Formation | 2013 |
---|---|
Founded at | Delft, Netherlands |
Type | Stichting |
Purpose | Cleaning the oceans |
Headquarters | Rotterdam, Netherlands |
Coordinates | 51°55′15″N 4°28′06″E / 51.92083°N 4.46833°E |
Boyan Slat | |
Budget (2022) | € 54.705 million [1] |
Staff | 120 [2] |
Website |
www |
The Ocean Cleanup is a nonprofit environmental engineering organization based in the Netherlands that develops technology to extract plastic pollution from the oceans and to capture it in rivers before it can reach the ocean. Their initial focus was on the Pacific Ocean and its garbage patch, and extended to rivers in countries including Indonesia, Guatemala, and the United States.
It was founded in 2013 by Boyan Slat, a Dutch inventor [3] [4] [5] who serves as its CEO. It develops both ocean and river systems. Its ocean system consists of a floating barrier at the surface of the water deployed in oceanic gyres to collect marine debris, [6] designed in a shape to funnel the debris into a collecting net, or directly into a wide-mouthed boat for on-site processing. The project aims to launch 60 1km-long systems, which they predict could remove 50% of the debris in the Great Pacific Garbage Patch five years from deployment. [7] [8]
Its river system consists of similar floating barriers, sometimes anchored to the riverbank. The Ocean Cleanup also publishes scientific papers, [9] [10] [11] [12] and estimates that "1% of rivers are responsible for 80% of the pollution in the world's seas". [13] [14] [15] They aim to have 1000 rivers protected by such barriers.
Slat proposed the cleanup project and supporting system in 2012. In October, he outlined the project in a TED-talk. The initial design consisted of long, floating barriers fixed to the seabed, attached to a central platform shaped like a manta ray for stability. The barriers would direct the floating plastic to the central platform, which would remove the plastic from the water. Slat did not specify the dimensions of this system in the talk. [16]
In 2014, the design replaced the central platform with a tower detached from the floating barriers. This platform would collect the plastic using a conveyor belt. The floating barrier was proposed to be 100 km long. They conducted and published a feasibility study. [17]
In 2015, this design won the London Design Museum Design of the Year, [18] [19] and the INDEX: Award. [20] [21] Later that year, scale model tests were conducted [22] in wave pools at Deltares and MARIN, testing the dynamics and load of the barrier in ocean conditions, and gathering data for computational modeling. [23]
A 100-metre segment went through a test in the North Sea in the summer of 2016. [22] [24] The test indicated that conventional oil containment booms would not stand up over time, and they changed the floater material to a hard-walled HDPE pipe. [25]
In May 2017, significant changes to the conceptual design were made: [24]
External videos | |
---|---|
The ocean plastic cleanup of Boyan Slat – a 2018 documentary of the organization, operational detail of System 001, and excerpt footage of the early life of the founder ( VPRO, full episode) |
Tests in 2018 [30] led to sea anchors being removed, and the opening of the U turned to face the direction of travel, by creating more drag in the middle with a deeper underwater screen. [31] [32]
On 9 September 2018, System 001 (nicknamed Wilson in reference to the floating volleyball in the 2000 film Cast Away) [33] [7] deployed from San Francisco. The ship Maersk Launcher towed the system to a position 240 nautical miles off the coast, where it was put through a series of sea trials. [34] It consisted of a 600 m (2,000 ft) long barrier with a 3 m (9.8 ft) wide skirt hanging beneath it.[ citation needed] It was made from HDPE, and consists of 50x12 m sections joined. [35] It was unmanned and incorporated solar-powered monitoring and navigation systems, including GPS, cameras, lanterns and AIS. [36] The barrier and the screen were produced by an Austrian supplier. [37]
In October it was towed to the Great Pacific Garbage Patch for real-world duty. [38] System 001 encountered difficulties retaining the plastic collected. [39] The system collected debris, but soon lost it because the barrier did not retain a consistent speed through the water. [40] In December, mechanical stress caused an 18-meter section to detach, and the rig was moved to Hawaii for inspection and repair. During the two months of operation, it had captured 2 metric tons of plastic. [41] [42] [43]
In June 2019, after four months of root cause analyses and redesign, [44] [45] System 001/B was deployed, [46] [47] with a water-borne parachute to slow the system, and an extended cork line to hold the screen in place. [48] [49] This successfully captured smaller plastic, [49] reduced the barrier size by two-thirds, and was easier to adjust offshore. [50] [51] [52]
In October 2019, The Ocean Cleanup unveiled a floating barrier for river cleanup, The Interceptor, to intercept river plastic and prevent it from reaching the ocean. [53] Two systems were deployed in Jakarta (Indonesia) and Klang (Malaysia). [54]
In January 2020, flooding broke the barrier of Interceptor 001 in Jakarta. It was replaced with a newer model with a stronger screen, simpler design, and an adjustable better-defined weak link. [55] [56] A third Interceptor was deployed in Santo Domingo, in the Dominican Republic. [57] In December, The Ocean Cleanup announced they would start large-scale production of the Interceptor series. [58]
In July 2022, an Interceptor Original was deployed near the mouth of Ballona Creek in southwestern Los Angeles County, California. This was the first Interceptor Original installed in the United States, and the second of its kind to be deployed globally. [59]
In May 2022, the Ocean Cleanup trialed a new Interceptor called Trashfence on the Rio Las Vacas in Guatemala. It was anchored to the riverbed, and the anchors washed out. [60] In April 2023, they returned with a pair of new Interceptors, at a point on the river with slower current, anchored to the riverbank. This was successful, and soon became their most prolific site; by June 13, they had already removed 850 tonnes of plastic from the river. [61]
In July 2021, a new design called System 002, also known as "Jenny", was deployed in the Great Pacific Garbage Patch for testing. [62] In October, the organization announced that the system had gathered 28,000 kilograms (62,000 lb) of trash. In October, the project announced plans for System 03, which would span up to 2.5 km (1.6 mi). [63]
By December, the project announced it had removed more than 150 tonnes of plastic from the Great Pacific Garbage Patch [65] and announced it would transition to the new longer System 03 the following year. [66]
In May 2023, the project deployed its System 03 barrier, 1,750 meters long. The system included a retention zone where material is held before it is removed from the water, with the nets' mesh size there was increased from 10 to 50 mm. This is to allow marine life such as fish and turtles to escape, and to allow smaller creatures such as blue buttons and violet snails to pass through. [67]
System 03 was estimated to have 5x the capacity of System 002, which is why they dropped a 0 from the naming scheme:
[O]ur modeling suggests it may be possible to clean the entire GPGP with as few as 10 systems. That’s why we knocked off one of the zeroes from ‘002’ when we named ‘03’ – we no longer need a three-figure amount of systems to clean all five ocean garbage patches around the world. [68]
The latest Jenny design uses a towed, floating structure. The structure acts as a containment boom. A permeable screen underneath the float catches subsurface debris. [62] It incorporated an 800 m (2,600 ft) barrier and added active propulsion to allow the system to operate at higher speed. Crewed boats tow the U-shaped barrier through the water at 1.5 knots. The ship can also be steered to areas with higher waste densities. [62] In July 2022, the floating system reached the milestone of 100,000 kg of plastic removed from the Great Pacific Garbage Patch. [69]
The Interceptor is a solar-powered, automated system designed to capture and extract waste. Along with an optimized water flow path, a barrier guides rubbish towards the opening of the Interceptor and onto the conveyor belt, which delivers waste to the shuttle. The shuttle deposits the waste equally into one of six bins according to sensors. When the bins are almost full, local operators are informed with an automated message. They then empty them and send the waste to local waste management facilities. The Interceptor project is similar to a smaller-scale local project called Mr. Trash Wheel developed in 2008 for Maryland's Baltimore harbor.
In 2021, The Ocean Cleanup began expanding their Interceptor systems to be able to tackle a wider range of rivers. [70] [71] The Interceptor Barricade developed for Rio Las Vacas in 2023 was the first model designed for very high-throughput rivers that may carry 10,000 kg of trash a day.
Unit | Type | Ocean | Location | Deployed | Status |
---|---|---|---|---|---|
001 | System 001 | Pacific Ocean | Great Pacific Garbage Patch | 2018 | Concluded |
002 | System 002 | Pacific Ocean | Great Pacific Garbage Patch | 2021 | Concluded |
03 | System 03 | Pacific Ocean | Great Pacific Garbage Patch | 2023 | Deployed |
Unit | Type | River | Location | Deployed | Status |
---|---|---|---|---|---|
001 | Interceptor Original 1st Gen | Cengkareng Drain | Jakarta, Indonesia | 2019 | Deployed |
002 | Interceptor Original 2nd Gen | Klang | Selangor, Malaysia | 2019 | Deployed |
003 | Interceptor Original 2nd Gen | Can Tho | Can Tho, Vietnam | 2021 | Deployed |
004 | Interceptor Original 2nd Gen | Rio Ozama | Santo Domingo, Dominican Republic | 2020 | Deployed |
005 | Interceptor Original 3rd Gen | Klang | Selangor, Malaysia | 2021 | Deployed |
006 | Interceptor Barricade | Las Vacas | Guatemala City, Guatemala | 2023 | Deployed |
007 | Interceptor Original 3rd Gen | Ballona Creek | Los Angeles County, California, United States | 2022 | Deployed |
008 | Interceptor Barrier + Tender | Kingston Harbour (Kingston Pen Gully) | Kingston, Jamaica | 2021 | Deployed |
009 | Interceptor Barrier + Tender | Kingston Harbour (Barnes Gully) | Kingston, Jamaica | 2021 | Deployed |
010 | Interceptor Barrier + Tender | Kingston Harbour (Rae Town Gully) | Kingston, Jamaica | 2021 | Deployed |
011 | Interceptor Barrier + Tender | Kingston Harbour (Tivoli Gully) | Kingston, Jamaica | 2022 | Deployed |
012 | Interceptor Guard | Kingston Harbour (D'Aguilar Gully) | Kingston, Jamaica | 2023 | Deployed |
013 | Interceptor Barrier + Tender, Interceptor Guard | Kingston Harbour (Mountain View Gully) | Kingston, Jamaica | 2023 | Deployed |
014 | Interceptor Guard | Kingston Harbour (Shoemaker Gully) | Kingston, Jamaica | 2023 | Deployed |
019 | Interceptor Original 3rd Gen | Chao Phraya | Bangkok, Thailand | 2024 | Deployed |
020 | Interceptor Original 3rd Gen | Cisadane | Indonesia | ? | Planned |
In August 2015, The Ocean Cleanup conducted the Mega Expedition, in which a fleet of approximately 30 vessels, with lead ship R/V Ocean Starr, crossed the Great Pacific Garbage Patch and mapped an area of 3.5 million square kilometers. The expedition collected data on the size, concentration and total mass of the plastic in the patch. According to the organization, this expedition collected more data on oceanic plastic pollution than the last 40 years combined. [78] [79]
In September and October 2016, The Ocean Cleanup launched the Aerial Expedition, in which a C-130 Hercules aircraft conducted the first ever series of aerial surveys to map the Great Pacific Garbage Patch. The goal was specifically to quantify the amount of large debris, including ghost nets in the patch. [80] Slat stated that the crew saw more debris than expected. [81]
The project released an app called The Ocean Cleanup Survey App, which enables others to survey the ocean for plastic, and report their observations. [82]
In February 2015, the research team published a study in Biogeosciences about the vertical distribution of plastic, based on samples collected in the North Atlantic Gyre. They found that plastic concentration decreases exponentially with depth, with the highest concentration at the surface, and approaching zero just a few meters deeper. [32] [83] A follow-up paper was published in Scientific Reports in October 2016. [84]
In June 2017, researchers published a paper in Nature Communications, with a model of the river plastic input into the ocean. Their model estimates that between 1.15 and 2.41 million metric tonnes of plastic enter the world's oceans every year, with 86% of the input stemming from rivers in Asia. [85] [86] In December 2017, they published a paper in Environmental Science & Technology about pollutants in oceanic plastic they had sampled. [87]
In March 2018, they published a paper in Scientific Reports, summarizing the combined findings from the two expeditions. They estimated that the Patch contains 1.8 trillion pieces of floating plastic, with a total mass of 79,000 metric tonnes. Microplastics (< 0.5 cm) make up 94% of the pieces, accounting for 8% of the mass. The study suggests that the amount of plastic in the patch increased exponentially since 1970. [88]
In September 2019, they published a paper in Scientific Reports studying why emissions into the ocean are higher than the estimates of debris accumulated at the surface layer of the ocean. They argue that debris circulation dynamics offer an explanation for this missing plastic and suggest that there is a significant amount of time between initial emissions and accumulation offshore. The study also indicated that current microplastics are mostly a result of the degradations of plastic produced in the 1990s or before. [89] A followup study in May 2020 showed that part of the plastic at the surface of the Great Pacific Garbage Patch is breaking down into microplastics and sinking to the deep sea. Most debris is still found at the surface, with 90% in the first 5 meters. [90]
In October 2019, other researchers estimated that most ocean plastic pollution comes from cargo ships, with a majority from Chinese cargo ships alone. [91] A spokesperson from The Ocean Cleanup said: "Everyone talks about saving the oceans by stopping using plastic bags, straws and single use packaging. That's important, but when we head out on the ocean, that's not necessarily what we find." [92]
The Ocean Cleanup raised over 2 million USD with the help of a crowdfunding campaign in 2014. [93]
As of 2019, it was mainly funded by donations and in-kind sponsors, including Maersk, Salesforce.com chief executive Marc Benioff, Peter Thiel, Julius Baer Foundation, The Coca-Cola Company and Royal DSM. [94] [95]
In 2019, it received a 10 million AUD award from the Macquarie Group Foundation as part of its 50th anniversary celebration. [96]
In October 2020, they unveiled a product made from plastic certified from the Great Pacific Garbage Patch, The Ocean Cleanup sunglasses, to help fund the continuation of the cleanup. [97] They made 21,000 sunglasses, sold at €200 apiece. They worked with DNV GL to develop a certification for plastic from water sources and the sunglasses were certified to originate from the GPGP. [97] [98] The sunglasses were designed by Yves Béhar and manufactured by Safilo. They sold out in early 2022. [99]
In October 2021, they were part of the #TeamSeas fundraising campaign led by YouTube stars Mark Rober and MrBeast, and received roughly half of the $30 million raised.
In 2022, Kia signed a seven-year deal to become a global partner of The Ocean Cleanup through funding and in-kind contributions. The partnership will fund the construction of a new Interceptor and will allow for recycled plastics to be used in the manufacturing process of Kia. [100]
In early 2023 the organization received its largest private donation to date of $25 million from Joe Gebbia, co-founder of Airbnb. [101]
Criticisms and doubts about method, feasibility, efficiency and return on investment have been raised in the scientific community. Miriam Goldstein, director of ocean policy at the Center for American Progress, stated in 2019 that compared to the ocean system, devices closer to shore are easier to maintain, and would likely recover more plastic per dollar spent overall. [102]
The team has expressed their own concerns that the devices could imperil sea life, [103] including neustons, communities of pleustons, Portuguese man-of-war, sea snails, and sail jellyfish that live near the ocean surface, [104] and have monitored for such impacts. A modelling study concluded that it is currently impossible to determine how damaging at-sea plastic removal strategies (such as those of The Ocean Cleanup) would be for marine life, with impacts potentially ranging from mild to severe. [105]
It is understood that this approach cannot solve the whole problem. [5] [106] Plastic in the oceans is spread far beyond the gyres; experts estimate that less than 5% of all the plastic pollution which enters the oceans makes its way into any of the garbage patches. [5]: 1 Much of the plastic that does make it to gyres is not floating at the surface, [103] though recent research confirms it is mostly within the first meters. Plastic in rivers can be more easily trapped at the source but that accounts for only a part of all plastic in the oceans.
In 2022, it collected 923 000 kg of ocean and river plastic on a budget of €54.705 million; a cost of €59.2/kg. [1]
The project and its founder have been recognized in many fora.
"I certainly hope they will be able to get it to work, but this is a very difficult environment where equipment breaks, which is why you normally do things closer to shore, where things are easier to repair," said Miriam Goldstein, director of ocean policy at the Center for American Progress, a liberal think tank. ... Goldstein wrote her Ph.D. dissertation in oceanography on the Pacific Garbage Patch. ... "A great deal of money is being spent on this Ocean Cleanup device," Goldstein said, "when there are various other methods that remove a lot more plastic, for a lot less money."
Formation | 2013 |
---|---|
Founded at | Delft, Netherlands |
Type | Stichting |
Purpose | Cleaning the oceans |
Headquarters | Rotterdam, Netherlands |
Coordinates | 51°55′15″N 4°28′06″E / 51.92083°N 4.46833°E |
Boyan Slat | |
Budget (2022) | € 54.705 million [1] |
Staff | 120 [2] |
Website |
www |
The Ocean Cleanup is a nonprofit environmental engineering organization based in the Netherlands that develops technology to extract plastic pollution from the oceans and to capture it in rivers before it can reach the ocean. Their initial focus was on the Pacific Ocean and its garbage patch, and extended to rivers in countries including Indonesia, Guatemala, and the United States.
It was founded in 2013 by Boyan Slat, a Dutch inventor [3] [4] [5] who serves as its CEO. It develops both ocean and river systems. Its ocean system consists of a floating barrier at the surface of the water deployed in oceanic gyres to collect marine debris, [6] designed in a shape to funnel the debris into a collecting net, or directly into a wide-mouthed boat for on-site processing. The project aims to launch 60 1km-long systems, which they predict could remove 50% of the debris in the Great Pacific Garbage Patch five years from deployment. [7] [8]
Its river system consists of similar floating barriers, sometimes anchored to the riverbank. The Ocean Cleanup also publishes scientific papers, [9] [10] [11] [12] and estimates that "1% of rivers are responsible for 80% of the pollution in the world's seas". [13] [14] [15] They aim to have 1000 rivers protected by such barriers.
Slat proposed the cleanup project and supporting system in 2012. In October, he outlined the project in a TED-talk. The initial design consisted of long, floating barriers fixed to the seabed, attached to a central platform shaped like a manta ray for stability. The barriers would direct the floating plastic to the central platform, which would remove the plastic from the water. Slat did not specify the dimensions of this system in the talk. [16]
In 2014, the design replaced the central platform with a tower detached from the floating barriers. This platform would collect the plastic using a conveyor belt. The floating barrier was proposed to be 100 km long. They conducted and published a feasibility study. [17]
In 2015, this design won the London Design Museum Design of the Year, [18] [19] and the INDEX: Award. [20] [21] Later that year, scale model tests were conducted [22] in wave pools at Deltares and MARIN, testing the dynamics and load of the barrier in ocean conditions, and gathering data for computational modeling. [23]
A 100-metre segment went through a test in the North Sea in the summer of 2016. [22] [24] The test indicated that conventional oil containment booms would not stand up over time, and they changed the floater material to a hard-walled HDPE pipe. [25]
In May 2017, significant changes to the conceptual design were made: [24]
External videos | |
---|---|
The ocean plastic cleanup of Boyan Slat – a 2018 documentary of the organization, operational detail of System 001, and excerpt footage of the early life of the founder ( VPRO, full episode) |
Tests in 2018 [30] led to sea anchors being removed, and the opening of the U turned to face the direction of travel, by creating more drag in the middle with a deeper underwater screen. [31] [32]
On 9 September 2018, System 001 (nicknamed Wilson in reference to the floating volleyball in the 2000 film Cast Away) [33] [7] deployed from San Francisco. The ship Maersk Launcher towed the system to a position 240 nautical miles off the coast, where it was put through a series of sea trials. [34] It consisted of a 600 m (2,000 ft) long barrier with a 3 m (9.8 ft) wide skirt hanging beneath it.[ citation needed] It was made from HDPE, and consists of 50x12 m sections joined. [35] It was unmanned and incorporated solar-powered monitoring and navigation systems, including GPS, cameras, lanterns and AIS. [36] The barrier and the screen were produced by an Austrian supplier. [37]
In October it was towed to the Great Pacific Garbage Patch for real-world duty. [38] System 001 encountered difficulties retaining the plastic collected. [39] The system collected debris, but soon lost it because the barrier did not retain a consistent speed through the water. [40] In December, mechanical stress caused an 18-meter section to detach, and the rig was moved to Hawaii for inspection and repair. During the two months of operation, it had captured 2 metric tons of plastic. [41] [42] [43]
In June 2019, after four months of root cause analyses and redesign, [44] [45] System 001/B was deployed, [46] [47] with a water-borne parachute to slow the system, and an extended cork line to hold the screen in place. [48] [49] This successfully captured smaller plastic, [49] reduced the barrier size by two-thirds, and was easier to adjust offshore. [50] [51] [52]
In October 2019, The Ocean Cleanup unveiled a floating barrier for river cleanup, The Interceptor, to intercept river plastic and prevent it from reaching the ocean. [53] Two systems were deployed in Jakarta (Indonesia) and Klang (Malaysia). [54]
In January 2020, flooding broke the barrier of Interceptor 001 in Jakarta. It was replaced with a newer model with a stronger screen, simpler design, and an adjustable better-defined weak link. [55] [56] A third Interceptor was deployed in Santo Domingo, in the Dominican Republic. [57] In December, The Ocean Cleanup announced they would start large-scale production of the Interceptor series. [58]
In July 2022, an Interceptor Original was deployed near the mouth of Ballona Creek in southwestern Los Angeles County, California. This was the first Interceptor Original installed in the United States, and the second of its kind to be deployed globally. [59]
In May 2022, the Ocean Cleanup trialed a new Interceptor called Trashfence on the Rio Las Vacas in Guatemala. It was anchored to the riverbed, and the anchors washed out. [60] In April 2023, they returned with a pair of new Interceptors, at a point on the river with slower current, anchored to the riverbank. This was successful, and soon became their most prolific site; by June 13, they had already removed 850 tonnes of plastic from the river. [61]
In July 2021, a new design called System 002, also known as "Jenny", was deployed in the Great Pacific Garbage Patch for testing. [62] In October, the organization announced that the system had gathered 28,000 kilograms (62,000 lb) of trash. In October, the project announced plans for System 03, which would span up to 2.5 km (1.6 mi). [63]
By December, the project announced it had removed more than 150 tonnes of plastic from the Great Pacific Garbage Patch [65] and announced it would transition to the new longer System 03 the following year. [66]
In May 2023, the project deployed its System 03 barrier, 1,750 meters long. The system included a retention zone where material is held before it is removed from the water, with the nets' mesh size there was increased from 10 to 50 mm. This is to allow marine life such as fish and turtles to escape, and to allow smaller creatures such as blue buttons and violet snails to pass through. [67]
System 03 was estimated to have 5x the capacity of System 002, which is why they dropped a 0 from the naming scheme:
[O]ur modeling suggests it may be possible to clean the entire GPGP with as few as 10 systems. That’s why we knocked off one of the zeroes from ‘002’ when we named ‘03’ – we no longer need a three-figure amount of systems to clean all five ocean garbage patches around the world. [68]
The latest Jenny design uses a towed, floating structure. The structure acts as a containment boom. A permeable screen underneath the float catches subsurface debris. [62] It incorporated an 800 m (2,600 ft) barrier and added active propulsion to allow the system to operate at higher speed. Crewed boats tow the U-shaped barrier through the water at 1.5 knots. The ship can also be steered to areas with higher waste densities. [62] In July 2022, the floating system reached the milestone of 100,000 kg of plastic removed from the Great Pacific Garbage Patch. [69]
The Interceptor is a solar-powered, automated system designed to capture and extract waste. Along with an optimized water flow path, a barrier guides rubbish towards the opening of the Interceptor and onto the conveyor belt, which delivers waste to the shuttle. The shuttle deposits the waste equally into one of six bins according to sensors. When the bins are almost full, local operators are informed with an automated message. They then empty them and send the waste to local waste management facilities. The Interceptor project is similar to a smaller-scale local project called Mr. Trash Wheel developed in 2008 for Maryland's Baltimore harbor.
In 2021, The Ocean Cleanup began expanding their Interceptor systems to be able to tackle a wider range of rivers. [70] [71] The Interceptor Barricade developed for Rio Las Vacas in 2023 was the first model designed for very high-throughput rivers that may carry 10,000 kg of trash a day.
Unit | Type | Ocean | Location | Deployed | Status |
---|---|---|---|---|---|
001 | System 001 | Pacific Ocean | Great Pacific Garbage Patch | 2018 | Concluded |
002 | System 002 | Pacific Ocean | Great Pacific Garbage Patch | 2021 | Concluded |
03 | System 03 | Pacific Ocean | Great Pacific Garbage Patch | 2023 | Deployed |
Unit | Type | River | Location | Deployed | Status |
---|---|---|---|---|---|
001 | Interceptor Original 1st Gen | Cengkareng Drain | Jakarta, Indonesia | 2019 | Deployed |
002 | Interceptor Original 2nd Gen | Klang | Selangor, Malaysia | 2019 | Deployed |
003 | Interceptor Original 2nd Gen | Can Tho | Can Tho, Vietnam | 2021 | Deployed |
004 | Interceptor Original 2nd Gen | Rio Ozama | Santo Domingo, Dominican Republic | 2020 | Deployed |
005 | Interceptor Original 3rd Gen | Klang | Selangor, Malaysia | 2021 | Deployed |
006 | Interceptor Barricade | Las Vacas | Guatemala City, Guatemala | 2023 | Deployed |
007 | Interceptor Original 3rd Gen | Ballona Creek | Los Angeles County, California, United States | 2022 | Deployed |
008 | Interceptor Barrier + Tender | Kingston Harbour (Kingston Pen Gully) | Kingston, Jamaica | 2021 | Deployed |
009 | Interceptor Barrier + Tender | Kingston Harbour (Barnes Gully) | Kingston, Jamaica | 2021 | Deployed |
010 | Interceptor Barrier + Tender | Kingston Harbour (Rae Town Gully) | Kingston, Jamaica | 2021 | Deployed |
011 | Interceptor Barrier + Tender | Kingston Harbour (Tivoli Gully) | Kingston, Jamaica | 2022 | Deployed |
012 | Interceptor Guard | Kingston Harbour (D'Aguilar Gully) | Kingston, Jamaica | 2023 | Deployed |
013 | Interceptor Barrier + Tender, Interceptor Guard | Kingston Harbour (Mountain View Gully) | Kingston, Jamaica | 2023 | Deployed |
014 | Interceptor Guard | Kingston Harbour (Shoemaker Gully) | Kingston, Jamaica | 2023 | Deployed |
019 | Interceptor Original 3rd Gen | Chao Phraya | Bangkok, Thailand | 2024 | Deployed |
020 | Interceptor Original 3rd Gen | Cisadane | Indonesia | ? | Planned |
In August 2015, The Ocean Cleanup conducted the Mega Expedition, in which a fleet of approximately 30 vessels, with lead ship R/V Ocean Starr, crossed the Great Pacific Garbage Patch and mapped an area of 3.5 million square kilometers. The expedition collected data on the size, concentration and total mass of the plastic in the patch. According to the organization, this expedition collected more data on oceanic plastic pollution than the last 40 years combined. [78] [79]
In September and October 2016, The Ocean Cleanup launched the Aerial Expedition, in which a C-130 Hercules aircraft conducted the first ever series of aerial surveys to map the Great Pacific Garbage Patch. The goal was specifically to quantify the amount of large debris, including ghost nets in the patch. [80] Slat stated that the crew saw more debris than expected. [81]
The project released an app called The Ocean Cleanup Survey App, which enables others to survey the ocean for plastic, and report their observations. [82]
In February 2015, the research team published a study in Biogeosciences about the vertical distribution of plastic, based on samples collected in the North Atlantic Gyre. They found that plastic concentration decreases exponentially with depth, with the highest concentration at the surface, and approaching zero just a few meters deeper. [32] [83] A follow-up paper was published in Scientific Reports in October 2016. [84]
In June 2017, researchers published a paper in Nature Communications, with a model of the river plastic input into the ocean. Their model estimates that between 1.15 and 2.41 million metric tonnes of plastic enter the world's oceans every year, with 86% of the input stemming from rivers in Asia. [85] [86] In December 2017, they published a paper in Environmental Science & Technology about pollutants in oceanic plastic they had sampled. [87]
In March 2018, they published a paper in Scientific Reports, summarizing the combined findings from the two expeditions. They estimated that the Patch contains 1.8 trillion pieces of floating plastic, with a total mass of 79,000 metric tonnes. Microplastics (< 0.5 cm) make up 94% of the pieces, accounting for 8% of the mass. The study suggests that the amount of plastic in the patch increased exponentially since 1970. [88]
In September 2019, they published a paper in Scientific Reports studying why emissions into the ocean are higher than the estimates of debris accumulated at the surface layer of the ocean. They argue that debris circulation dynamics offer an explanation for this missing plastic and suggest that there is a significant amount of time between initial emissions and accumulation offshore. The study also indicated that current microplastics are mostly a result of the degradations of plastic produced in the 1990s or before. [89] A followup study in May 2020 showed that part of the plastic at the surface of the Great Pacific Garbage Patch is breaking down into microplastics and sinking to the deep sea. Most debris is still found at the surface, with 90% in the first 5 meters. [90]
In October 2019, other researchers estimated that most ocean plastic pollution comes from cargo ships, with a majority from Chinese cargo ships alone. [91] A spokesperson from The Ocean Cleanup said: "Everyone talks about saving the oceans by stopping using plastic bags, straws and single use packaging. That's important, but when we head out on the ocean, that's not necessarily what we find." [92]
The Ocean Cleanup raised over 2 million USD with the help of a crowdfunding campaign in 2014. [93]
As of 2019, it was mainly funded by donations and in-kind sponsors, including Maersk, Salesforce.com chief executive Marc Benioff, Peter Thiel, Julius Baer Foundation, The Coca-Cola Company and Royal DSM. [94] [95]
In 2019, it received a 10 million AUD award from the Macquarie Group Foundation as part of its 50th anniversary celebration. [96]
In October 2020, they unveiled a product made from plastic certified from the Great Pacific Garbage Patch, The Ocean Cleanup sunglasses, to help fund the continuation of the cleanup. [97] They made 21,000 sunglasses, sold at €200 apiece. They worked with DNV GL to develop a certification for plastic from water sources and the sunglasses were certified to originate from the GPGP. [97] [98] The sunglasses were designed by Yves Béhar and manufactured by Safilo. They sold out in early 2022. [99]
In October 2021, they were part of the #TeamSeas fundraising campaign led by YouTube stars Mark Rober and MrBeast, and received roughly half of the $30 million raised.
In 2022, Kia signed a seven-year deal to become a global partner of The Ocean Cleanup through funding and in-kind contributions. The partnership will fund the construction of a new Interceptor and will allow for recycled plastics to be used in the manufacturing process of Kia. [100]
In early 2023 the organization received its largest private donation to date of $25 million from Joe Gebbia, co-founder of Airbnb. [101]
Criticisms and doubts about method, feasibility, efficiency and return on investment have been raised in the scientific community. Miriam Goldstein, director of ocean policy at the Center for American Progress, stated in 2019 that compared to the ocean system, devices closer to shore are easier to maintain, and would likely recover more plastic per dollar spent overall. [102]
The team has expressed their own concerns that the devices could imperil sea life, [103] including neustons, communities of pleustons, Portuguese man-of-war, sea snails, and sail jellyfish that live near the ocean surface, [104] and have monitored for such impacts. A modelling study concluded that it is currently impossible to determine how damaging at-sea plastic removal strategies (such as those of The Ocean Cleanup) would be for marine life, with impacts potentially ranging from mild to severe. [105]
It is understood that this approach cannot solve the whole problem. [5] [106] Plastic in the oceans is spread far beyond the gyres; experts estimate that less than 5% of all the plastic pollution which enters the oceans makes its way into any of the garbage patches. [5]: 1 Much of the plastic that does make it to gyres is not floating at the surface, [103] though recent research confirms it is mostly within the first meters. Plastic in rivers can be more easily trapped at the source but that accounts for only a part of all plastic in the oceans.
In 2022, it collected 923 000 kg of ocean and river plastic on a budget of €54.705 million; a cost of €59.2/kg. [1]
The project and its founder have been recognized in many fora.
"I certainly hope they will be able to get it to work, but this is a very difficult environment where equipment breaks, which is why you normally do things closer to shore, where things are easier to repair," said Miriam Goldstein, director of ocean policy at the Center for American Progress, a liberal think tank. ... Goldstein wrote her Ph.D. dissertation in oceanography on the Pacific Garbage Patch. ... "A great deal of money is being spent on this Ocean Cleanup device," Goldstein said, "when there are various other methods that remove a lot more plastic, for a lot less money."