Industrial Sugar Feedstocks
A Carbon Conversion Technology Platform
Advancing the Future of Biomanufacturing
Built on energy infrastructure
Carbon in
Sugar out
Something
Scaling Beyond Agriculture
The Sugar Feedstock Bottleneck
The Bioeconomy
$4 Trillion today
$30 Trillion by 2050
The bioeconomy runs on sugar
Agriculture can’t scale it
Biomanufacturing will remake how we produce food, materials, and chemicals
But agriculture was never built for a multi-trillion-dollar bioeconomy
Agriculture at risk
Severe weather events
Crop and food losses
Supply and price shocks
Dependence on land, farms, crops, waste streams, or agricultural supply chains
Beyond Agriculture
Scaling Biomanufacturing from Energy and Carbon Infrastructure
Resilient, scalable industrial sugar feedstocks
Energy Infrastructure
Vertical Integration
Onshore supply
Building the feedstock layer of the future bioeconomy, modular sugar production systems integrated with energy and carbon infrastructure.
The Shift
From Agricultural Supply Chains to Industrial Infrastructure
Biology does not require farms. It requires carbon, energy, and the right metabolic pathways
Always on. Secure.
The Solution
Sugar, Rebuilt for Industrial Scale
Solarferm is building the feedstock layer of the future bioeconomy: modular sugar production systems integrated with energy and carbon infrastructure.
We make industrial feedstocks the way industry makes energy and chemicals: continuously, where infrastructure and resources are available and viable.
An Advanced Carbon-to-Sugar Platform
Solarferm’s proprietary bioproduction technology is an adaptable carbon conversion platform designed to enable industries to efficiently produce high-demand, fermentation-ready industrial sugars from carbon dioxide (CO₂) and hydrogen (H₂), integrated directly with energy and carbon infrastructure.
Currently focused on feedstock applications for the industrial bioeconomy, Solarferm aims to deploy the most cost-effective and scalable sugar production technology available.
Vertically Integrated Biomanufacturing
What We Do
CO₂ to Sugar
Solarferm is a developer and technology provider for the energy, chemical and manufacturing sectors.
Modular Reactors and Energy Systems
Forms our hardware
Sugar, Rebuilt from First Principles
Our carbon conversion platform produces fermentable sugar feedstocks directly from carbon dioxide (CO₂) and hydrogen (H₂)
Digital Programmable Sugars
Synthetic biology forms our operating system: programmable microbial chassis optimised to precisely assemble sugar molecules, from glucose and fructose to advanced carbohydrate derivatives.
Target industrial sugar feedstocks:
Monosaccharides: glucose, fructose
Nutritional and functional sugar families include:
Monosaccharides: allulose, tagatose, mannose, galactose, xylose, arabinose
Disaccharides: sucrose, trehalose, cellobiose
Derivatives: functional polysaccharides and specialty carbohydrate intermediates
How We Do It
CO₂ to Sugar
We compresses the supply chain to its molecular essentials
Solarferm produces fermentable sugar feedstocks directly from carbon dioxide (CO₂) and hydrogen (H₂)
Why Now
Biomanufacturing is ready
Fermentation capacity is exploding
We believe it is critical that resilient food production systems be urgently deployed for global food and energy security
Solarferm is building that future
But the feedstock system is still stuck in the 20th century.
So we asked a simple question:
What if sugar didn’t come from farms?
What if it came from infrastructure?
Synthetic biology is accelerating
One Feedstock
Every Market
Industrial feedstock infrastructure for the next generation of fermentation, biomanufacturing and the bioeconomy
Precision Fermentation
Alternative Proteins
Cellular Agriculture
Chemicals, Materials
Energy Carriers
Sugar, plugged into energy infrastructure
How We Do It
C3, Carbon Capture and Conversion
Thermochemistry
Thermal Catalysis. Thermal catalytic hydrogenation of carbon dioxide into formic acid, the liquid reduced carbon feedstock for bioproduction of glucose, or fructose
Electrochemistry.
Electrochemical Optimisation. Electrochemical reduction and optimisation of formic acid chemistry.
Process optimisation for formic acid synthesis in the feedstock synthesis plant, and for tuning formic acid and carbon dioxide feedstock utilisation in the sugar bioproduction plant
Synthetic Biology
We combine thermochemistry and biotechnology bioproduction system that scales on our energy infrastructure.