summarize text each 150 words
elinaa
GarbageIsland-TheGreatPacificGarbagePatch.docx
The text below is adapted from an article which appears on the Yale Environment Review website,
The Yale Environment Review is run by students of Yale University;
“The Yale Environment Review is a student-run publication that aims to increase access to the latest developments in environmental studies. We aim to shed light on cutting-edge environmental research through summaries, analysis, and interviews. We do through three types of content:
· Focus articles explore one recent peer-reviewed article and connect its findings to our everyday lives.
· Feature pieces build a story around a central theme using multiple recent peer-reviewed articles.
· Spotlights profile the people behind the latest research in the environmental field”
About Us (n.d.). Retrieved July 23, 2019, from Yale Environment Review website: https://environment-review.yale.edu/about-us
Words: 920
FK Grade: 7.3
FK Reading Ease: 50.6
< K2000 lexis: 78%
Adapted from;
Schoell, M. (2019, May 23). Garbage Island: The Great Pacific Garbage Patch. Retrieved July 15, 2019, from Yale Environment Review website: https://environment-review.yale.edu/garbage-island-great-pacific-garbage-patch
Garbage Island: The Great Pacific Garbage Patch
GLOSSARY
solely (adv); only e.g. Whether you pass or fail depends solely on your grades. Nothing else is counted.
accumulation (n); an amount of something which has collected over time e.g. You need to brush your teeth twice a day to stop the accumulation of plaque.
accumulate (v); to collect over time e.g. After 30 years in business, Mary had accumulated both experience and a large amount of money.
current (n); water moving in a particular direction. E.g. When I was swimming near the beach, a current suddenly carried me out. It was too strong for me to swim against.
durability (n); how long something will last. E.g. These cars are well known for their durability. Some of them last 30 or 40 years and still work.
debris (n); rubbish (often covering a wide area). E.g. After the explosion, the police searched through the debris to see if anyone remained alive.
organism (n); a living thing – plant or animal.
ingest (v); to eat or drink something
There is a growing island in the North Pacific Ocean - one that consists solely of trash. A new report presents the shocking reality of the size and composition of the Great Pacific Garbage Patch.
Image retrieved from https://pentanglearts.org/event/garbage-island/
Single-use plastics are part of our modern daily lives. They are cheap to produce, convenient, and clean. Given these advantages, it is perhaps not surprising that we produce over 300 million tons of plastic globally every year. However, since most plastics take almost 1,000 years to decompose, plastic use has caused enormous damage to the environment. Recycling can never provide a solution to this problem; less than 10% of plastic ends up being recycled. This means that most of our plastic either ends up in landfills or is carried through river systems and ultimately to the open ocean. In fact, a shocking 8 million tons of it ends up in the natural environment each year - equivalent to over 5,000 blue whales.
Once plastic reaches the ocean, waves, winds, and currents break it down and transport it in various directions. Depending on the size, density, and location of these plastic pieces, they may wash ashore, sink to the ocean floor, or get trapped in oceanic currents. Through a combination of environmental processes, circulating ocean currents form massive vortexes called gyres. Since the rise of plastic production, gyres have become places where garbage collects in large amounts. This problem is more than just an ugly collection of trash. The presence of plastics of all sizes in the ocean has detrimental effects on entire food chains of sea and land animals.
A problem is that these trash accumulation zones are quite difficult to quantify, due to their sheer volume and the size range of the plastics within them. In a recent study from Scientific Reports, a group of researchers led by Laurent Lebreton provides the most detailed estimates of the current size and composition of The Great Pacific Garbage Patch (GPGP), a massive marine debris accumulation zone in the North Pacific Ocean. They aimed to conduct a large-scale field monitoring effort to better understand the density and type of marine debris in and around the GPGP, and to use these data to predict its size and movement.
From 2015 to 2016, the team launched a large-scale, multi-vessel survey through the GPGP. A fleet of 18 vessels trawled a total of 652 nets across the ocean surface over the course of three months, hoping to collect a range of plastic sizes and identify their origin and age. After capture, researchers sorted samples by size class and material type. For several samples, the team was able to identify a language and manufacturing date. Of these samples, one third of the labels had Japanese inscriptions, and one third Chinese—an important reminder that plastic pollution is a global problem.
In addition to collecting and analysing pieces of plastic, the team used two low-flying planes to examine GPGP. This method allowed them to locate and identify larger pieces of plastic that their nets couldn’t capture (typically plastics larger than 0.5 meters). They incorporated this data into a model aimed at helping them understand how the GPGP has moved in position and increased in size over time.
The model shows that sea surface currents are the most important factor in driving trash to the GPGP. This means that while other environmental drivers such as wind and waves might play a small role in moving trash across the ocean, their real power is in washing trash ashore, pulling trash offshore, or breaking it down.
Overall, researchers estimated the GPGP to be 1.6 million km2—more than twice the size of Texas. Over the past 40 years, the rate of plastic accumulation has increased more and more rapidly. Of the marine debris collected, 99.9% were plastics. Nets, ropes, and lines used for fisheries and the marine industry composed 52% of the GPGP by mass. Because fishing equipment is designed for durability in marine environments, it is typically made of harder plastics called polyethylene and polypropylene. These plastics are incredibly resistant to degradation over long periods of time. As increasing populations, development, and income are likely to bring growth to the fishing industry, better accountability and management of equipment in commercial fishing is of great importance.
Plastic waste in our oceans can have harmful effects on habitat quality and human health. Over time, larger pieces of plastic within the GPGP break down into smaller pieces, become suspended in the water, or sink to the ocean floor. Marine organisms or seabirds often ingest these plastics by mistaking them for food, not realizing that they are cannot be digested and have no nutritional value. Even the most microscopic pieces of plastic cause serious problems in the marine environment. Through a process called bioaccumulation, microplastics accumulate within organisms and make their way through the marine food chain, eventually, ending up on our plates. This disturbing reality is already having major impacts on food safety and the fishing industry.
Understanding the size, growth rate, and composition of the GPGP should help communities and nations worldwide to more efficiently manage their waste and encourage a reduction in plastic production. Additionally, these results provide a call to action for policy changes around plastic use in the fishing industry. It is also essential that consumers change their behaviours when it comes to single-use plastics. Reduce, reuse, and refuse plastic — the health of our oceans is a global responsibility, and its protection depends on support from individuals to governments.
