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Bottom trawling


Bottom trawling is a method that deploys heavy nets towed along the seafloor to capture demersal species, including groundfish like and , as well as such as and . The nets, equipped with weighted footropes or rollers to maintain bottom contact, are dragged at speeds of 1 to 7 knots, herding fish into the codend for retention while often disturbing sediments and non-target organisms in their path. Primary variants include trawls, which use hydrodynamic to spread the net mouth, and trawls, which rely on rigid beams for stability, each exerting distinct pressures on benthic habitats depending on gear design and substrate type. Originating in medieval around the with early beam trawls in the , bottom trawling evolved through technological advancements, including the adoption of otter boards in the early , enabling larger-scale operations by sailing vessels and later motorized fleets. By the mid-20th century, it had industrialized globally, contributing to expanded fisheries in regions like the starting in the late . Today, bottom trawling accounts for approximately 19 million tonnes of annual landings, representing about one-quarter of global wild marine capture fisheries, underscoring its role in supplying protein to billions despite varying regional regulations. While effective for targeting abundant demersal stocks and supporting economic fisheries, bottom trawling generates significant due to its physical disturbance of ecosystems, which empirical studies link to reductions in benthic , habitat homogenization, and elevated rates often exceeding 20-50% of total catch in some operations. Peer-reviewed meta-analyses indicate variable recovery potential in disturbed areas, with sandy substrates rebounding faster than biogenic reefs, though repeated trawling can impede and alter carbon cycling by resuspending and potentially releasing stored CO2 from sediments. These impacts, quantified through , highlight trade-offs between harvest yields and long-term integrity, prompting debates on spatial management and gear modifications to mitigate effects without forgoing the method's productivity.

Definition and Overview

Method and Principles

Bottom trawling employs a conical or funnel-shaped net towed along the seabed to capture demersal fish and shellfish that inhabit or feed near the ocean floor. The method relies on the net's groundgear—a weighted footrope or roller rig—maintaining contact with the substrate to disturb sediment and benthic organisms, herding them upward into the path of the advancing net. This herding principle exploits the escape responses of target species, such as flatfish, cod, and shrimp, which flee the disturbance rather than burrowing deeper. Towing speeds typically range from 2 to 4 knots, with haul durations varying from 30 minutes to several hours depending on vessel size, target depth, and gear configuration. The horizontal opening of the net mouth is achieved through two primary mechanisms in bottom trawls: otter boards or a rigid beam. In otter trawling, the dominant form, large hydrodynamically shaped doors (otter boards) attached to towing warps plane outward under water flow, spreading the net laterally up to 100 meters or more while the vertical dimension is maintained by buoyant headline floats opposing the weighted groundrope. Beam trawling, alternatively, uses a steel beam—often 10-15 meters long with ground-contacting shoes at each end—to rigidly hold the net open, eliminating doors but requiring heavier construction suited to smaller vessels and finer substrates. Pair trawling, a variant of otter trawling, employs two vessels to tow a single net without doors, relying on the angled warps for spread and allowing deeper water operations. Operational principles emphasize bottom contact for efficacy, with gear modifications like rock-hopper rollers or doors adapting to varied seafloor topographies—sandy flats, rocky reefs, or slopes—to minimize snags while maximizing catch efficiency. The trawl's forward sections, including sweeps and doors, primarily function to herd rather than enclose, as the net's tapered codend concentrates escaping for retrieval. Empirical studies confirm that otter trawls cover broader areas per tow than trawls due to greater spread, though both disturb plumes extending meters behind the gear. These designs prioritize capturing low-swimming through physical disruption over selective luring, distinguishing bottom trawling from pelagic or trap-based methods.

Global Prevalence and Catch Statistics

Bottom trawling accounts for approximately 25 percent of global wild catch, equivalent to an estimated 19 million tonnes annually as of the late 2010s, with recent analyses confirming a share of around 26 percent of fisheries landings. This method targets demersal species on continental shelves and slopes, contributing significantly to the harvest of groundfish, , and other bottom-dwelling organisms, though exact volumes vary by reconstruction methodology due to underreporting in official FAO data. The practice is geographically concentrated, with over 99 percent of bottom trawling occurring within national exclusive economic zones (EEZs) rather than high seas, primarily on the world's continental shelves where suitable habitats exist. It prevails in regions with extensive shelf areas, such as the Northwest Pacific, Eastern Central Atlantic, and parts of the , but is absent or restricted in deep-sea or protected areas lacking demersal stocks. Globally, bottom trawling effort has remained stable in recent decades, though localized declines occur due to stock depletions or regulatory measures, while expansion persists in developing Asian fisheries. Ten countries account for 64 percent of the global bottom trawling catch, dominated by Asian nations including , , , and , which together lead due to large fleets targeting high-value demersal species like , , and prawns. European countries such as , , and also feature prominently, reflecting industrialized fleets in the Northeast Atlantic and . In contrast, many and small nations report minimal domestic bottom trawling but experience foreign-flagged operations capturing over 90 percent of their trawl landings in some cases. These patterns underscore bottom trawling's role as a high-volume industrial method, reliant on fuel-intensive vessels operating in productive but vulnerable shelf ecosystems.

Historical Development

Origins and Early Adoption

The earliest documented references to bottom trawling appear in during the 13th and 14th centuries, where rudimentary trawls—nets dragged along the using a wooden to keep the mouth open—were employed by fishermen in regions including the , , , , , and the . Protests against these practices, citing concerns over disturbance and , date back to this period, as recorded in complaints during the reign of Edward III in around 1376. Beam trawling, the predominant early form, involved small vessels towing nets close to shore, limiting range and efficiency until the late . In , the method gained traction among Devon fishermen before spreading to ports like , , and by the 1830s, enabling captures of and other demersal using wooden beams up to 12 meters long. Adoption expanded in the from the 1820s, driven by growing demand for , though it remained artisanal and sail-powered until steam vessels in the mid-19th century increased operational scale. Early experiments with powered trawling occurred in the 1850s, such as the steam vessel fitted with beam trawls at in 1858, marking a shift toward mechanization that facilitated broader adoption across by the 1870s. This evolution from medieval sporadic use to 19th-century laid the groundwork for industrial bottom trawling, though initial uptake was regionally concentrated in temperate Atlantic fisheries.

Technological Evolution and Expansion

Bottom trawling gear evolved from fixed beam trawls, used since the in the , to more efficient trawls in the late , enabling larger net openings without heavy beams. The trawl, utilizing hydrodynamically shaped boards ( boards) to spread the net mouth via water pressure and vessel tow, was patented in 1894 by James Scott of Granton, , though similar concepts emerged in the in . This innovation reduced gear weight, allowing steam-powered vessels to deploy bigger nets over wider areas, marking a shift from labor-intensive beam trawling limited by sail power and beam size. The advent of trawlers in the accelerated adoption, with vessels maintaining constant speeds for consistent net herding by otter boards, unlike variable winds in sail era. By the early , engines replaced , extending trip durations and range, while synthetic materials post-1940s improved net durability and reduced drag. technologies, including and echo sounders, transitioned to commercial use, enhancing fish detection and navigation for deeper, offshore operations. Post-war industrialization drove massive expansion, with factory trawlers—equipped with onboard processing and freezing—emerging in the 1950s, enabling fleets to harvest, process, and store catches at sea for weeks or months. This scaled up operations, particularly in the North Atlantic and Soviet fleets, where vessel numbers surged; for instance, the USSR built over 1,000 large trawlers by the 1970s. Globally, bottom trawling fleets proliferated into new regions like the Indian Ocean and South Pacific by the 1960s-1970s, fueled by demand for whitefish and shrimp, accounting for approximately 25% of marine landings by the late 20th century. Further refinements, such as rockhopper gear in the for uneven and twin trawling rigs doubling effort per vessel, intensified pressure but expanded catch potential. By the , GPS and acoustic sensors optimized towing paths, while vessel sizes grew to over 100 meters, with global bottom trawl effort sweeping an estimated 3.6 million km² of annually as of 2018 data. These advancements correlated with a tripling of trawled area since the , reflecting efficiency gains that propelled bottom trawling from coastal craft to industrial dominance.

Gear and Techniques

Primary Types

Bottom trawling gear is categorized primarily into three types based on the mechanism used to maintain the horizontal opening of the net: beam trawls, otter trawls, and pair trawls. These distinctions arise from variations in how the net is spread and towed along the to capture demersal species. Beam trawls employ a rigid beam, typically constructed from or wood and spanning 4 to 12 meters, to hold the mouth open while the trawl is dragged across the bottom. The beam's ends are fitted with shoes or rollers that contact the , elevating the beam slightly to allow passage over obstacles, and ground ropes or chains along the 's lower edge herd upward into the codend. This type is suited for rough or uneven , such as those with or shells, and is commonly used in inshore targeting like or , with vessels often smaller than those for other trawls. Beam trawls exert concentrated pressure on the due to the beam's contact points, potentially causing localized disturbance. Otter trawls, the most prevalent form of bottom trawling, utilize hydrodynamically shaped otter boards (or doors) made of , wood, or composite materials, weighing 500 to 2,000 kilograms each, to spread the horizontally via hydrodynamic lift and water flow. These boards are connected to the vessel by warps and positioned at the net's sides, while sweeps and ground gear maintain vertical opening and bottom contact; the setup allows towing at speeds of 2 to 4 knots over sandy or muddy substrates. Otter trawls account for the majority of global bottom trawl catches, enabling efficient coverage of larger areas compared to beam trawls, and are deployed by single vessels in offshore fisheries for species like , , and . Pair trawls involve two vessels towing a single without otter boards or beams, relying on the warps from each boat to provide horizontal spread through angled tension and the vessels' separation, typically 100 to 300 meters apart. This method reduces the need for heavy onboard gear, allowing lighter vessels to operate, and is effective for schooling over soft bottoms, with towing speeds similar to otter trawls. Pair trawling is less common than otter trawling but used in regions like the for targeted species, offering potential gains due to the absence of doors.

Net Design and Operation

Bottom trawling nets are constructed as cone-shaped bags with a wide forward opening that tapers to a closed codend for retaining catch. The primary components include the wings at the mouth, the central body with progressively smaller sizes to guide rearward, and the codend with small mesh to hold target species while allowing water drainage. Mesh configuration often features larger meshes in the forward sections to permit of juveniles and non-target small organisms, enhancing selectivity. Ground gear along the footrope, such as rollers or rockhoppers, maintains bottom contact while minimizing snags on uneven seabeds. In otter trawls, the dominant type, horizontal mouth opening is achieved via large hydrodynamic otter boards (doors) connected to the vessel's warps and to the net wings by sweeps or bridles, which spread the net laterally as the vessel tows at speeds typically 2-4 knots. Vertical opening results from the buoyant headline buoyed by floats and the weighted ground gear, creating a height of 1-5 meters depending on design and target depth. During operation, the trawl is deployed astern, doors plane outward under hydrodynamic force, and the net is herded along the , funneling and into the codend over durations of 1-6 hours before hauling. Beam trawls employ a rigid , often 4-12 long and constructed of or , to hold the mouth open horizontally without doors; the beam is towed via or trawl heads on the . The hangs from the beam, with similar cone body and codend, but frequently incorporates tickler chains ahead of the footrope to disturb buried like or . Operation suits shallower, smoother grounds, with towing by single vessels and reduced reliance on vessel power for spreading, though beam weight demands robust winches for handling. Modern designs incorporate selectivity devices, such as escape panels or grids excluding larger like turtles or sharks, and acoustic or camera systems for to optimize operation and reduce discards. Net materials are predominantly knotted or twine for durability against abrasion from contact.

Economic and Social Contributions

Role in Global Food Supply

Bottom trawling contributes substantially to the global supply of , accounting for approximately 26% of marine capture fisheries production worldwide. This equates to around 19-24 million tonnes of and landed annually, representing about one-quarter of total wild marine landings. These catches primarily consist of demersal species such as , , , and , which form a key source of animal protein, particularly in coastal and developing regions where constitutes a significant dietary component. The method's efficiency in harvesting benthic resources supports by providing affordable, nutrient-dense protein to billions. In 2022, global capture fisheries totaled 92.3 million tonnes, with bottom trawling enabling access to shelf ecosystems that yield high-biomass demersal stocks otherwise underutilized by surface or pelagic methods. Studies indicate that without bottom trawling, replacement protein would require substantial increases in or alternative fisheries, potentially straining other ecosystems or raising costs. This role is especially pronounced in exclusive economic zones, where over 99% of bottom trawling occurs, directly benefiting national food supplies in countries reliant on . Despite its productivity, the sector's contribution must be weighed against challenges, though managed stocks demonstrate that bottom trawling can sustain yields when paired with quotas and protections. Peer-reviewed analyses affirm its ongoing importance for global nutrition, supplying omega-3 fatty acids and micronutrients absent or scarce in terrestrial proteins.

Employment and Industry Impacts

Bottom trawling supports direct employment in the tens of thousands within major regions, with broader industry linkages extending to processing, supply chains, and ancillary sectors. In the , approximately 20,000 individuals are employed aboard bottom trawler vessels, representing a fraction of the overall fisheries workforce but concentrated in industrial operations targeting demersal species. Globally, bottom trawling contributes 26 percent of marine fisheries landings, underpinning economic activity in high-catch nations such as , , and , where it integrates with export-oriented industries. However, its mechanized nature yields lower labor intensity per metric ton of catch compared to alternatives like longlining, which can sustain up to six times more jobs in deep-sea contexts. Industry-wide, bottom trawling drives revenue through high-volume harvests of species like , , and , sustaining vessel construction, gear manufacturing, and port infrastructure in trawling-dependent economies. In , it generates landings valued in billions of euros annually, though government subsidies—totaling hundreds of millions—offset operational costs amid fluctuating prices and quota restrictions. Small-scale fisheries, by contrast, produce 3–4 times more jobs per unit of effort than industrial bottom trawling fleets, highlighting efficiency trade-offs that favor capital over labor in trawling operations. Technological advancements, including larger nets and sonar-guided hauling, have further reduced crew sizes per vessel, contributing to a secular decline in direct employment even as catch volumes stabilize in regulated areas. Regulatory pressures, including proposed bans on bottom trawling in marine protected areas, pose risks to short-term employment in coastal communities reliant on the practice. For instance, European transport unions have warned that restrictions could jeopardize thousands of jobs in processing and support roles, exacerbating vulnerabilities in regions with limited diversification. Overexploitation from unchecked trawling, however, has historically led to stock collapses and subsequent layoffs, as seen in North Atlantic cod fisheries during the late 20th century, underscoring causal links between habitat disruption and long-term industry contraction. Transition to selective gears or spatial management could mitigate losses by reallocating effort to sustainable segments, though empirical evidence from partial bans indicates mixed outcomes with initial disruptions followed by adaptation in alternative fisheries.

Ecological Impacts

Target Species Management and Bycatch

Bottom trawling primarily targets demersal inhabiting the seafloor, including gadoid fishes such as (Gadus morhua) and (Melanogrammus aeglefinus), flatfishes like (Pleuronectes platessa) and (Solea solea), and crustaceans such as Norway lobster (Nephrops norvegicus) and . Management strategies for these target emphasize assessments to set total allowable catches (TACs) and fishing effort quotas, often informed by models integrating catch-per-unit-effort and surveys. In regions like the North Atlantic, TACs for have been reduced by over 80% since the 1970s peaks to allow , with showing rebounds in some stocks under strict enforcement, such as Iceland's haddock fishery achieving levels exceeding thresholds by 2022. Gear modifications, including larger mesh sizes in codends, improve size selectivity to release undersized juveniles, reducing mortality on immature target by up to 30-50% in trials from the Northeast Atlantic. However, multi-species nature of trawled assemblages complicates precise control, as overlapping distributions lead to correlated depletions without species-specific adaptations. Bycatch in bottom trawling encompasses non-target , , and occasionally mammals or seabirds, often comprising juveniles of target or with low value that are discarded. Globally, bottom trawls account for approximately 46% of total discards in fisheries, equating to about 4.2 million tonnes annually, with trawling exhibiting discard ratios exceeding 60% due to fine meshes capturing small, unmarketable organisms. In the U.S. , trawl averaged 64,000 metric tons yearly from 2010-2020, including significant juveniles whose post-release mortality reaches 25-40%, undermining target recruitment. Mediterranean bottom trawl discards hover at 45-50% of catch weight, dominated by small and that decompose rapidly upon surfacing, amplifying ecological waste. Causal factors include non-selective designs herding broad assemblages and behavioral differences, such as deep-water ascending into nets during . Mitigation efforts focus on bycatch reduction devices (BRDs) and turtle excluder devices (TEDs), which divert non-target species via escape panels or grids; for instance, TEDs in shrimp trawls reduced bycatch by over 90% in U.S. Southeast Atlantic fisheries since mandatory adoption in 1987, per observer data. Selectivity experiments in the NW Mediterranean demonstrated that modified trawls with square-mesh panels increased escapement of small hake () by 20-40%, aiding stock sustainability without fully eliminating multi-species trade-offs. Despite these, discard rates persist at 17-22% across U.S. trawls overall, with effectiveness limited by poor compliance in some fleets and unintended incentives like high-grading (discarding lower-value catch for quota optimization). Empirical assessments indicate that while managed fisheries can sustain target yields—evidenced by certifications for certain stocks—unmitigated bycatch contributes to localized depletions, particularly for data-poor species lacking dedicated assessments.

Seabed Disturbance and Habitat Effects

Bottom trawling involves dragging heavy gear, such as otter boards, beam trawls, or rockhoppers, across the , which physically disrupts sediments and structures, leading to direct mortality of benthic and alteration of complexity. This disturbance penetrates several centimeters into soft sediments, resuspending particles and homogenizing the surface, with impacts scaling with gear weight and towing speed. In muddy or sandy substrates, a single pass can remove 6–41% of faunal , primarily affecting infaunal and epifaunal through crushing, burial, or displacement. Habitat effects vary by seabed type and trawling intensity; soft-bottom communities experience reduced and shifts toward opportunistic, short-lived , while hard substrates like biogenic reefs or fields suffer fragmentation and of three-dimensional structure essential for shelter and feeding. Chronic trawling depletes long-lived biota disproportionately, with effects 2–3 times greater on with lifespans over 10 years compared to those under 3 years, as measured by abundance and reductions in comparative studies. Vulnerable ecosystems (VMEs), including cold-water corals and seamounts, show up to 40.7% area after decades of trawling in some bioregions, impairing services like cycling and carbon . Recovery of disturbed benthic communities typically requires 1.9–6.4 years post-trawling cessation, based on meta-analyses of experimental and observational data, though full of pre-disturbance states may exceed this in heavily fished areas due to persistent changes and altered . , bottom trawling affects approximately 5 million square kilometers of annually, representing a substantial fraction of continental shelves, with higher intensities in regions like the where over 80% of is trawled at least once every three years. These disturbances compound natural events like storms but exceed them in frequency and spatial extent on fished grounds, as evidenced by core analyses showing trawling-induced homogenization absent in undisturbed references.

Ecosystem Recovery and Resilience

Bottom trawling induces significant disturbances to benthic communities, including reductions in , , and structural complexity, but empirical studies indicate variable recovery potential upon cessation, influenced by type, prior disturbance intensity, and . A global of experimental and observational data from over 50 studies found average recovery times for ranging from 1.9 to 6.4 years in soft-sediment habitats, with faster recolonization by opportunistic taxa like polychaetes and slower for longer-lived suspension feeders. However, biogenic habitats such as reefs or sponge fields exhibit protracted recovery, often exceeding decades due to the slow growth rates of erect epifauna, with some structures showing incomplete even after 20-40 years of protection. In marine protected areas (MPAs) where bottom trawling is banned, evidence of ecosystem rebound includes increased benthic biomass and shifts toward pre-disturbance community structures. For instance, whole-site MPAs in temperate reef systems demonstrated detectable recovery in interstitial habitats between reefs within three years of trawling exclusion, marked by higher densities of epibenthic invertebrates and reduced sediment resuspension. Similarly, a tropical trawl ban in the led to homogenized yet recovering benthic assemblages, with decreased habitat fragmentation fostering similarity in community composition across sites over five years post-cessation. Long-term assessments, such as 17-year post-fishing closures in submarine canyons, reveal partial restoration of macrofaunal diversity but persistent alterations in trophic structure, suggesting resilience tempered by hysteresis effects where communities stabilize in altered states. Resilience varies markedly; sandy and muddy substrates support rapid turnover via larval recruitment, enabling recovery within 1-3 years in low-intensity trawled areas, whereas deep-sea or vulnerable ecosystems (VMEs) like seamounts display low , with -induced declines in cold-water corals persisting without full reversal even after decades. Experimental cessation in the soft-bottom communities showed short-term trophic shifts toward more diverse feeding guilds within 1-2 years, attributed to opportunistic recolonizers, though full equivalence to undisturbed baselines required longer periods. Factors enhancing include natural disturbances like storms that mimic effects, potentially preconditioning communities, but chronic can erode this by depleting , prolonging trajectories. Overall, while is feasible in many contexts, complete restoration remains habitat-specific and often incomplete, underscoring the role of disturbance frequency in determining long-term states.

Carbon and Broader Environmental Footprint

Bottom trawling exhibits a high primarily due to its substantial consumption, as the requires significant engine power to drag across the seafloor. Globally, bottom trawl fisheries account for elevated from , estimated at 2.8 times the average across major fishing gear types, though this exceeds only methods like pots and traps in some analyses. varies by configuration and target species; for instance, semi-pelagic bottom trawls can reduce energy use by 17% compared to traditional setups. Sediment resuspension from trawling gear further amplifies emissions by exposing buried carbon to oxygen, accelerating remineralization and 2 production. Quantitative models indicate that bottom disturbs 0.16-0.40 Pg of carbon annually, converting it to aqueous 2, with 55-60% released to the atmosphere over 7-9 years. From 1996 to 2020, such disturbances contributed approximately 0.97 ppm to atmospheric 2 levels, a figure contested by critiques highlighting overestimations in carbon turnover rates and sediment heterogeneity. In shelf seas like the , repeated reduces long-term carbon storage by depleting macrobenthic communities that aid burial, potentially releasing millions of tonnes of 2 equivalent annually. Broader effects encompass from dissolved CO2, which lowers and impairs calcifying organisms, alongside potential oxidation in resuspended sediments that generates additional CO2 via cycling. These processes may indirectly influence nutrient dynamics, exacerbating localized through enhanced decomposition, though empirical quantification remains limited by site-specific variability. Case studies demonstrate that not all trawled areas exhibit outsized footprints, underscoring the role of fishing intensity and in modulating impacts.

Regulations and Management

International Frameworks

The has issued annual resolutions since 2004 urging states to manage bottom trawling to protect deep-sea ecosystems, emphasizing the need for prior assessments of fishing impacts and protection of vulnerable marine ecosystems (VMEs) such as seamounts and cold-water corals from destructive practices. Resolution 59/25, adopted on 17 December 2004, called for states and regional organizations (RFMOs) to close areas to bottom trawling where VMEs are known or likely to occur, based on of significant adverse impacts (SAIs). This was expanded in resolution 61/105 of 8 December 2006, which required flag states authorizing bottom fisheries beyond national jurisdiction to conduct impact assessments, establish encounter protocols (e.g., move-on rules when VME indicator species are caught), and prohibit fishing in identified VME hotspots. Subsequent resolutions, including 64/72 (2009), 66/68 (2011), and 71/123 (2016), reiterated these requirements, stressing data collection, transparency in RFMO decisions, and performance reviews to ensure compliance. The (FAO) of the provides voluntary but influential technical guidelines for implementing these resolutions. The International Guidelines for the Management of Deep-sea Fisheries, developed in 2008 and endorsed by the UN , define VMEs as ecosystems susceptible to damage from bottom-contact gears like trawls, including criteria for identifying them (e.g., long-lived species like corals and sponges with slow recovery rates). These guidelines recommend frameworks for deep-sea fisheries, such as baseline data collection on benthic habitats, precautionary closures, and observer programs to monitor of VME elements, aiming to prevent SAIs defined as measurable changes in community structure lasting beyond five years. also maintains a global VME database tracking RFMO measures to restrict bottom trawling in areas beyond national jurisdiction. Implementation occurs primarily through RFMOs, which apply UN and FAO standards regionally; for instance, organizations like the North East Atlantic Fisheries Commission and South Pacific Regional Fisheries Management Organisation have adopted encounter thresholds (e.g., 100 kg of corals or sponges per tow) triggering temporary closures. Under the Convention on the (), states have obligations to cooperate on high-seas fisheries conservation, indirectly supporting these frameworks by requiring compatible measures between coastal and high-seas regimes. However, these instruments are largely non-binding, relying on state and RFMO action, with no universal prohibition on bottom ; resolution 79/145 of 16 December 2024 continues to advocate eliminating destructive practices consistent with , without mandating outright bans. Effectiveness varies, as evidenced by ongoing illegal trawling in some protected areas despite protocols.

National and Regional Practices

In the , bottom trawling is governed by the , which includes the 2016 Deep-sea Access Regulation prohibiting such gear below 800 meters depth in the Northeast Atlantic to protect vulnerable marine ecosystems. In 2022, the EU closed 87 sensitive zones in its Northeast Atlantic waters to all bottom-contact gears, covering areas with vulnerable habitats like cold-water corals. Member states must implement these frameworks, though enforcement varies; for instance, the proposed phasing out bottom trawling in all marine protected areas (MPAs) and sites by 2030, but as of 2025, no comprehensive national plans exist across the bloc to achieve this, with several countries facing legal action for inadequate protection. implemented a ban on bottom trawling in coastal zones up to 20 nautical miles offshore in select areas, marking an early national restriction within the EU. In the United States, the (NOAA) oversees bottom trawling through eight regional fishery management councils, which designate essential fish habitats and impose area closures. Bottom trawling is prohibited year-round in over 50% of U.S. federal waters, with more than 37% closed to all bottom-tending gears to mitigate habitat damage; on the , restrictions cover 90% of seafloor habitats identified as sensitive. Turtle excluder devices (TEDs) are mandated in and trawl fisheries to reduce , while electronic monitoring programs track compliance in groundfish bottom trawl operations. Proposed legislation, such as the 2024 Bottom Trawl Clarity Act, seeks to clarify "substantial" versus "limited" impacts and establish dedicated trawling zones to balance fishing access with deep-sea protections. China, the world's largest practitioner of bottom trawling, maintains restrictions including a year-round in territorial waters shallower than 40 meters and seasonal closures elsewhere to allow stock recovery, policies tracing back to the 1950s with expansions in the 2000s. Despite these measures, enforcement remains inconsistent, contributing to overcapacity; bottom trawling accounts for a significant portion of China's catch, with historical data indicating it comprised about 50% of global bottom trawl biomass landings since the late 1980s. The fleet's distant-water operations often evade oversight, exacerbating depletion in . Norway employs area-based management for bottom trawling, with extensive closures in fjords, national parks, and vulnerable zones to limit contact, alongside gear restrictions like the 2022 ban on beam trawling in certain coastal areas. Subsidies support the industry, which targets and , but studies show persistent impacts on octocoral habitats despite these controls. In the South Pacific, regional measures under the South Pacific Regional Fisheries Management Organisation, updated in 2023, require protection of at least 70% of vulnerable indicator on seamounts, mandating encounter protocols and temporary closures for bottom trawling.

Effectiveness of Mitigation Measures

Mitigation measures for bottom trawling include gear modifications such as bycatch reduction devices (BRDs), selective codends, and ground gear alterations; spatial management like marine protected areas (MPAs) and temporary closures; and operational controls including vessel monitoring and effort quotas. These aim to reduce , minimize seabed disturbance, and promote habitat recovery, though their effectiveness varies by implementation, compliance, and ecosystem context. Peer-reviewed studies indicate that while some measures yield measurable reductions in impacts, full mitigation often requires integrated approaches, as single interventions may not address all ecological effects. BRDs, such as rigid grids and soft netting panels integrated into trawls, have demonstrated bycatch reductions of up to 37% in fisheries with catch losses below 4%, based on field trials in waters. Ground gear modifications, like elevated or modified footropes, significantly lowered ray bycatch in Mediterranean bottom trawls by facilitating escapes during towing, without substantial target loss. Selective codends, including T90 meshes that maintain openness under tension, improved size selectivity for like , increasing retention of legal sizes while releasing juveniles, as evidenced in demersal trawl experiments. However, effectiveness depends on behavior and gear positioning; for instance, artificial lighting near BRDs enhanced escapement in some bycatch scenarios but showed variable results in fisheries. Spatial closures, including bans in MPAs, have proven effective for and enhancement. In , , a 15-year trawling exclusion led to increased benthic and , with video surveys over 26 years confirming rebounds in anemones, corals, and mobile species. Tropical trawl bans restored benthic communities within years, boosting overall metrics. Closures in coastal protection zones reduced organic carbon loss by 29% and macrobenthos decline by 54%, per modeling of trawling data. Compliance remains a challenge; full adherence to bans was achieved in only 73% of monitored areas, limiting broader efficacy. Operational and gear innovations like mid-water trawl doors further mitigate impacts by elevating gear off the , reducing use and benthic while maintaining catch efficiency. Integrated management, combining these with quotas and monitoring, sustains target stocks in well-regulated fisheries, though chronic in unprotected areas continues to impair deep-sea . Overall, evidence from diverse regions underscores that rigorous amplifies benefits, but incomplete adoption or evasion undermines potential, with peer-reviewed assessments highlighting the need for site-specific evaluation over generalized assumptions of .

Controversies and Future Directions

Debates on Sustainability

Bottom trawling's sustainability is debated primarily along lines of target species management versus broader effects, with proponents emphasizing empirical successes in well-regulated fisheries and opponents highlighting persistent degradation and losses that challenge long-term viability. A 2023 review in the ICES Journal of Marine Science analyzed global data, finding that bottom-trawl fisheries have sustained target stocks, with groundfish populations increasing above target levels since 2005 in managed systems, attributing this to total allowable catches, stock assessments, and gear selectivity improvements. These fisheries produce 26% of wild-caught , and where regulated—such as in Alaskan operations—bycatch rates have dropped to 6-8%, discards halved since the 1980s, and carbon emissions averaged 0.83 kg CO2 per kg product, lower than (2.28 kg CO2/kg) and far below (19.2 kg CO2/kg). Critics argue that even managed trawling inflicts irreversible damage on benthic habitats, reducing and beyond target . Studies indicate trawling erodes alpha- and beta-diversity linearly across trawled areas, affecting commercial and threatened rays, with recovery rates varying widely but often insufficient for sensitive structures like cold-water corals, which regenerate over decades if at all. A 2024 Nature Geoscience analysis of shelf sea sediments found bottom trawling reduces long-term carbon storage by enhancing remineralization, contributing to atmospheric CO2 despite varying spatio-temporal responses, countering claims of negligible climate impact. Environmental advocacy syntheses, drawing on peer-reviewed evidence, report trawling depletes complexity and indicator taxa in vulnerable ecosystems, with global footprints covering up to 24% of continental shelves in some regions. The debate underscores causal trade-offs: effective sustains yields and minimizes some impacts—93% of maintaining high status (>0.8) in modeled assessments—but fails to fully mitigate chronic disturbances in high-effort zones, where benthic communities show quasi-linear declines regardless of effort reductions. Proponents, often from , prioritize and compare favorably to terrestrial alternatives requiring land conversion, while opponents, including marine ecologists, stress empirical data on homogenization and carbon fluxes indicating unsustainability without widespread effort cuts or bans. Global variability in , with many fisheries lacking robust , amplifies , as sustained do not equate to ecosystem-level .

Ban Proposals vs. Management Alternatives

Proposals to ban bottom trawling have gained traction among environmental advocacy groups and some policymakers, particularly in marine protected areas (MPAs) and vulnerable high-seas regions, citing irreversible damage and high carbon emissions equivalent to . The has advocated for prohibiting mobile bottom-contact gears in MPAs by 2030 to enhance and , with studies estimating that such bans could yield net societal benefits exceeding initial economic costs within 3-5 years through improved and reduced fuel subsidies. In regions like waters, a 2012 trawl ban led to rapid increases in and , though long-term data indicate partial rather than full of pre-trawling ecosystems. Critics of bans, including fisheries scientists, argue that blanket prohibitions overlook site-specific variability in habitat resilience and could displace effort to less regulated areas or land-based , potentially elevating overall environmental footprints. Management alternatives emphasize targeted regulations over outright bans, leveraging that well-enforced measures can sustain target stocks while minimizing non-target impacts. These include caps, real-time area closures via vessel monitoring systems, and gear modifications such as raised footropes or selective meshes, which have reduced discards by up to 50% in Northeast U.S. fisheries without compromising yields. In the Northwest Atlantic, coordinated fleet avoidance of high- zones has maintained stock rebuilding trajectories, demonstrating that bottom 's benthic effects—often recoverable within 1-6 years in sandy substrates—can be mitigated below thresholds seen in unmanaged systems. Peer-reviewed assessments indicate that such approaches yield lower per-ton carbon emissions than substituting with or protein, as provides efficient wild capture of . Economic analyses further suggest that transitioning to selective or hybrid gears in waters could cut seafloor pressure by 30-70% while preserving €5-10 billion in annual industry value, avoiding the job losses and risks of abrupt bans. Comparisons reveal trade-offs: bans excel in fragile habitats like deep-sea corals, where recovery may span decades, but risk unintended shifts to higher-impact alternatives absent compensatory policies. strategies, when data-driven and adaptive, have proven effective in maintaining —e.g., U.S. groundfish stocks rebuilt post-2000s reforms—though enforcement gaps in developing nations undermine outcomes. Ongoing debates hinge on integrating high-resolution seabed mapping with economic incentives, as unsubstantiated calls for universal bans may reflect advocacy priorities over causal evidence of scalable alternatives.

Innovations and Potential Reforms

Innovations in bottom trawling gear have focused on minimizing contact and while maintaining catch efficiency. For instance, Katchi Tech's automatic winching system enables door-less trawl nets to hover above the seafloor by dynamically adjusting depth along contours, reducing physical disturbance; field tests in demonstrated precise positioning via integrated sensors and data analytics. Similarly, semi-pelagic trawls with "flying doors" or otter boards designed for greater lift and lower drag elevate gear off the bottom, limiting habitat disruption in targeted fisheries. Bycatch reduction technologies include selective escape panels and grids in nets, allowing non-target like juveniles or undersized fish to exit before haul-back; a 2022 study found adaptive implementation of such modifications, combined with real-time monitoring, cut bycatch by up to % in dynamic scenarios. Acoustic and camera-based systems for onboard further enable live release of discards, with trials showing improved survival rates for released compared to traditional methods. On the U.S. , a 2024 NOAA-developed multi-depth trawl net captures at varying levels, optimizing surveys and potentially commercial operations by stratifying catches vertically rather than scraping uniformly. Potential reforms emphasize incentives over outright bans, given the absence of scalable alternatives for high-volume demersal species like . proposals include designating "bottom trawl zones" to confine operations to resilient habitats while protecting sensitive areas, as outlined in 2024 U.S. legislation aiming to clarify management boundaries. Redirecting subsidies from destructive practices to gear upgrades and fuel-efficient designs could accelerate adoption, with studies indicating such economic levers reduce pressure more effectively than prohibitions alone. In the , integrating innovative gears into marine protected areas (MPAs) via pilot programs tests viability without full exclusion, prioritizing empirical assessment of recovery. Comprehensive reforms also advocate prohibiting trawling in non-industrial exclusive economic zones and vulnerable MPAs to safeguard hotspots, as implemented in Ghana's 2025 framework.