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Crop residue

Crop residue refers to the non-edible materials remaining in after the of primary crops, including stalks, leaves, husks, roots, and seed pods from cereals, , and other agricultural produce. Globally, crop residues are produced at approximately 5 billion metric tons annually, with major contributors including , straw, rice straw, and sugarcane bagasse, primarily from leading producers like and . These materials play a critical role in by serving multiple functions, such as enhancing , providing feed, and supporting production. In agricultural systems, crop residues are essential for maintaining soil fertility and structure; when incorporated into the soil through practices like conservation tillage or no-till farming, they increase organic matter content, improve water retention, and reduce erosion by up to 80% in some cases. Leaving at least 25% of residues in the field is recommended to preserve soil stability and nutrient cycling, preventing degradation and supporting long-term productivity. However, excessive removal for uses like biomass energy can deplete soil carbon and microbial activity, necessitating guidelines like those from the USDA, which suggest sustainable removal rates of 30% or less based on factors such as soil type, climate, and tillage intensity to avoid productivity losses. Beyond , crop residues are a vital resource for in smallholder and subtropical farming systems, where they provide fibrous bulk feed for ruminants after treatments like ammoniation, which can increase digestible intake by up to 46% and improve organic matter digestibility by 17%, enhancing and yields. They also hold significant potential for , with materials like straw and converted into biofuels, reducing reliance on fossil fuels and avoiding from open burning. Effective management—balancing retention for with utilization for feed and energy—promotes a in agriculture, minimizing waste and supporting global amid growing demands.

Introduction and Fundamentals

Definition and Importance

Crop residue consists of the non-edible portions of left in agricultural fields following the harvest of primary crops, encompassing materials such as stalks, , husks, leaves, and roots derived from cereals, , , and other cultivated . These remnants emerge as a natural of the , where harvesting focuses on marketable yields while leaving structural and vegetative parts behind to undergo or management. As a vital , crop residue contributes significantly to by supplying that enriches nutrient content upon breakdown, enhances water retention through surface mulching that reduces evaporation and runoff, and fosters by creating microhabitats for soil microorganisms, insects, and other organisms essential to . Globally, agricultural systems generate approximately 4.2 billion metric tons of crop residue annually (2015–2020 ), underscoring its scale as a renewable source with potential applications beyond field management. Historically, in pre-industrial farming practices, crop residues were central to sustainable nutrient cycling within fallow-based systems, where they were routinely incorporated into soils or utilized as to recycle essential elements like and , maintaining productivity in the absence of fertilizers. This role highlights residues' foundational importance in early agricultural and long-term land .

Types and Sources

Crop residues are primarily classified into two categories: field residues and processing residues. Field residues refer to the non-harvested portions of crops left directly on the agricultural land after the primary product, such as grains, is collected; these typically include stalks, stems, leaves, husks, shells, roots, and cobs. Examples of field residues include wheat straw, (comprising stalks and cobs), and stems and pods. In contrast, processing residues arise from the or post-harvest of the main crop product and are generated at mills, gins, or factories; common instances are rice husks, sugarcane bagasse, and cotton bolls or gin trash. This distinction is important for management, as field residues remain while processing residues are often relocated. The of residue to the primary crop product varies by species and growing conditions, influencing the volume available for utilization. For , the grain-to-straw is approximately 1:1, meaning roughly equal masses of and straw are produced per . Similar patterns occur in other cereals, such as corn with a grain-to-stover of about 1:1.2 and at 1:1.5, while like soybeans exhibit ratios around 1:1.5 for pods and stems relative to seeds. These ratios are derived from empirical data on partitioning and are used to estimate residue yields from production statistics. Globally, cereal crops represent the dominant source of residues, accounting for the majority of total . For instance, annual residue from alone is estimated at 1.11 billion tonnes, while generates about 1.25 billion tonnes and 1.28 billion tonnes, based on averaged data from 2015–2020 aligned with FAO trends extending into 2020–2024. contribute notably, exemplified by residues (stems, leaves, and pods) totaling roughly 0.49 billion tonnes annually, and root crops add through tops, stalks, and leaves from crops like potatoes and . , a , produces residues such as bolls and stalks estimated at 20–30 million tonnes yearly from global lint of about 25 million tonnes in 2022. These estimates draw from FAO data, where global primary crop reached 9.6 billion tonnes in 2022, with cereals comprising over 50 percent of harvested area. Production volumes exhibit significant regional variability, driven by cropping patterns, climate, and farming intensity. dominates global output, generating approximately 70 percent of total residues due to the prevalence of intensive and systems; for example, alone accounts for 0.38 billion tonnes of residues and 0.24 billion tonnes from annually. In contrast, the lead in residues (0.41 billion tonnes in ) and (0.25 billion tonnes in ), while contributes notably to and root crop residues like and . These disparities reflect FAO-reported trends from 2020–2024, where Asian production surged amid population demands, contrasting with diversified systems elsewhere.

Properties and Characterization

Physical and Chemical Properties

Crop residues exhibit a range of physical properties that influence their handling, storage, and incorporation into . typically ranges from 40 to 70 kg/m³ for loose , such as or , increasing with smaller particle sizes and higher levels. content at is generally 10-20% on a basis for many residues after drying, though it can reach up to 75% immediately post- depending on and conditions. varies with and processing methods; for instance, unprocessed residues may have diameters of 1-5 mm, with finer distributions (0.65-1 mm) resulting from milling, which affects surface area and potential. Lignin content in cereal crop residues, such as wheat or rice straw, typically ranges from 15-25%, serving as a structural component that imparts rigidity and resistance to breakdown. This polyphenolic polymer varies across residues, with lower levels (around 16%) in straw compared to wood, influencing overall durability. Chemically, crop residues are primarily composed of organic matter with varying nutrient profiles. Macronutrient contents include nitrogen (N) at 0.5-2%, phosphorus (P) at 0.1-0.5%, and potassium (K) at 0.5-3% on a dry matter basis, with higher levels in legume residues compared to cereals. Micronutrients such as iron (Fe) and others are present in trace amounts, typically less than 0.1% each, contributing to soil fertility when residues decompose. The carbon-to-nitrogen (C:N) ratio is high, ranging from 40:1 to 100:1, which slows microbial decomposition due to nitrogen immobilization during early stages. Carbohydrate fractions dominate the chemical makeup, with comprising 30-40% and 20-30% of in most residues, providing the primary energy source for decomposers. These properties vary significantly by crop type, growth stage, and environmental conditions. residues like generally have lower nutrient contents and higher than pulses or oilseeds, while mature at exhibit elevated (up to 25%) compared to earlier stages. Environmental factors, including and during growth, can alter composition; for example, drier conditions may increase concentration, enhancing residue persistence. and timing further contribute to this variability, with taller or later-harvested often yielding denser, more fibrous residues.

Measurement Techniques

Field estimation techniques provide direct, on-site quantification of crop residue cover and amount, essential for assessing management practices in agricultural fields. The line-transect method is widely used, involving the extension of a 50- to 100-foot measuring tape or diagonally across crop rows at multiple locations, with intersections of residue noted at regular 1-meter intervals to calculate percentage cover as the ratio of hits to total points sampled. This approach yields reliable estimates for conservation tillage compliance, typically requiring 10-20 transects per field for representativeness. Photographic analysis offers a complementary visual method, where frames (e.g., 0.25-1 m²) are photographed from above, and images are analyzed using software such as SamplePoint to superimpose random or systematic points and classify residue versus coverage, achieving high precision with minimal equipment. Remote sensing expands measurement capabilities to landscape and regional scales, leveraging spectral differences between residue and bare soil. platforms like MODIS facilitate broad estimation through time-series analysis of normalized difference indices in the near-infrared spectrum, supporting global monitoring of residue retention trends. Unmanned aerial vehicles (drones) with multispectral cameras compute the (NDVI) to delineate residue cover, with studies from 2013-2023 reporting accuracies of 90-95% when calibrated against ground data, particularly effective for heterogeneous fields. Laboratory methods enable detailed of residue quality post-collection from field samples. weight follows protocols of oven-drying subsamples at 60-70°C to constant mass, yielding per unit area after accounting for moisture content. content is assessed via , such as optical emission (ICP-OES) after wet acid digestion, quantifying macronutrients like , , and to inform potential. For global-scale assessments, modeling integrates field and remote data; seminal approaches, such as those reviewing spectral unmixing and index-based estimation in van der Meer et al. (2013), provide frameworks for deriving residue production from statistics and retention rates. Updates in 2024 incorporate techniques, including unsupervised clustering on high-resolution imagery, to refine these models and reduce estimation biases across diverse agroecosystems. As of 2025, comprehensive reviews highlight integrated multi-level sensing approaches (, UAV, and ground-based) for enhanced crop residue measurement accuracy. Measuring crop residue faces challenges from spatial variability influenced by terrain , , and species, which can alter residue distribution and spectral signatures. Manual methods like line-transects exhibit variability due to sampling inconsistencies and operator subjectivity in complex landscapes.

Agricultural Management

Soil Incorporation and Tillage Practices

incorporation of residues involves integrating plant materials left after into the profile or retaining them on the surface to support sustainable agricultural practices. Conventional methods, such as moldboard plowing or disking, fully incorporate residues by turning the , typically burying 100% of the material to depths of 15-30 cm, which facilitates but increases disturbance. In contrast, conservation systems, including no-till and reduced-till approaches, minimize inversion while retaining 30-100% of residue as surface , promoting long-term stability through practices like direct seeding into undisturbed fields covered by previous remnants. Residue burning, once common for rapid field clearance, has become outdated and is banned in many regions since the due to air quality concerns, with increasing enforcement in areas like northern , where burning has been prohibited since 2015 but continues to occur, and in California's leading to near-total prohibitions by 2025. These incorporation techniques offer key benefits, including enhanced water management and . Surface residue mulches in conservation tillage can increase water infiltration rates by up to 30%, reducing runoff and improving moisture retention for subsequent crops. Additionally, the mulch layer suppresses emergence by limiting light penetration and altering temperature fluctuations, often reducing biomass by 50-90% in high-residue systems. To ensure uniform distribution, specialized equipment such as combine-mounted straw choppers or flail shredders processes residues into smaller pieces, spreading them evenly across the field to avoid patchy coverage that could hinder planting. Globally, no-till practices—retaining substantial residue cover—have been adopted on over 15% of as of 2025, reflecting widespread recognition of their role in sustainable farming. As of 2025, initiatives like the ICAR review meeting highlight ongoing efforts to promote sustainable residue management globally. Despite these advantages, challenges persist in residue management. High-residue fields under conservation tillage can cause equipment clogging, particularly with no-till or drills, where uncut stalks lead to hairpinning or residue buildup in seed furrows, necessitating modifications like row cleaners or adjusted tine spacing. During the initial transition to these systems, crop yields may dip by 1-5.7% in the first few years due to cooler soils and altered availability, though long-term often stabilizes or improves. Incorporated residues also contribute to mineralization over time, releasing essential elements like for uptake, though this process is detailed in subsequent biochemical analyses.

Nutrient Cycling and Mineralization

Nutrient cycling through crop residue mineralization involves the microbial decomposition of , releasing essential nutrients such as (N), (P), and (K) in inorganic forms available for plant uptake. and fungi primarily drive this process by breaking down complex organic compounds into simpler inorganic ions, including (NH₄⁺), (NO₃⁻), (PO₄³⁻), and (K⁺). This conversion enhances by recycling nutrients that would otherwise be lost, with microbial activity temporarily immobilizing nutrients before gradual release. The mineralization process for follows a sequential pathway: organic N is first converted to NH₄⁺ through ammonification, then oxidized to NO₃⁻ via under aerobic conditions. However, up to 20-30% of the mineralized N can be lost through of NO₃⁻ or to gaseous forms like N₂ and N₂O, particularly in wet or poorly aerated soils. Mineralization rates vary by residue type; for straw with high carbon content, only 10-15% of total N is typically mineralized over 1-2 years due to initial microbial , while legume residues like peas release about 35% of their N in the same period, owing to higher initial N concentrations. Key factors influencing these rates include the carbon-to-nitrogen (C:N) ratio of the residue, content, and microbial communities. Residues with C:N ratios exceeding 30:1, in , promote N as microbes prioritize carbon , delaying net release; in contrast, low C:N ratios below 20:1 in facilitate rapid mineralization. High content, prevalent in , slows breakdown by resisting enzymatic attack, extending the release timeline. Fungi, such as Ascomycetes and Basidiomycetes, dominate of high- residues using specialized enzymes like , while handle initial stages of simpler compounds. Temporal dynamics show rapid initial release, with up to 50% of available N from residues becoming mineralized in the first growing season, followed by slower mineralization over subsequent years as recalcitrant components persist. Recent 2020s studies indicate that warmer soils, driven by climate change, can accelerate mineralization rates by approximately 20%, potentially doubling with every 10°C increase, according to the Q10 temperature coefficient commonly observed in soil processes, though this heightens risks of nutrient losses in vulnerable systems.

Efficiency of Nutrient Uptake

The efficiency of uptake from crop residues refers to the proportion of nutrients released through that subsequent crops can absorb and utilize for growth. For (N), recovery rates from incorporated residues typically range from 10% to 20% in the first year following application, increasing over multiple seasons, comparable to initial recovery from synthetic fertilizers under similar conditions. (P) and (K) uptake efficiencies from residues range from 30% to 60%, with higher rates observed when residues are deeply incorporated into the to enhance contact with root zones and microbial activity. Several factors influence these uptake efficiencies. Residue placement plays a key role; surface retention in zero-till systems can initially reduce uptake by 10-15% due to slower and potential by surface microbes, though benefits accrue over time as residues integrate into the . enhances overall availability from residues by diversifying microbial communities and improving , leading to more synchronized release with crop demand. Field trials from 2017 to 2024 have demonstrated overall uptake efficiencies of 40-70% for key nutrients in rotated systems incorporating residues, particularly in cereal-based rotations. Compared to synthetic fertilizers, crop residues offer a slower, more sustained nutrient release profile, which minimizes losses through leaching or volatilization while matching plant needs over extended periods. This gradual mineralization reduces environmental risks associated with rapid fertilizer application. Nutrient uptake efficiency is commonly calculated using the formula: \text{Uptake Efficiency} = \left( \frac{\text{Nutrient in Plant}}{\text{Nutrient Applied}} \right) \times 100 where "Nutrient in Plant" represents the amount absorbed by the biomass, and "Nutrient Applied" includes the total from residues or fertilizers. Recent advancements in have improved monitoring of uptake from residues. Since 2022, in-situ sensors, such as electrochemical probes and IoT-enabled NPK detectors, enable real-time assessment of uptake dynamics, allowing farmers to adjust residue management for optimal efficiency without excess inputs.

Environmental Impacts

Soil Health and Erosion Control

Crop residue retention significantly enhances by increasing content, which typically rises by approximately 0.5% over five years in no-till systems with residue management. This accumulation improves through better aggregate stability and supports greater microbial diversity in response to residue incorporation. Additionally, the added boosts soil water-holding capacity by 10-30%, enhancing infiltration and reducing losses, thereby promoting . In , surface from crop residues acts as a protective barrier, reducing and by 50-90% in sloped fields by dissipating raindrop impact, slowing runoff, and forming residue barriers that limit particle transport. For instance, no-till systems with 55% residue cover on 5% slopes have achieved up to 86% reduction. Case studies from the U.S. illustrate these benefits, where post-1990s adoption of no-till and residue retention contributed to a 43% overall decline in cropland between 1982 and 2003. Over the long term, residue management reduces by lowering by 5-10% and increasing , which alleviates root restriction and improves . It also aids stabilization, particularly in acidic soils, through liming effects from residue that raise by up to 0.5 units over extended periods. In regenerative farming practices of the 2020s, integrating crop residues with cover crops has further mitigated soil loss in the , where only 15% of fields use sustained no-till as of 2021, yet such combinations reduce erosion rates and support yield stability amid ongoing affecting 35% of the region's soils (with national no-till adoption reaching ~28% by 2022). practices that retain residues, such as no-till, amplify these outcomes by minimizing disturbance.

Carbon Sequestration and Climate Mitigation

Crop residues play a significant role in carbon sequestration by enhancing soil organic carbon (SOC) buildup when incorporated or retained on the soil surface. Practices such as residue incorporation can contribute approximately 0.21 t C ha⁻¹ yr⁻¹ to SOC stocks, while broader organic matter inputs from residues may achieve up to 0.6 t C ha⁻¹ yr⁻¹, depending on soil type, climate, and management intensity. Globally, improved residue management as part of agricultural practices holds a sequestration potential of 0.44–0.68 Gt C yr⁻¹, equivalent to about 1.6–2.5 Gt CO₂e annually, helping to mitigate climate change by storing atmospheric carbon in soils. Key mechanisms underlying this sequestration include reduced decomposition rates in no-till systems, where crop residues promote the formation of stable soil aggregates that physically protect organic carbon from microbial breakdown. In no-till farming, residue retention slows organic matter turnover, allowing carbon to accumulate in macroaggregates and microaggregates over time. Additionally, converting crop residues into biochar through pyrolysis sequesters 50–80% of the original carbon in a highly stable form that persists in soils for centuries, preventing its release as CO₂. Residue mulching further supports climate resilience by improving soil moisture retention, which enhances drought tolerance in crops and indirectly sustains carbon inputs under variable weather conditions. In modern agricultural contexts, crop residue management is increasingly integrated into frameworks, enabling farmers to earn credits through post-2020 policies and voluntary markets that reward verified increases. For instance, methodologies approved since 2020 quantify from residue retention and no-till practices, providing incentives in regions like the and . However, climate warming poses challenges, as elevated temperatures accelerate residue mineralization, potentially offsetting 10–20% of gains in major croplands like the through enhanced decomposition.

Economic Aspects

Valuation and Costs

Crop residues hold intrinsic economic value primarily through their nutrient content, which serves as a natural equivalent when retained in the field. For instance, one of wheat straw typically contains nutrients valued at $15-35 in terms of (N), (P₂O₅), and (K₂O) costs, based on prices from 2022-2025 of approximately $0.65/lb for N, $0.90/lb for P₂O₅, and $0.40/lb for K₂O as of November 2025. Similarly, for , is estimated at $40 per as of 2025, encompassing 37 lbs N, 3.5 lbs P₂O₅, and 33 lbs K₂O. In a global context, rice straw in regions like provides $15-35 per in NPK value. The of removing crop residues arises from lost benefits and depletion, often ranging from $25-40 per in replacement costs to maintain . For example, harvesting 3-4 s of per incurs $120-162 per ($297-400 per ) in losses alone. Global market prices for baled in 2025 vary by region but generally fall between $50-120 per , with in the UK averaging £80 per (approximately $104 USD) and big square bales in the reaching up to $200 per for premium qualities. These prices reflect demand for uses like animal bedding, adjusted for 2025 inflation and regional supply tightness. Management costs for crop residues include tillage operations, which average $15-25 per for conventional incorporation, while no-till practices reduce this to $10-15 per through minimized passes. Burning residues, restricted under post-2015 regulations in many regions, incurs fines of $78-111 per in areas like due to air quality mandates. However, residue retention yields economic benefits, including 2-5% long-term increases from improved and cycling, translating to $50-200 per in savings on inputs and higher outputs. For context, these gains align with enhanced uptake efficiencies observed in systems. Economic models, such as cost-benefit analysis (CBA), demonstrate that residue management practices like no-till yield positive net returns. For example, incorporating residue value as a source results in a benefit-cost ratio of 1.14 and a (NPV) of $220 per over multi-year horizons compared to conventional . In broader assessments, NPV for residue retention reaches $100-200 per over 10 years, turning positive after 3-4 years as yield and soil benefits accrue, even after accounting for initial equipment costs. These models emphasize the long-term profitability of sustainable practices over short-term removal incentives.

Markets and Trade

The markets for crop residues primarily revolve around their use as biomass feedstocks, , and raw materials for bio-based products, with domestic trade dominating due to high transportation costs limiting long-distance movement. , agricultural residues, including , represent a significant domestic market potential, with an estimated 140–180 million dry tons available annually at a reference price of $70 per dry ton, equating to a supply value of approximately $9.8–12.6 billion. This trade is largely internal, focused on regional collection for local and sectors. Internationally, leads in production volumes, generating over 700 million tons of rice annually, with 91% of global rice straw originating from the region; however, exports remain modest at 10–20 million tons, primarily to neighboring countries for and industrial applications. Emerging models in the 2020s have begun integrating residue-to-product loops, such as in , where rice straw is repurposed into and through farmer cooperatives, enhancing local value chains and reducing waste. Supply chains for crop residues involve coordinated collection, , and , often challenged by the bulky nature of the material. Collection typically start with baling, which costs $20–25 per ton for or similar residues, including raking, baling, and on-farm hauling. Quality standards are critical to maintain value, with baled residues required to have content below 15% to prevent spoilage and ensure suitability for transport and end-use, as higher levels can lead to microbial degradation. The sector is expanding these chains, with EU reports projecting growth in residue utilization to support a of up to €2.6 trillion by 2030 (including services), driven by policies promoting sustainable sourcing for and energy. In practice, these chains emphasize densification techniques like baling to reduce volume by up to 50%, facilitating efficient road or to facilities. Key challenges in crop residue include , which aligns supply with periods and creates demands, and high costs comprising 20–30% of total delivered value due to low . These factors limit economic viability beyond 100 miles from source, exacerbating supply inconsistencies in rural areas. Policy incentives have addressed some barriers; in , post-2018 subsidies under the Crop Residue Management Scheme provide 50% cost coverage for machinery for individual farmers (up to 80% for groups), with revised guidelines for 2025 and over 100,000 units distributed cumulatively to curb burning and boost . Similarly, introduced over 4 billion yuan in subsidies in 2019 for residue management equipment, promoting collection for and reducing open burning by incentivizing farmers, with ongoing programs in 2025. These measures have spurred market growth but require ongoing investment to mitigate logistical hurdles.

Industrial and Alternative Uses

Biofuel Production

Crop residue, primarily such as and stalks from cereals like , , and corn, serves as a key feedstock for second-generation due to its abundance and renewable . The conversion process typically begins with pretreatment to break down the complex structure of , , and , making sugars accessible for microbial . , a thermal-mechanical method, is widely used for this purpose, as it disrupts lignocellulosic matrices at high pressure and temperature (around 180–240°C for 5–10 minutes), increasing enzymatic accessibility by up to 50–100% compared to untreated . Following pretreatment, enzymatic releases fermentable sugars, which are then converted via or bacterial into bioethanol, with typical yields ranging from 200 to 400 liters per of dry residue depending on the feedstock and process optimization. Alternatively, of pretreated residues produces , primarily , at yields of 30–50 cubic meters per of volatile solids, offering a pathway for . The global potential for outputs from crop residues is substantial, particularly for and value-added s. From straw alone, approximately 355 kilotonnes of could be produced annually based on assessments. This lignocellulosic composition, rich in fermentable carbohydrates, facilitates such conversions while yielding as a , estimated at 11 million tonnes globally, which can be repurposed for or materials like adhesives. and are leading producers, together accounting for approximately 24% of the world's crop residue resources suitable for , driven by their high agricultural outputs of and . Recent advances have propelled toward commercialization, emphasizing from crop residues. Facilities like Clariant's sunliquid® plant in began in 2022, processing 250,000 tonnes of agricultural residues annually to yield 50,000 tonnes of , though it faced operational challenges leading to closure in 2023 before being restarted by Corden BioChem in May 2025. These developments support carbon-neutral claims, as lifecycle analyses indicate that reduce by 60–80% compared to fossil fuels, accounting for cultivation, conversion, and end-use. Integrated biorefineries further enhance viability by co-producing or , minimizing waste and improving overall energy returns.

Animal Feed, Bedding, and Other Applications

Crop residues serve as a vital resource for , particularly in systems where they supplement in regions with limited grazing land. In developing countries, crop residues contribute significantly to , accounting for approximately 24% of the total feed energy suitable for globally. For instance, is commonly ensiled to improve its and ; treatment enhances the crude protein content and digestibility of ensiled corn residues, making them more suitable for sheep and other . However, untreated residues like stover have limitations due to high content, which reduces voluntary intake and requires supplementation with or to boost degradability and prevent nutritional deficiencies. As bedding material, crop straws such as , , and varieties provide absorbent and comfortable flooring for , helping to manage and maintain in barns. Chopped straw exhibits an absorbency of about 2.1 times its weight, while straw reaches up to 2.5 times, effectively reducing bacterial growth risks in animal housing. Beyond , straw serves as a key substrate in cultivation; for example, composted straw supports the growth of , with the spent material often repurposed as feed due to its improved nutrient profile post-cultivation. Other applications of crop residues include manufacturing composite materials. Rice straw has been used since the early 2000s to produce particleboard and medium-density fiberboard (MDF), with panels incorporating up to 20% rice straw particles achieving mechanical strength comparable to traditional wood-based boards, meeting standards like ANSI A208.2 for interior use. Emerging uses involve bioplastics from , with pilot programs launched in 2023 to produce biodegradable and prototypes evaluated through 2025 for mechanical properties suitable for single-use items. These applications promote by minimizing waste through integrated farm systems, where efficient residue utilization can reduce overall and support circular economies, such as in smallholder operations that repurpose residues to lower feed costs and environmental impacts.