo thiophene-azo dye or acetic acid can be fine-tuned to be the major product.
Electrocatalytic conversion of GHG emissions from Steel industries
Electrochemical separation and agglomeration of iron ore in steel slag
Preamble:
Steel slag is a by-product obtained in the steel production plants and also presents huge challenge in the solid waste disposal. The steel slag although considered as solid waste also possess several valuable elements such as titaniumnickelZincironaluminumsilica so on and so forth. These elements or compounds when extracted by chemical or physical process results in value addition in diverse fields of applications such as wastewater treatment to semiconductor devices. It can be understood from the literature that the leaching technique was the most widely used in the resource recovery domain followed by other techniques like fusionhydrothermal treatment. As iron is the major constituent of steel productionany Fe content in the slag can be recovered electrochemically and utilize the silica content in the slag to encapsulate the same to avoid from environmental reactions and corrosion. The major advantage of Entity1 solution is that it can separate the minerals or elements at concentrations as low as parts per million (ppm) or parts per billion (ppb) (Ref: 202341000490).
Silicon Ingots From Refractory Bricks and Steel SludgeSlag Industrial Wastes
Steel slag is a by-product obtained in the steel production plants and also presents huge challenge in the solid waste disposal. The steel slag although considered as solid waste also possess several valuable elements such as titaniumnickelZincironaluminumsilica so on and so forth. These elements or compounds when extracted by chemical or physical process results in value addition in diverse fields of applications such as wastewater treatment to semiconductor devices. It can be understood from the literature that the leaching technique was the most widely used in the resource recovery domain followed by other techniques like fusionhydrothermal treatment.
Refractory bricks from steel plants are mostly silicon dioxide (> 70-98%). These refractory
bricks are rich source of semiconductor materials like Si and SiC upon proper processing. In
additionsteel sludge a waste material from steel industries possesses > 70% of SiO 2 that can be processed to Si or SiC.
Electrocatalytic conversion of GHG emissions from petrochemical industries
The electrocatalytic conversion of GHG emissions to Value Added Products (VAPs) including ethanol is carried out employing electrochemical reactor at ambient of 28oC1 atms pressure and flow rate of emissions from petrochemical industry roughly 500ml/min. The initiator solution is acidified with 50 ml of conc. HCl. The acidified solution generates in-house hydrogen gas to facilitate the reduction of GHG emissions with carbon in the form of CO2COCH4ethaneN2SOxNOxSH2S etc into ethanolacetates and 5-methyl –phenylazothiophene – 2 – azo dye.
Solutions available to industries till now
CCS (Carbon Capture Storage)
CCUS (Carbon Capture Utilization & Storage - group of technologies that can avoid the atmospheric emission of CO from industrial processes is called CCUS)
CCS (Carbon Capture Storage)
CDR(Carbon Dioxide Removal)
CCUS (Carbon Capture Utilization & Storage - group of technologies that can avoid the atmospheric emission of CO from industrial processes is called CCUS)
If your process results in any kind of emissionswe would have a profitable solution to your challenge
India's Pledge for Achieving Net Zero Emissions and the Importance of Industry Decarbonization
Oil & Gas
Steel Industry
Cement Production
Power Plants
Sponge Iron Manufacturing
Distilleries
Why We Are Different
100% Indigenous Technology focused on Make in India initiative
ZERO Residue to dispose a NETZERO Target achievement
Chemical-based technology ensures consistency in operations
Our technology can deal with a combination of emissions on as is basis
Using CO2 gas emissions right where they're made cuts costssafety risks& logistical issues in transportation
VAP generated by the process can generate additional revenue streams to the client
Cross Section of a Reactor Under Production
Cross Section of a Reactor Control System
Using CO2 gas emissions right where they're made cuts costssafety risks& logistical issues in transportation
Representation of a Ghg to Ethylene Reactor
Implement Entity 1’s Electrocatalytic technology to convert greenhouse gases into useful chemicals
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Ethanol
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EVA
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Ethyl acetates
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Metal acetates
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Chloro Acetyl Chloride
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Thiophene Azo dyes
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Butadiene
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Propanaldehyde
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Azo dyes
UN
DOABLE!!
Entity 1's Innovation in Sustainable Technology
Entity 1 utilises an innovative reactor processusing conversion chemistry to transform all green house gas emissions to energy: Such as Ethanol or materials such as ethylene and butadienewhich find applications across many industries.
Meet the BelieversSustainers and People who make a difference.
Team
Pankaj Agrawal
Chairman
Experienced investment banker with 36+ years. Forbes & Arabian Business Magazine recognized leader in UAE. Founder of Signature Group since 2005. Advised over US$ 3 billion in global transactions
Kaushik Palicha
Founder & InventorTechnology
Post Graduate in Finance and Economicsleading transition to renewable energywaste-to-valuewith 82+ granted patents & 60+ pendingsupporting Make-in-India
Dr. Sangaranayanan
Director - Technology
PhD from Institute of Science Bangalore with 45 years in academic and electrochemical research. Alexander Von Humboldt Fellow & Chair Professor at IIT Madras Chemistry Department.
Paritosh Gupta
Advisor
35+ years in sustainable infrastructure projects. Strong partnerships with international agencies and foreign governments. Former Founder and CEO of Kukuza Project Development Company
Dr. Harinipriya
Director - Technical
PhD in Electrochemistry from IIT Madras with 20+ years of academic and professional experience. Expertise in energy conversionsolar thermal systemsand next-generation battery research
Himanshu Singhal
Director - Strategic Business
With 20+ years in global bankingHimanshu specializes in foreign exchange and interest rates. Himanshu was part of the founding team at Kotak Mahindra Bank Treasurywas responsible for setting up of IT systemsoperationsand first digital FX platform of the bank. He served as EVP - Global Markets overseeing regional sales. He is an MIT Sloan School alum
Pramod Pandey
Director - Operations
A graduate engineer with 36 years of experiencecurrently holds key roles at Indo Japan Polymers Pvt Ltd and Energec Chem Speciality Pvt Ltd. Excels in both B2C and B2B industrial sectorsdemonstrating adaptability and multicultural leadership skills.
Mita Samant
Director – Finance
With 20+ years of corporate finance experience at esteemed firms like L&TMorgan Stanleyand Essar Groupshe received the RPG Top Gear Award. Skillfully managed a consortium of 21 banks with a substantial working capital limit.
Besky Christopher
Compliance & Investor Relations
Over 20 years of industry experience in telecomcement manufacturingand chemical distribution. Proficient in laws like Income Tax ActGoods & Services Tax Lawand Companies Acthis expertise lies in meticulous complianceand transparency
Janani Chandrasekar
Banking & Treasury
With a decade-long experience in corporate finance and corporate restructuringspecializing in treasury and controlling functionsshe has managed working capital for 15 consortium banks. Notablyshe excels in Foreign Direct Investment and M&A compliance.
Dr. Ruchir Gupta
Advisor
An Associate Professor in Computer Science and Engineering at IIT Varanasi with prior roles at JNU and IIIT Jabalpurcompleted his PhD at IIT Kanpur focusing on Edge ComputingIoTand Game Theory. His widely published research covers federated learningresource allocationand reinforcement learning. He joins Y-Capita as an advisorspecializing in AI integration and machine learning processes.
Pankaj Agrawal
Chairman
Experienced investment banker with 36+ years. Forbes & Arabian Business Magazine recognized leader in UAE. Founder of Signature Group since 2005. Advised over US$ 3 billion in global transactions
Kaushik Palicha
Founder & InventorTechnology
PhD in Finance & Economicsleading transition to renewable energywaste-to-valuewith 10+ granted patents & 60+ pendingsupporting Make-in-India
Dr. Sangaranarayanan
Director Technology
PhD from Institute of Science Bangalore with 45 years in academic and electrochemical research. Alexander Von Humboldt Fellow & Chair Professor at IIT Madras Chemistry Department.
Mr. ParitoshGupta
Advisor
35+ years in sustainable infrastructure projects. Strong partnerships with international agencies and foreign governments. Former Founder and CEO of Kukuza Project Development Company
Dr. Harinipriya
Director Technical
PhD in Electrochemistry from IIT Madras with 20+ years of academic and professional experience. Expertise in energy conversionsolar thermal systemsand next-generation battery research
Revolutionising Industrial Emissions and harvesting themcompletelyto make energy & materials. Using ScienceTechnology & Innovation – to keep our Planet clean.
UNDO
ABLE!!
ABLE!!
UNDO
Got a moment? While you are watching a short video about uswe have cleaned up One thousand twelve tons of emissions.
That's our game plan! And we're just getting started. Stay tuned for our innovative solutionssupporting industries to produce sustainablyand offering Carbon Credits. Watch this space – it will get even more fun from here.
Frequently asked questions
What's New?
Entity1 Secures a Major Patent!
We are proud to announce that Entity1 has been granted Patent No. 558979 for its groundbreaking innovation:
"Electrocatalytic Reactor and Method for Electrocatalytic Reduction of Greenhouse Gas (GHG) Emissions into Useful Chemicals."
This patentapproved under the Patents Act1970is valid for 20 years from October 52023. It marks a significant leap in sustainable technologyreinforcing our mission to convert harmful emissions into valuable resources. Stay tuned for more innovations from Entity1! 🌱🔬
29 January 2025
What's New?
Entity 1: The Rajya Sabha has passed the Oilfields (Regulation and Development) Amendment Bill2024modernizing energy laws to attract investments.
The bill redefines "mineral oils" to include unconventional hydrocarbonsintroduces "petroleum leases" for new agreementsand promotes green energy initiatives. It also eases operations for small players and strengthens compliance measures to enhance investor confidence.
16 December 2024
What's New?
Entity 1: The Union Cabinetled by the Prime Ministerhas approved modifications to the Pradhan Mantri JI-VAN Yojana.
The scheme's implementation timeline is extended by five yearsuntil 2028-29and now includes advanced biofuels from sources like agricultural residuesindustrial wasteand algae. It prioritizes innovation in technologies and feedstockspromoting sustainable agricultural residue useemploymentand India's energy security. It also supports advanced biofuel technology development and contributes to India's net-zero emissions target by 2070.
7 October 2024
What's New?
Entity 1: The "Pradhan Mantri JI-VAN Yojana" was launched on March 72019to promote 2G ethanol capacity development and investment.
This scheme offers financial assistance for 2G Bio-ethanol projects. The first 2G Ethanol Project by Indian Oil in PanipatHaryanawas dedicated in 2022with other projects by BPCLHPCLand NRL nearing completion. Second-generation biofuelsderived from non-food bioresources like residues and wasteaim to increase biofuel productionreduce carbon emissionsand enhance energy efficiency. They are more sustainable than firstgeneration biofuels and don't compete with food production.
7 October 2024
What's New?
Entity 1: India Glycols has signed a
Memorandum of Understanding (MoU)
To purchase all value added products produced by the Entity 1's RamCharan reactorsat any customer location across Indiashowcasing the reactors' capabilities.
26 July 2024
What's New?
Entity 1: Manas Agro has signed a Memorandum of Understanding (MoU)
To purchase all the ethanol and Rectified Spirit produced by Entity 1's Ram Charan reactorsat any customer location across Indiashowcasing the reactors' capabilities.
17 July 2024
What's New?
Entity 1: Hands over the first Handbook for Engineering of the RamCharan reactors to Shri Nagendranath SinhaPrincipal SecretaryMinistry of Steel.
All SAIL plants are putting up GHG and Slag reactors which will reinforce SAIL's long term commitment to carbon capture and reducing their carbon footprint.
3 July 2024
What's New?
Entity 1 : Presenting the Electro Catalytic Reactor to the Honorable Union Minister for Transport - Shri Nitin Gadkari for converting carbon dioxide oxide to Ethanolpioneering eco-friendly technologies.
2 May 2024
What's New?
Entity 1: Customer trials at site - transforming emissions into carbon type raw materialdriving sustainability.
2 May 2024
What's New?
Entity 1: Conducting Mini Reactor trials at steel plant siterevolutionizing emission management.
2 May 2024
What's New?
Entity 1: Showcasing at a Steel Event on emissions to value-added productsleveraging innovative solutions.
2 May 2024
Indicative Industries Which Can Benefit From Our Technology
Electrocatalytic conversion of GHG emissions from petrochemical industries
The electrocatalytic conversion of GHG emissions to Value Added Products (VAPs) including ethanol is carried out employing electrochemical reactor at ambient of 28oC1 atms pressure and flow rate of emissions from petrochemical industry roughly 500ml/min. The initiator solution is acidified with 50 ml of conc. HCl. The acidified solution generates in-house hydrogen gas to facilitate the reduction of GHG emissions with carbon in the form of CO2COCH4ethaneN2SOxNOxSH2S etc into ethanolacetates and 5-methyl –phenylazothiophene – 2 – azo dye.
Thusfrom the HR-MS spectra of liquid and solid products of the GHG emissions electrocatalytic reduction as ethanolMg acetoethoxideCupric ethoxidecuprous ethoxide5-methyl-phenyl azo thiophene-azo dye. Depending on the variation in constituents and composition of the input GHG emissionseither ethanol or 5-methyl-phenyl azo thiophene-azo dye or acetic acid can be fine-tuned to be the major product.
Electrocatalytic conversion of GHG emissions from petrochemical industries
Electrochemical separation and agglomeration of iron ore in steel slag
Steel slag is a by-product obtained in the steel production plants and also presents huge challenge in the solid waste disposal. The steel slag although considered as solid waste also possess several valuable elements such as titaniumnickelZincironaluminumsilica so on and so forth. These elements or compounds when extracted by chemical or physical process results in value addition in diverse fields of applications such as wastewater treatment to semiconductor devices. It can be understood from the literature that the leaching technique was the most widely used in the resource recovery domain followed by other techniques like fusionhydrothermal treatment. As iron is the major constituent of steel productionany Fe content in the slag can be recovered electrochemically and utilize the silica content in the slag to encapsulate the same to avoid from environmental reactions and corrosion. The major advantage of Entity1 solution is that it can separate the minerals or elements at concentrations as low as parts per million (ppm) or parts per billion (ppb) (Ref: 202341000490).
Silicon Ingots From Refractory Bricks and Steel SludgeSlag Industrial Wastes
Steel slag is a by-product obtained in the steel production plants and also presents huge challenge in the solid waste disposal. The steel slag although considered as solid waste also possess several valuable elements such as titaniumnickelZincironaluminumsilica so on and so forth. These elements or compounds when extracted by chemical or physical process results in value addition in diverse fields of applications such as wastewater treatment to semiconductor devices. It can be understood from the literature that the leaching technique was the most widely used in the resource recovery domain followed by other techniques like fusionhydrothermal treatment.
Refractory bricks from steel plants are mostly silicon dioxide (> 70-98%). These refractory
bricks are rich source of semiconductor materials like Si and SiC upon proper processing. In
additionsteel sludge a waste material from steel industries possesses > 70% of SiO 2 that can be processed to Si or SiC.
Preamble:
Steel slag is a by-product obtained in the steel production plants and also presents huge challenge in the solid waste disposal. The steel slag although considered as solid waste also possess several valuable elements such as titaniumnickelZincironaluminumsilica so on and so forth. These elements or compounds when extracted by chemical or physical process results in value addition in diverse fields of applications such as wastewater treatment to semiconductor devices. It can be understood from the literature that the leaching technique was the most widely used in the resource recovery domain followed by other techniques like fusionhydrothermal treatment. As iron is the major constituent of steel productionany Fe content in the slag can be recovered electrochemically and utilize the silica content in the slag to encapsulate the same to avoid from environmental reactions and corrosion. The major advantage of Entity1 solution is that it can separate the minerals or elements at concentrations as low as parts per million (ppm) or parts per billion (ppb) (Ref: 202341000490).
Silicon Ingots From Refractory Bricks and Steel SludgeSlag Industrial Wastes
Steel slag is a by-product obtained in the steel production plants and also presents huge challenge in the solid waste disposal. The steel slag although considered as solid waste also possess several valuable elements such as titaniumnickelZincironaluminumsilica so on and so forth. These elements or compounds when extracted by chemical or physical process results in value addition in diverse fields of applications such as wastewater treatment to semiconductor devices. It can be understood from the literature that the leaching technique was the most widely used in the resource recovery domain followed by other techniques like fusionhydrothermal treatment.
Refractory bricks from steel plants are mostly silicon dioxide (> 70-98%). These refractory
bricks are rich source of semiconductor materials like Si and SiC upon proper processing. In
additionsteel sludge a waste material from steel industries possesses > 70% of SiO 2 that can be processed to Si or SiC.
Electrochemical separation and agglomeration of iron ore in steel slag
Electrocatalytic conversion of GHG emissions from Steel industries
Thusfrom the HR-MS spectra of liquid and solid products of the GHG emissions electrocatalytic reduction as ethanolMg acetoethoxideCupric ethoxidecuprous ethoxide5-methyl-phenyl azo thiophene-azo dye. Depending on the variation in constituents and composition of the input GHG emissionseither ethanol or 5-methyl-phenyl azo thiophene-azo dye or acetic acid can be fine-tuned to be the major product.
Electrocatalytic conversion of GHG emissions from petrochemical industries
The electrocatalytic conversion of GHG emissions to Value Added Products (VAPs) including ethanol is carried out employing electrochemical reactor at ambient of 28oC1 atms pressure and flow rate of emissions from petrochemical industry roughly 500ml/min. The initiator solution is acidified with 50 ml of conc. HCl. The acidified solution generates in-house hydrogen gas to facilitate the reduction of GHG emissions with carbon in the form of CO2COCH4ethaneN2SOxNOxSH2S etc into ethanolacetates and 5-methyl –phenylazothiophene – 2 – azo dye.
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