There are many kinds of pollution in the ocean which threaten human and ecosystem health.
Plastics, a major portion of the chemicals industry, are of particular concern from a pollution standpoint. There are 75-150 million tons of plastic in the ocean today, of which an estimated 4.8-12.7 million tons entered the ocean in 2010 1. The World Wildlife Fund estimates that oceanic plastic pollution does $3.1 trillion of damage each year, or about $280,000 per ton of plastic in the ocean 2, while Beaumont et al. estimate damages at 3300-33,000 per ton per year based on lost ecosystem services 1.
The WWF cost translate into a cost of $0.68-1.36 per pound of wild-caught fish 3, in contrast to prevailing retail market fish prices of around $6-19 per pound 4.
Poor waste management practices, rather than the absolute volume of plastic waste generated, is the main factor that determines how much oceanic pollution occurs.
The share of discarded fishing gear as a share of all oceanic plastic has been estimated at 20% 5, though lower estimates of 0.5 to 1 million tons are made 8, and there is limited reliable data on the subject 9. Beyond sheer mass, discarded fishing gear is of particular concern because of the potential to continue catching sea life after discard, a phenomenon known as "ghost fishing" 10. Furthermore, discarded nets have been observed to disrupt ship propellers, having caused at least one major shipwreck 11.
A deposit-refund system is suggested to reduce the level of fishing gear discard. Under such a system, a deposit would be assessed with the sale of fishing gear, and that deposit would be refunded upon returning used gear to a facility at a port. The system is analogous to the beverage container deposit system that exists in many parts of the world 12.
Improved recycling can increase the economic incentive for fishers to avoid loss of equipment 13.
There is ongoing work to develop biodegradable fishing nets 14.
Persistent organic pollutants (POPs) refer, as the name suggests, to organic compounds that break down slowly. Most POPs are pesticides, as well as solvents, pharmaceuticals, and some industrial chemicals 15. Evidence is that since the 1970s, when heavier regulations on POPs were instituted, the level of POP concentration in the ocean has been decreasing, though it remains high enough to cause health problems for sea life, particular life higher on the food chain, and for humans who consume seafood 16.
The main regulatory tool on POPs the Stockholm Convention on Persistent Organic Pollutants, an international agreement which bans or restricts many classes of POPs 17. Methods to remove POPs from the ocean, such as with certain nanomaterials, are active areas of research 18.
Accumulation of three metals in the ocean in particular--mercury, cadmium, and lead--are of particular concern due to their toxic natures.
Anthropogenic sources constitute about 30% of total mercury emissions, but many of the natural resources are the result of mercury absorption and re-emission, and not the cause of new mercury into the biosphere 16. The bioaccumulation of mercury and resulting human exposure, from eating seafood, can cause neurological, heart, and nervous system problems, and it is advised that pregnant or child-bearing-age women, and young children, avoid certain kinds of seafood as a result 20.
In addition to mercury, cadmium, and lead, phosphate mining leads to chromium, nickel, copper, arsenic, thorium, and uranium pollution into coastal waters 16. Rare earth element pollution is also an emerging concern 16.
Beaumont, N., Aanesen, M., Austen, M. C., Börger, T., Clark, J. R., Cole, M., Hooper, T., Lindeque, P. K., Pascoe, C., Wyles, K. J. "Global ecological, social and economic impacts of marine plastic". Marine Pollution Bulletin 142, pp. 189-195. May 2019. ↩ ↩2
DeWit, W., Burns, E. T., Guinchard, J., Ahmed, N. "Plastics: The Costs to Society, the Environment, and the Economy". World Wildlife Fund, prepared by Dalberg. September 2021. ↩
Ritchie, H., Roser, M. "Fish and Overfishing". Our World in Data. October 2021. ↩
Fisherman's Market Seafood Outlet. "Market Prices". Accessed September 1, 2022. ↩
Ritchie, H., Roser M. "Plastic Pollution". Our World In Data. 2019. ↩ ↩2
Jambeck, J., Geyer, R., Wilcox, C., Siegler, T., Perryman, M., Andrady, A., Narayan, R., Law, K. "Plastic waste inputs from land into the ocean". Science 347(6223), pp. 768-771. February 2015. ↩
Li, W., Tse, H., Fok, L. "Plastic waste in the marine environment: A review of sources, occurrence and effects". Science of The Total Environment 566-567, pp. 333-349. October 2016. ↩
Nicolas, A. "Ghost fishing gear". World Wildlife Fund. October 2020. ↩
Richardson, K., Wilcox, C., Vince, J., Hardesty, B. D. "Challenges and misperceptions around global fishing gear loss estimates". Marine Policy 129: 104522. July 2021. ↩
NOAA Marine Debris Program. "Impact of "Ghost Fishing" via Derelict Fishing Gear". National Oceanic and Atmospheric Administration. March 2015. ↩
Macfadyen, G., Huntington, T., Cappell, R. "Abandoned, lost or otherwise discarded fishing gear". FAO Fisheries and Aquaculture Technical Paper Rome, ISBN 9789251061961. 2009. ↩
Nogueira, L.A., Kringelum, L.B., Olsen, J., Jørgensen, F.A., Vangelsten, B.V. "What would it take to establish a take‐back scheme for fishing gear? Insights from a comparative analysis of fishing gear and beverage containers". Journal of Industrial Ecology 26(6), pp. 2020-2032. December 2022. ↩
Chun, Z. "Five Ways to Tackle Ghost Fishing Gear". The Maritime Executive. December 2018. ↩
Kim, S., Kim, P., Lim, J., An, H., Suuronen, P. "Use of biodegradable driftnets to prevent ghost fishing: physical properties and fishing performance for yellow croaker". Animal Conservation 19(4), pp. 309-319. February 2016. ↩
Ritter, L., Solomon, K. R., Forget, J. "Persistent Organic Pollutants". Canadian Network of Toxicology Centers, prepared for The International Programme on Chemical Safety, Inter-Organization Programme for the Sound Management of Chemicals. Accessed December 15, 2022. ↩
United Nations "The Second World Ocean Assessment". 2021. ↩ ↩2 ↩3 ↩4
Stockholm Convention on Persistent Organic Pollutions. "Stockholm Convention". Accessed December 15, 2022. ↩
Ighalo J. O., Yap P. S., Iwuozor K. O., Aniagor C. O., Liu T., Dulta K., Iwuchukwu F. U., Rangabhashiyam S. "Adsorption of persistent organic pollutants (POPs) from the aqueous environment by nano-adsorbents: A review". Environmental Research 212:113123. September 2022. ↩
United States Environmental Protection Agency. "Mercury Emissions: The Global Context". April 2022. ↩
Washington State University. "Risks of Mercury in Fish". Accessed December 15, 2022. ↩