Avoided emissions cannot be credibly claimed for seaweed-derived biostimulants until consistent, quantifiable reductions in synthetic fertilizer use are demonstrated and unresolved efficacy and composition characterization gaps in this subsection are critical.

Strain development

There are not enough scalable, low‑risk strains for production

There is a lack of seaweed strains that can provide high yields at low risk to wild populations. Breeding or engineering seaweed for higher yields of biomass and/or target compounds can scale production to industrial levels while minimizing crop-to-wild interactions (Hwang et al., 2019; Li et al., 2016; Wang et al., 2016; Zhang et al., 2007; see Hatch Blue’s Seaweed Insights Platform, University of Connecticut’s National Seaweed Nursery Directory).

Characterizing and mapping seaweed chemical composition

Seaweed bioactive compounds important for product performance are partially characterized

The compounds in seaweed responsible for improving crop yield remain uncertain, highlighting the need for robust R&D to measure and track the precise chemical composition of seaweed-based agriculture supplements that elicit the desired environmental performance for specific crops. ‘Omics approaches (e.g., genomics, transcriptomics, metabolomics) using strains with and without candidate genes that produce the chemical compound of interest can validate chemical characterization (Geelen and Xu, 2020).

Cultivation techniques and scale-up

There is not enough seaweed being produced, and at consistent quality, to enable sustainable industry growth

Please see the chapter titled, “Cultivation and Drying Considerations” for more information.

Seaweed-based agricultural supplement production is energy intensive and inconsistent in quality

Scaling seaweed-based agricultural supplements faces challenges of high-energy demand in production, consistency in performance, and variability in seaweed composition across seasons and environments. For example, conversion methods of Kappaphycus alvarezii extract can account for 65–99% of total environmental impacts yet it still falls short of substituting for traditional fertilizers (Ghosh et al., 2015; I. Singh et al., 2018; S. Singh et al., 2016; Table 5). More research is needed to identify and test low-energy production lines, product stability and shelf-life, and if/how conversions that produce different seaweed-based products can be integrated to lower costs.

The lifecycle emissions and cost competitiveness of seaweed-derived supplements relative to synthetic fertilizers depend on addressing the gaps in processing and conversion technologies.

Processing and Conversion Technologies

Processing methods are not optimized to minimize emissions and maximize extraction yield

Processing dominates the carbon footprint for liquid extraction production, meriting engineering/technology innovation to reduce energy needs and explore new low-carbon technologies (e.g., MAE, UAE, EAE). Seaweed meal/mulch conversion would benefit from waste valorization of existing seaweed product workstreams. Biochar needs research into low-energy conversion methods to make it more economically viable (e.g., EAE; Garcia-Vaquero et al., 2017; Ahmed et al., 2023).

Lack of standardized extraction and storage methods inhibit consistent product efficacy

A big challenge to scaling seaweed-based agriculture supplement production is inconsistent shelf-life. The extraction process can result in variable bioactive compositions, compounded by unstable bioactivity while in transport and storage before use. Research is needed to map how a seaweed’s chemical composition changes over space and time so that production lines can standardize best practices for conversion and stabilize the final product for a longer shelf life (Geelen and Xu, 2020).

Seaweed-derived supplements cannot displace synthetic fertilizers at volumes relevant to agricultural decarbonization until consistent data including agronomic performance data, standardized efficacy metrics, and credible cost trajectories exist to attract the commercial-scale investment needed to move beyond niche production.

Life Cycle Analyses (LCAs) need to cover more species, regions, and processing workstreams

More LCAs covering the end-to-end product lifecycle are needed to quantify the full mitigation potential and identify energy hotspots. Standardized methods to account for carbon sequestration through seaweed production and GHG release at product end-of-life should be developed. This can be achieved using exemplar species to leverage existing research literature. Furthermore, LCA analyses on continuous processing would help assess sustainability and scaling potential opportunities (Waqas et al., 2024).

Economic viability and high costs

Investment in production lines are hindered by limited understanding of a technology’s efficiency and feasibility at scale

Securing investment for seaweed-based agricultural supplements can be challenging due to uncertainty in product performance and market competitiveness (World Bank, 2023). Piloting seaweed-production lines, including farms and processing facilities, alongside market confidence studies will reveal the true economics and performance in different contexts. Innovative financing (e.g., market-tailored subsidies, carbon credits, impact investing) and business models (e.g., integrated multi-product cooperatives, commodity trading firms, hedge instruments, etc.) alongside different distribution pathways can unlock funding and de-risk investment (DeAngelo et al., 2023).

Lack of transparency in performance and sourcing of products

Seaweed-based agriculture supplements offer reputational capital in the form of their organic pedigree and regenerative potential, but only if they are demonstrated to meet these criteria. Therefore, seaweed-based agriculture supplements should demonstrate transparency in sourcing and production. Certification (e.g., OMRI, EU Organic) and buyer specifications (e.g., locally harvested) can help encourage social legitimacy and whether benefits reach coastal producers, smallholder farmers, and Indigenous harvesters in addition to upstream processors and large-scale distributors.

Regional differences

Awareness and buy-in for new agricultural products takes time and trust

For instance, farmers in Europe prioritize drought-resilient products due to widespread soil degradation, while those in India favor low-cost, salinity-reducing products. Australian mechanized farms prefer dry meal application while East African farms favor water-soluble products for manual irrigation systems (Battacharyya et al., 2015; Margal et al., 2023; World Bank, 2023). Therefore, promoting buy-in demands marketing and financing campaigns that are tailored to different user needs, priorities, and access points. Performance trials should be carried out by entities that are trusted by product users and hold no conflicts of interest with product success.

Siloed development and limited stakeholder engagement impede social legitimacy, making partnerships essential to demonstrate place-based benefits

Product user buy-in grows when evidence backs performance claims, mandating locally relevant demonstrations of product efficacy and safety through site visits, demonstration events, and public engagement. Integrating indigenous and traditional knowledge with campaigns to build literacy of the benefits of agricultural supplements can grow social legitimacy. Transparent communication about technology and sustainability practices, including energy use and packaging, can further build stakeholder trust and acceptance (World Bank, 2023).

The addressable market for seaweed-derived fertilizer alternatives cannot reach the scale needed for meaningful synthetic fertilizer displacement while inconsistent regulatory classification of biostimulants across jurisdictions creates compliance barriers that slow adoption in the major agricultural markets where substitution impact would be greatest.

Regulations and Standards

Lack of standards on classification and performance hamper adoption

Seaweed-based agriculture supplements are recognized under different national/international standards. The EU’s Fertilizing Products Regulation (2019/1009) explicitly includes seaweed extracts as “plant biostimulants,” while organic certification schemes (e.g., USDA/NOP, EU organic) permit seaweed amendments but do not classify them as fertilizers. Regulatory clarity can support incentives—such as subsidies, carbon credits, or clear labeling standards—which then strengthen markets. Governments can also link use of seaweed-based agriculture supplements to food security and climate resilience to open new funding pathways.

Dis-harmonized pathways can hamper scaled development, production, and regulation

Harmonized and credible pathways can help legitimize seaweed-based agriculture supplement production and regulation (Campbell et al., 2020). These pathways can be co-designed with farmers, harvesters, Indigenous communities, and scientists in ways that align standards and laws to ensure sustainable production and procedural legitimacy. Importantly, pathway development should be evidence-based and verified to avoid any presumption of “greenwashing” (Mather and Fanning, 2019).