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61,005 resultsShowing papers similar to Falling into the darkness – microplastics sinking fluxes in the deep sea
ClearFalling into the darkness – microplastics sinking fluxes in the deep sea
Researchers deployed a sediment trap at 230 metres depth on the Condor seamount in the Azores for 12 months, collecting 18 sequential samples to quantify seasonal patterns in microplastic sinking fluxes and investigate the mechanisms by which floating microplastics are transported to the deep sea.
Sinking microplastics at a deep-sea seamount in the North Atlantic: a year-long flux study
Sinking microplastics were collected from sediment traps deployed at a deep-sea seamount in the North Atlantic, providing direct evidence of how plastic particles travel from the surface to the deep ocean floor. The study quantifies the deep-sea plastic flux at an ecologically significant seafloor feature.
Vertical Flux of Microplastics in the Deep Subtropical Pacific Ocean: Moored Sediment-Trap Observations within the Kuroshio Extension Recirculation Gyre
Researchers used deep-ocean sediment traps to measure the downward flux of microplastics in the western North Pacific Ocean over a two-year period. They found that microplastics, primarily fibers, were sinking to depths of nearly 5,000 meters, with seasonal variations linked to biological processes at the surface. The study provides some of the first direct evidence that microplastics are actively being transported to the deep ocean floor.
First long-term evidence of microplastic pollution in the deep subtropical Northeast Atlantic
Researchers found microplastic particles in all 110 sediment trap samples collected over a 12-year period from 2,000-meter depths in the Northeast Atlantic, establishing the deep ocean as a long-term sink for microplastics with fluxes increasing over time.
Vertical flux of microplastic, a case study in the Southern Ocean, South Georgia
Researchers deployed floating sediment traps in the Southern Ocean near South Georgia to measure the vertical flux of microplastics, finding that sinking of microplastics represents a significant and understudied pathway for removing plastic from the ocean surface into deep water.
Dispersion, Accumulation, and the Ultimate Fate of Microplastics in Deep-Marine Environments: A Review and Future Directions
This review synthesizes knowledge about how microplastics are transported to and accumulate in deep-marine environments, which may serve as the ultimate sink for ocean plastic pollution. Researchers integrated sedimentological models to explain how ocean currents, density flows, and settling processes deliver microplastics to the seafloor. The study highlights that deep-sea environments, often considered pristine, are increasingly contaminated with microplastic particles.
Dispersion, accumulation and the ultimate fate of microplastics in deep-marine environments: A review and future directions
This review synthesized existing knowledge on microplastic distribution in deep-marine environments, integrating process-based sedimentological transport models with field data to outline how microplastics disperse, accumulate, and become buried in seafloor sediments, and identifying key gaps for future research.
Deep-sea microplastics aging and migration exerted by seamount topography and biotopes in the subtropic Northwest Pacific Ocean
This study investigated how seamount topography influences the aging and vertical migration of microplastics in the deep sea, finding that seamount-induced flow patterns promote particle sinking and accumulation of aged microplastics in benthic zones. The work highlights deep-sea seamounts as hotspots for microplastic deposition.
Global Modeled Sinking Characteristics of Biofouled Microplastic
Researchers developed a global model of microplastic biofouling and sinking using satellite oceanographic data to estimate where and when buoyant plastic particles sink out of the surface ocean, finding that sinking timescales ranged from days in tropical waters to months in high-latitude regions depending on temperature and productivity.
A novel method enabling the accurate quantification of microplastics in the water column of deep ocean
A new sampling method was developed to accurately measure microplastics in the deep ocean water column, addressing gaps left by traditional net trawls that miss very small particles. Reliable deep-sea sampling is critical since the deep ocean is thought to be a major sink for global microplastic pollution.
The vertical distribution and biological transport of marine microplastics across the epipelagic and mesopelagic water column
Remotely operated vehicles and custom samplers were used to collect microplastics from depths of 5–1000 m in Monterey Bay, finding that microplastic concentrations in mesopelagic waters (200–600 m depth) were comparable to or higher than surface concentrations. The study demonstrates that the deep ocean is not merely a sink but an active reservoir of microplastics vertically transported by biological organisms.
Modeling submerged biofouled microplastics and their vertical trajectories
Researchers modeled how biofouling — the growth of algae and microbes on plastic surfaces — affects the vertical movement of microplastic particles in the open ocean. Biofouling increased sinking rates, causing microplastics to accumulate at depth rather than floating at the surface. This has implications for understanding where microplastics end up in the water column and how they are ingested by deep-water organisms.
Microplastic pollution in deep-sea sediments and organisms of the Western Pacific Ocean
Researchers collected deep-sea sediment and organism samples from multiple sites in the western Pacific Ocean and found microplastics at all locations sampled, with depth, distance from land, and current patterns influencing accumulation, confirming the western Pacific deep sea as a significant microplastic sink.
Hitchhiking into the Deep: How Microplastic Particles are Exported through the Biological Carbon Pump in the North Atlantic Ocean
This study investigated how microplastic particles are exported from the ocean surface to the deep sea through the biological carbon pump in the North Atlantic. Microplastics were found associated with sinking organic aggregates (marine snow), fecal pellets, and zooplankton, demonstrating biological packaging as a key mechanism for deep-sea plastic transport.
Fate of microplastics in deep-sea sediments and its influencing factors: Evidence from the Eastern Indian Ocean
Surface sediments from 26 sites in the deep basin of the Eastern Indian Ocean were analyzed for microplastics, finding concentrations ranging widely and influenced by water depth, distance from land, and ocean current patterns. The study extends deep-sea microplastic monitoring to the Indian Ocean and identifies oceanographic transport as a key control on plastic distribution.
Prevalence of small high-density microplastics in the continental shelf and deep sea waters of East Asia
Researchers collected water samples at multiple depth layers across the continental shelf and deep sea of East Asia and found that small, high-density microplastics were more abundant in deeper waters, suggesting vertical sinking pathways concentrate certain particle types in the deep ocean.
Effects of biofouling on the sinking behavior of microplastics
Researchers studied how biofouling — the accumulation of microorganisms and organic matter on particle surfaces — alters the sinking behavior of microplastics, finding that biofouled particles sink faster and are more likely to reach seafloor sediments.
Organic pollutants in deep sea: Occurrence, fate, and ecological implications
This review synthesized data on organic pollutants in the deep sea, finding that persistent contaminants including microplastics and their sorbed chemicals reach depths exceeding 10,000 meters through particle sinking, water mass transport, and biological vectors, threatening poorly understood but ecologically vital deep-sea ecosystems.
Stratification and deposition pathways of microplastics in the abyssal sediments of the Philippine Sea
Scientists analyzed sediment cores drilled from the deep Philippine Sea to understand how microplastics sink and accumulate in the ocean's most remote depths. They found microplastics at every layer studied, with concentrations peaking near both the surface and the deepest layers, and discovered that the sediment's chemistry and mineral composition help govern how particles migrate downward. This research reveals that even the abyssal ocean — far from human activity — is accumulating plastic debris, with geological and chemical forces influencing where it ends up.
Microplastic sedimentation in the northern Gulf of Mexico
Researchers collected deep-sea sediment samples over six years in the northern Gulf of Mexico to understand how microplastics travel through the water column. They found that microplastic sedimentation appears to be driven by sinking marine particles such as fecal pellets and marine snow. The study provides insights into the pathways by which microplastics reach the deep ocean floor in regions influenced by major river systems like the Mississippi.
The deep sea is a major sink for microplastic debris
Researchers analyzed deep-sea sediments from the Atlantic, Mediterranean, and Indian Ocean and found microplastic fibers up to 4 orders of magnitude more concentrated than at the contaminated sea surface, identifying the deep seafloor as a vast and previously unknown repository of the world's 'missing' plastic.
Elucidating the vertical transport of microplastics in the water column: A review of sampling methodologies and distributions
This review synthesized sampling methodologies and findings on microplastic vertical distribution in the water column, identifying that surface trawl studies dramatically underestimate total water column burdens and that sinking behavior, biofouling, and hydrodynamic processes create complex depth-dependent distribution patterns.
Modelling the sedimentation of macro-, micro- and nanoplastics in the ocean from surface to sediment
Researchers modeled the sedimentation of macro-, micro-, and nanoplastics from the ocean surface to the seafloor, finding that biofouling and particle aggregation dramatically accelerate sinking rates and that most plastics eventually reach benthic environments.
>b/b<: influence of feeding mode on microplastic intake by benthic organisms and detection of persistent organic pollutants in biological and sediment samples
This study investigated micropollutant accumulation including microplastics in deep-sea organisms from the Southern Atlantic, examining how feeding mode influences contaminant intake. Results showed that filter feeders and deposit feeders accumulated different levels of microplastics and chemical pollutants, reflecting the deep sea's vulnerability to surface pollution.