In many industrial sectors, natural gas and LPG remain critical energy carriers—valued for their clean combustion and ability to deliver high-temperature heat for demanding processes. However, these fossil gases are also a major source of greenhouse gas emissions. The good news? Replacing them with renewable synthetic biogas is one of the most impactful and technically accessible steps industries can take toward decarbonization.

By using residual biomass from forestry and agriculture—resources that are often already available on site—synthetic biogas can be produced directly at the point of use. Through an integrated gasification process, woody or agricultural by-products are converted into a clean, energy-rich gas with excellent combustion characteristics. The process removes tars and avoids nitrogen dilution, resulting in a gas with high heating value and low emissions.

For industries that already operate solid fuel boilers, BioShare’s integrated gasification concept offers a fast-track pathway to fossil fuel independence. Rather than overhauling existing systems, synthetic biogas production can be seamlessly embedded within the plant’s current infrastructure—minimizing capital expenditure and project risk.

The resulting gas can be compressed and distributed locally, replacing fossil gas in burners, kilns, dryers, or other thermal applications—while dramatically reducing the plant’s carbon footprint. This makes synthetic biogas an ideal solution for sectors such as food processing, pulp and paper, chemicals, and ceramics—industries where clean, high-temperature heat is essential and electrification is not always practical.

Beyond its immediate climate benefits, synthetic biogas production supports energy security and resilience. By localizing fuel supply and reducing dependency on volatile gas markets, industries gain greater control over their energy costs and emissions strategy.

At BioShare, we enable industries to turn waste into value—transforming residual biomass into clean, renewable energy that powers production, cuts emissions, and drives long-term sustainability.

As we transition toward a carbon-neutral future, biofuels will remain a vital part of the energy mix—especially in areas where electrification is limited by technical, economic, or practical constraints. Heavy transport, maritime operations, aviation, and high-temperature industrial processes all depend on dense, storable fuels. For these sectors, renewable liquid and gaseous biofuels are not just a fallback—they’re a cornerstone of the sustainable energy system.

Importantly, biofuels also offer one of the most effective solutions for seasonal energy storage. While electricity demand and renewable supply often fall out of sync across the year, biofuels provide a flexible and dispatchable energy reserve. They can be produced when surplus biomass or electricity is available and stored for use during periods of low renewable output or high system stress—ensuring security of supply, grid balance, and energy system resilience year-round.

Biofuels derived from biomass also close the loop on biogenic carbon. When sustainably sourced, they offer significant climate advantages—replacing fossil fuels with low-carbon, renewable alternatives that perform on par or better in terms of combustion quality and emissions. Unlike fossil fuels, they contribute to circular carbon flows rather than adding new carbon to the atmosphere.

The thermochemical route to biofuel production is especially well suited to handle a broad spectrum of feedstocks—from forestry and agricultural residues to sorted fractions of municipal waste. It offers scale, flexibility, and performance that aligns with the climate goals of industrial players, energy providers, and policymakers alike.

At BioShare, we see biofuels as an essential complement to electrification—a tool for both decarbonization and energy system integration. With the right infrastructure and partnerships, they enable a new generation of climate-smart, energy-secure regions.

Biochar is gaining global attention as a powerful climate solution—providing a scalable, cost-effective way to remove carbon dioxide from the atmosphere while creating value-added products. Produced through thermochemical conversion of biomass, biochar is a stable, carbon-rich material that resists decomposition for hundreds to thousands of years. When applied to soil, stored in construction materials, or used in industrial applications, it offers a practical, measurable form of carbon capture and storage (CCS).

For CHP (combined heat and power) plants, biochar production is a unique opportunity. Unlike large-scale, capital-intensive CCS systems, biochar extraction represents a small- to medium-scale carbon removal solution with low investment thresholds. By integrating biochar production into existing energy infrastructure, plant operators can transform their facilities into CO₂-negative energy hubs—generating renewable power and heat while actively drawing down atmospheric carbon.

BioShare’s approach focuses on system integration to maximize both energy efficiency and biochar quality. By carefully managing process conditions—such as feedstock type, temperature, and residence time—our solution produces biochar with a high fixed carbon content and consistent physical properties, suitable for multiple applications.

Importantly, the thermal integration with boiler plants ensures that excess process heat is not wasted. Instead, it is harnessed to support power production, district heating, or drying processes—boosting overall system performance and reducing emissions.

Biochar enables facilities to move beyond fossil fuel substitution and into climate-positive operations—capturing carbon, generating revenue from by-products, and contributing to circular, regionally anchored value chains.

Whether your goal is carbon removal, soil regeneration, or sustainable materials, biochar offers a future-ready solution that turns residual biomass into environmental and economic value.

As the global energy transition gathers momentum, electrification is leading the way—but it cannot solve everything. In sectors where batteries are impractical or inefficient, electrofuels—also known as e-fuels or RFNBOs (Renewable Fuels of Non-Biological Origin)—offer a flexible, scalable solution for decarbonization.

Electrofuels are synthetic fuels produced by combining green hydrogen, generated through electrolysis of water using renewable electricity, with captured carbon dioxide—often from biogenic or atmospheric sources. The result is a suite of carbon-neutral fuels that are fully compatible with existing infrastructure and engines.

Electrofuels serve as a bridge between the power and transport sectors—storing renewable electricity in chemical form and enabling energy use in places where electrons alone can’t go.

They are especially critical in hard-to-abate sectors like aviation, shipping, heavy industry, and long-haul transport, where electrification is limited by energy density, range, or infrastructure constraints.

BioShare contributes to the electrofuel landscape by enabling cost-efficient, decentralized production through integration with biomass conversion systems. By coupling renewable hydrogen with biogenic CO₂ from gasification or pyrolysis processes, we facilitate the production of compliant RFNBO fuels at the 1–10 MW scale—ideal for regional hubs, industrial clusters, and utility-scale applications.

Biomass is more than just a fuel—it’s a complex and untapped source of high-value molecules. Within forestry and agricultural residues lie small but significant concentrations of fine chemicals that can be extracted and refined into valuable inputs for the cosmetics, pharmaceuticals, food, and specialty chemicals industries.

These bioactive compounds—such as polyphenols, terpenes, and organic acids—represent a unique opportunity to move beyond energy production and into biorefining, where every part of the biomass is used to its highest potential.

By extracting fine chemicals before thermochemical conversion, it is possible to capture this hidden value without disrupting the overall energy recovery process. For CHP plants already handling large volumes of biomass, this opens a new dimension of value-added utilization with minimal additional feedstock needs.

The key to success lies in smart integration. BioShare works to align the extraction of fine chemicals with the plant’s thermal and operational profile—ensuring that the impact on boiler load, fuel characteristics, and energy flows is carefully managed. This enables fine chemical recovery to become a viable and synergistic part of the plant’s overall performance, rather than a competing process.

With growing demand for bio-based and ethically sourced ingredients, fine chemical extraction offers CHP plants a pathway into new markets—while reinforcing their role as regional hubs for resource-efficient and sustainable production.

By unlocking the full molecular potential of biomass, BioShare helps clients rethink what’s possible from existing feedstocks—adding depth to the value chain and creating competitive advantages in the green economy.