What are zooplankton and their role in the ocean?

Zooplankton are microscopic to small drifting animals that graze on phytoplankton, forming the base of marine food webs. They drive the biological pump by creating sinking fecal pellets that sequester carbon.

How do copepods transport microplastics to the deep ocean?

Copepods ingest microplastics, process them through their gut in about 40 minutes, and package them into dense fecal pellets that sink rapidly, carrying pollutants to sediments thousands of meters deep.

What is the biological carbon pump?

The biological pump transfers carbon from surface waters to the deep ocean via sinking particles like zooplankton fecal pellets, helping mitigate climate change by storing ~10-15 billion tons of CO2 yearly.

Key findings from the 2026 Plymouth Marine Lab study?

Median gut passage: 40 min; flux: 271 particles/m³/day in English Channel. Consistent across MP shapes, highlighting zooplankton as major transporters. Read more.

How do microplastics affect the ocean's carbon sequestration?

Microplastics alter fecal pellet sinking rates and density, potentially reducing carbon export by up to 4.4 Pg/year regionally, impairing the ocean's CO2 absorption capacity.

What is New Zealand's involvement in microplastics research?

NIWA, U Auckland, Otago, and MPI document MPs in sediments, lakes, and Southern Ocean plankton. Continuous Plankton Recorder data shows co-occurrence with zooplankton.

Implications for marine food webs and human health?

Chronic exposure via zooplankton affects fish, seabirds, mammals; bioaccumulation in seafood poses risks. Subtle effects on behavior, reproduction under multiple stressors.

What solutions exist to reduce microplastic pollution?

Producer responsibility, bans on microbeads, improved wastewater treatment, fishing gear management. Global Plastics Treaty in negotiation. Research roles advance monitoring.

Career paths in marine microplastics research in NZ?

Degrees at Auckland/Otago unis, NIWA labs, postdocs. Check research jobs, career advice, professor reviews.

Future research directions post-2026 study?

Integrate data into transport models, assess toxicity combos, identify hotspots. NZ focus: Southern Ocean fluxes, local fisheries impacts.

How many microplastics are in the ocean?

Over 125 trillion particles, with zooplankton exporting significant portions daily to depths, per recent estimates.

Zooplankton Microplastics Biological Pump Deep Ocean Study |

Photo by Peter Neumann on Unsplash

Understanding Zooplankton and the Ocean's Biological Pump Mechanism

Zooplankton, which are tiny drifting animals ranging from single-celled organisms to small crustaceans, form a critical layer in marine food webs. Among them, copepods stand out as the most abundant multicellular animals on Earth, outnumbering all insects combined. These minuscule creatures, often just millimeters long, play a pivotal role in the ocean's biological pump—a natural process that sequesters carbon dioxide from the atmosphere into the deep sea. Here's how it works step by step: Phytoplankton, microscopic plants near the ocean surface, absorb carbon dioxide through photosynthesis. Copepods and other zooplankton graze on these phytoplankton, packaging the carbon-rich material into dense fecal pellets. These pellets, along with dead zooplankton bodies and marine snow aggregates, sink rapidly to depths of thousands of meters, effectively locking away carbon for centuries. This biological carbon pump is estimated to transport around 10 to 15 billion metric tons of carbon annually, helping mitigate climate change by reducing atmospheric CO2 levels.

Recent discoveries reveal a darker side: zooplankton are inadvertently becoming biological pumps for microplastics too. Microplastics, defined as plastic particles smaller than 5 millimeters originating from degraded larger plastics, cosmetics, textiles, and industrial sources, are ingested alongside food. Over 125 trillion microplastic particles currently pollute the ocean, and their transport to the deep sea via zooplankton could reshape marine ecosystems in unforeseen ways. This dual pumping action highlights the interconnectedness of ocean health, pollution, and climate regulation.

The Landmark 2026 Study: Pioneering Real-Time Visualization

Published on January 5, 2026, in the Journal of Hazardous Materials, the study 'Real-time visualization reveals copepod mediated microplastic flux' marks a breakthrough in understanding microplastic dynamics. Led by Dr. Valentina Fagiano from Spain's Oceanographic Center of the Balearic Islands (COB-IEO-CSIC), in collaboration with experts Dr. Matthew Cole, Dr. Rachel Coppock, and Professor Penelope Lindeque from the UK's Plymouth Marine Laboratory (PML), the research provides the first quantitative, real-time measurements of microplastic movement through zooplankton guts. Conducted using copepods (Calanus helgolandicus) sampled from the Western Channel Observatory near Plymouth, the findings underscore zooplankton's role as efficient transporters, potentially moving hundreds of particles daily per cubic meter of seawater.

This international effort exemplifies how higher education institutions and research labs worldwide contribute to global environmental science. For aspiring marine biologists, such collaborative projects offer invaluable training in advanced imaging and field sampling techniques.

Core Findings: Quantifying the Microplastic Flux

The study's most striking revelation is the median gut passage time for microplastics: approximately 40 minutes, remarkably consistent regardless of particle shape—beads, fibers, or fragments—or food availability. Copepods ingest these pollutants continuously, repackaging them into negatively buoyant fecal pellets that sink swiftly. In the study site, researchers calculated a flux of about 271 microplastic particles per cubic meter of seawater per day, driven by local copepod densities.

Ingestion rates remain steady 24/7, embedding microplastics deep into food webs.
Fecal pellets act as 'delivery vehicles,' depositing plastics in sediments far below the surface.
No significant impact from co-ingested food, suggesting microplastics are treated like natural prey.

These metrics bridge individual animal behavior to ecosystem-scale transport, reducing uncertainties in pollution models.

Fluorescently labeled microplastics visible in the gut of a copepod under microscope

Innovative Methods: From Field Collection to Lab Imaging

The methodology was meticulous. Copepods were gently collected via fine-mesh plankton nets from PML's RV Quest at the L4 monitoring station. In controlled lab settings, they were exposed to fluorescently labeled polystyrene beads, polyamide (Nylon) fibers, and fragments under varying phytoplankton concentrations to mimic natural conditions. High-resolution real-time imaging tracked individual particles from ingestion through expulsion, yielding precise timings for gut residence and ingestion intervals.

This non-invasive approach, combining field realism with lab precision, sets a new standard for microplastic research. Such techniques are increasingly taught in marine science programs at universities worldwide, equipping students for frontline environmental challenges.

Ecological Consequences: Ripple Effects Through Marine Food Webs

By shuttling microplastics downward, zooplankton expose deeper-dwelling organisms and sediments to persistent pollutants. Fish larvae, small pelagic fish, seabirds, and marine mammals feeding on copepods face chronic low-level exposure. While acute toxicity is rare, cumulative effects could disrupt energy allocation, reproduction, foraging behavior, and immune function—especially when compounded by warming oceans or ocean acidification.

In the food web, microplastics bioaccumulate, potentially reaching seafood consumed by humans. Studies indicate subtle shifts in predator health, underscoring the need for vigilant monitoring.

Disrupting the Biological Carbon Pump: A Climate Double Whammy

Microplastics don't just hitch a ride—they interfere with the pump's efficiency. Research shows they alter fecal pellet density and sinking speeds, causing more to disintegrate mid-water and release carbon prematurely. One analysis estimates this could diminish ocean carbon uptake by up to 4.4 petagrams annually in some regions. With oceans absorbing 25-30% of human CO2 emissions, any impairment exacerbates global warming.

For deeper insights, explore the EurekAlert report on microplastics and carbon absorption.

New Zealand Perspectives: Local Waters and Southern Ocean Connections

New Zealand's vast Exclusive Economic Zone, encompassing pristine sub-Antarctic waters, makes this research acutely relevant. NIWA (National Institute of Water and Atmospheric Research) and the University of Auckland have documented microplastics in Queen Charlotte Sound sediments, transported via coastal currents. Meanwhile, Ministry for Primary Industries' Continuous Plankton Recorder surveys (2002-2023) reveal microplastics co-occurring with zooplankton in the Ross Sea sector of the Southern Ocean.

University of Otago studies on lake food webs and University of Canterbury theses on pelagic microplastics highlight national expertise. These findings warn of deepening pollution in NZ's fisheries-rich waters, threatening taonga species like hoki and orange roughy.

Continuous Plankton Recorder samples from Southern Ocean showing microplastics and zooplankton

Read NIWA's work here.

Navigating Challenges: Policy, Mitigation, and Research Gaps

Challenges: Rising plastic production (projected 20% growth by 2040), poor waste management, and fishery gear losses amplify inputs.
Solutions: Extended Producer Responsibility laws, microbead bans (NZ implemented 2018), and wastewater filtration upgrades.
Research Needs: Long-term field data, toxicological thresholds, and modeling NZ-specific fluxes.

Government reports urge international treaties like a Global Plastics Treaty to curb sources.

Thriving Careers in Marine Science: Opportunities in New Zealand

This study spotlights demand for skilled researchers. NZ universities like Auckland, Otago, and Victoria offer marine biology degrees, with labs at NIWA providing hands-on experience. Explore research jobs, research assistant positions, and NZ academic opportunities on AcademicJobs.com. Whether pursuing a winning academic CV or postdoc roles, the field promises impactful work. Check higher ed jobs for faculty spots in environmental science.

Looking Ahead: Optimism Through Science and Action

Integrating these flux data into models will pinpoint hotspots and guide interventions. Collaborative efforts between PML, NIWA, and others pave the way for resilient oceans. By reducing plastic leakage and bolstering research, we can preserve the biological pump's vital functions. Stay informed via university jobs and career advice resources. Engage with professors on Rate My Professor to connect with mentors driving change.

For the full study, visit ScienceDirect or PML's news page.