Environmental effects of shipping

From Justapedia, unleashing the power of collective wisdom
Jump to navigation Jump to search

Part of a series on
Pollution
MAERSK MC KINNEY MÖLLER & MARSEILLE MAERSK (48694054418).jpg
Container ships in port
Air
Biological
Digital
Electromagnetic
Natural
Noise
Radiation
Soil
Solid waste
Space
Thermal
Visual
War
Water
Misc

Lists

Categories

The environmental effects of shipping include air pollution, water pollution, acoustic, and oil pollution.[1] Ships are responsible for more than 18 percent of some air pollutants.[2][which?]

As for greenhouse gas emissions, the International Maritime Organization (IMO) estimates that carbon dioxide emissions from shipping were equal to 2.2% of the global human-made emissions in 2012[3] and expects them to rise 50 to 250 percent by 2050 if no action is taken.[4]

Although in the movement of a given mass of cargo a given distance, ships are the most energy-efficient method, the sheer size of the maritime transport industry means that it has a significant effect on the environment.[5][6] The annual increasing amount of shipping overwhelms gains in efficiency, such as from slow-steaming. The growth in tonne-kilometers of sea shipment has averaged 4 percent yearly since the 1990s,[7] and it has grown by a factor of 5 since the 1970s. There are now over 100,000 transport ships at sea, of which about 6,000 are large container ships.[5]

The fact that shipping enjoys substantial tax privileges has contributed to the growing emissions.[8][9][10]

Ballast water

Main article: Ballast water discharge and the environment
A cargo ship discharging ballast water into the sea

Ballast water discharges by ships can have a negative impact on the marine environment.[1] Cruise ships, large tankers, and bulk cargo carriers use a huge amount of ballast water, which is often taken on in the coastal waters in one region after ships discharge wastewater or unload cargo, and discharged at the next port of call, wherever more cargo is loaded.[11] Ballast water discharge typically contains a variety of biological materials, including plants, animals, viruses, and bacteria. These materials often include non-native, nuisance, invasive, exotic species that can cause extensive ecological and economic damage to aquatic ecosystems along with serious human health problems.

Sound pollution

Noise pollution caused by shipping and other human enterprises has increased in recent history.[12] The noise produced by ships can travel long distances, and marine species who may rely on sound for their orientation, communication, and feeding, can be harmed by this sound pollution.[13][14]

The Convention on the Conservation of Migratory Species has identified ocean noise as a potential threat to marine life.[15] The disruption of whales' ability to communicate with one another is an extreme threat and is affecting their ability to survive. According to a Discovery Channel article on Sonic Sea Journeys Deep into the Ocean over the last century, extremely loud noise from commercial ships, oil and gas exploration, naval sonar exercises and other sources has transformed the ocean's delicate acoustic habitat, challenging the ability of whales and other marine life to prosper and ultimately to survive. Whales are starting to react to this in ways that are life-threatening. Kenneth C. Balcomb, a whale researcher and a former U.S Navy officer states that the day 15 March 2000, is the day of infamy. Although sonar helps to protect us, it is destroying marine life. According to IFAW Animal Rescue Program Director Katie Moore, "There's different ways that sounds can affect animals. There's that underlying ambient noise level that's rising, and rising, and rising that interferes with communication and their movement patterns. And then there's the more acute kind of traumatic impact of sound, that's causing physical damage or a really strong behavioral response. It's fight or flight".[citation needed]

Wildlife collisions

Carcass of a whale on a shore in Iceland
See also: Santa Barbara Channel § Risk of ship-whale collisions, and Vessel speed restrictions to reduce ship collisions with North Atlantic right whales

Marine mammals, such as whales and manatees, risk being struck by ships, causing injury and death.[1] For example, a collision with a ship traveling at only 15 knots has a 79% chance of being lethal to a whale.[16] Ship collisions may be one of the leading causes of population decline for whale sharks.[17]

One notable example of the impact of ship collisions is the endangered North Atlantic right whale, of which 400 or fewer remain.[18] The greatest danger to the North Atlantic right whale is injury sustained from ship strikes.[16] Between 1970 and 1999, 35.5% of recorded deaths were attributed to collisions.[19] From 1999 to 2003, incidents of mortality and serious injury attributed to ship strikes averaged one per year. From 2004 to 2006, that number increased to 2.6.[20] Deaths from collisions has become an extinction threat.[21] The United States' National Marine Fisheries Service (NMFS) and National Oceanic and Atmospheric Administration (NOAA) introduced vessel speed restrictions to reduce ship collisions with North Atlantic right whales in 2008, which expired in 2013.[22] However, in 2017 an unprecedented mortality event occurred, resulting in the deaths of 17 North Atlantic right whales caused primarily from ship-strikes and entanglement in fishing gear.[18]

Atmospheric pollution

Exhaust gases from ships are considered to be a significant source of air pollution, both for conventional pollutants and greenhouse gases.[1]

Conventional pollutants

Air pollution from ships is generated by diesel engines that burn high sulfur content fuel oil, also known as bunker oil, producing sulfur dioxide, nitrogen oxide and particulate, in addition to carbon monoxide, carbon dioxide, and hydrocarbons which again leads to the formation of aerosols and secondary chemicals reactions including formations of HCHO,[23] Ozone etc. in the atmosphere.[1] Diesel exhaust has been classified by the U.S. Environmental Protection Agency (EPA) as a likely human carcinogen. The agency recognizes that these emissions from marine diesel engines contribute to ozone and carbon monoxide nonattainment (i.e., failure to meet air quality standards), as well as adverse health effects associated with ambient concentrations of particulate matter and visibility, haze, acid deposition, and eutrophication and nitrification of water.[24] EPA estimates that large marine diesel engines accounted for about 1.6 percent of mobile source nitrogen oxide emissions and 2.8 percent of mobile source particulate emissions in the United States in 2000. Contributions of marine diesel engines can be higher on a port-specific basis. Ultra-low sulfur diesel (ULSD) is a standard for defining diesel fuel with substantially lowered sulfur contents. As of 2006, almost all of the petroleum-based diesel fuel available in Europe and North America is of a ULSD type. However, bunker oil is still available, and large marine engines are able to switch between the two types simply by opening and closing the respective valves from two different on-board fuel tanks.

In 2016, the IMO adopted new sulfur-emissions regulations for implementation by larger ships beginning in January 2020.[25][26][27]

Of total global air emissions, marine shipping accounts for 18 to 30 percent of the nitrogen oxides and 9% of the sulfur oxides.[2][28] Sulfur in the air creates acid rain which damages crops and buildings. When inhaled, sulfur is known to cause respiratory problems and even increases the risk of a heart attack.[29] According to Irene Blooming, a spokeswoman for the European environmental coalition Seas at Risk, the fuel used in oil tankers and container ships is high in sulfur and cheaper to buy compared to the fuel used for domestic land use. "A ship lets out around 50 times more sulfur than a lorry per tonne of cargo carried."[29]

Cities in the United States like Long Beach, Los Angeles, Houston, Galveston, and Pittsburgh see some of the heaviest shipping traffic, which has left local officials desperately trying to clean up the air.[30] Increasing trade between the United States and China is helping to increase the number of vessels navigating the Pacific and is exacerbating multiple environmental problems. To maintain the level of growth China is experiencing, large amounts of grain are being shipped to China. The numbers of shipments are expected to continue increasing.[31]

In contrast to sulfur emissions (which depend on the fuel used), nitrous oxide emissions are primarily a function of combustion temperature. As air contains over 70% nitrogen by volume, some of it will react with oxygen during combustion. Given that those reactions are endothermic, a higher amount of nitrous oxides will be produced at higher combustion temperatures. However, other pollutants, particularly unburned or partially burnt hydrocarbons (also known as hyperfine particulates or soot), will be more common at lower combustion temperatures, so there is a trade-off between nitrogen oxides and soot.

Other than replacing ambient air with pure oxygen or some other oxidizing agent, the only ways to significantly reduce the nitrogen oxide emissions are via passing flue gasses through a catalytic converter and/or diesel exhaust fluid treatment, whereby an aqueous solution of urea reacts with the nitrous oxides in the flue gas to produce nitrogen, carbon dioxide and water. However, both those options add cost and weight. Furthermore, the urea in diesel exhaust fluid is usually derived from fossil fuels, and therefore it is not carbon neutral.

A third option entails the use of wet scrubbers that essentially spray seawater through the exhaust column as it is pumped through a chamber. Depending on the detailed engineering-design attributes of the wet scrubber, these devices can wash out the sulfur oxides, soot and nitrogen oxides from the engine exhaust, thus leaving a sludge that contains soot and various acidic compounds (or neutralized compounds, if alkaline substances are mixed in with the scrubbing liquid beforehand).[32] This material can then be either treated via an on-board device (closed-loop system), or it can simply be dumped overboard (open-loop system). The discharged material can be harmful to marine life, especially in nearshore settings.

In a recent study, the future of ship emissions has been investigated and reported that the growth of carbon dioxide emissions do not change with most common alternatives such as Ultra-low sulfur diesel (ULSD) or liquified natural gas (LNG) as well as growing volume of methane emission due to methane slip through the LNG supply-chain.[33] Methane is a much more powerful greenhouse gas than carbon dioxide per unit volume, and is only slowly broken down in the environment by various chemical, photochemical and biological processes.

In inland-waters-based applications where sulfur cannot (fully) be removed from the fuel before combustion (desulfurization), flue gas scrubbing is commonly employed. However, this would add weight and cost on ships and produce a further waste stream (usually calcium sulfate if flue gases are scrubbed by being passed through calcium hydroxide solution) which would have to be disposed of, adding yet further cost. In addition, calcium hydroxide commonly being produced by calcination of calcium carbonate releases yet more carbon dioxide into the atmosphere. While this stream is comparatively small in relation to carbon-dioxide emissions caused by combustion of fossil fuels, it needs to be taken into account as well, as part of a complete life-cycle assessment.[citation needed]

Localized air pollution

Cruise ship haze over Juneau, Alaska

One source of environmental stresses on maritime vessels recently has come from states and localities, as they assess the contribution of commercial marine vessels to regional air quality problems when ships are docked at port.[34] For instance, large marine diesel engines are believed to contribute 7 percent of mobile source nitrogen oxide emissions in Baton Rouge and New Orleans, Louisiana. Ships can also have a significant impact in areas without large commercial ports: they contribute about 37 percent of total area nitrogen oxide emissions in the Santa Barbara, California area, and that percentage is expected to increase to 61 percent by 2015.[24] Again, there is little cruise-industry specific data on this issue. They comprise only a small fraction of the world shipping fleet, but cruise ship emissions may exert significant impacts on a local scale in specific coastal areas that are visited repeatedly. Shipboard incinerators also burn large volumes of garbage, plastics, and other waste, producing ash that must be disposed of. Incinerators may release toxic emissions as well.

In 2005, MARPOL Annex VI came into force to combat this problem. As such cruise ships now employ CCTV monitoring on the smokestacks as well as recorded measuring via opacity meter while some are also using clean burning gas turbines for electrical loads and propulsion in sensitive areas.

Greenhouse gas pollutants

See also: Initial IMO Strategy on the reduction of GHG emissions from ships

Maritime transport accounts for 3.5% to 4% of all climate change emissions, primarily carbon dioxide.[1][28] According to the World Bank, in 2022, the shipping industry's 3% of global greenhouse gas emissions make it "the sixth largest greenhouse gas emitter worldwide, ranking between Japan and Germany."[35][36][37]

Although the industry was not a focus of attention of the Paris Climate Accord signed in 2016, the United Nations and the IMO have discussed CO2 emissions goals and limits. The First Intersessional Meeting of the IMO Working Group on Greenhouse Gas Emissions[38] took place in Oslo, Norway on 23–27 June 2008. It was tasked with developing the technical basis for the reduction mechanisms that may form part of a future IMO regime to control greenhouse gas emissions from international shipping, and a draft of the actual reduction mechanisms themselves, for further consideration by the IMO's Marine Environment Protection Committee (MEPC).[39] In 2018, the industry discussed in London placing limits to cut levels from a benchmark of 2008 carbon dioxide emissions by 50% by the year 2050. Some methods of reducing emissions of the industry include lowering speeds of shipping (which can be potentially problematic for perishable goods) as well as changes to fuel standards.[40] In 2019, international shipping organizations, including the International Chamber of Shipping, proposed creating a $5 billion fund to support the research and technology necessary to cut GHG emissions.[41]

Another approach to reducing the impact of greenhouse gas emissions from shipping was launched by vetting agency RightShip, which developed an online "Greenhouse Gas (GHG) Emissions Rating" as a systematic way for the industry to compare a ship's CO2 emissions with peer vessels of a similar size and type. Based on the IMO Energy Efficiency Design Index (EEDI) that applies to ships built from 2013, RightShip's GHG Rating can also be applied to vessels built prior to 2013, allowing for effective vessel comparison across the world's fleet. The GHG Rating utilises an A to G scale, where A represents the most efficient ships. It measures the theoretical amount of carbon dioxide emitted per tonne nautical mile travelled, based on the design characteristics of the ship at time of build such as cargo carrying capacity, engine power and fuel consumption. Higher rated ships can deliver significantly lower CO2 emissions across the voyage length, which means they also use less fuel and are cheaper to run.[citation needed]

Decarbonization of shipping

Nuclear marine propulsion has been proposed as the only long-proven and scalable propulsion technology that produces practically zero greenhouse gas emissions.[42] Advances in small modular reactors which aim to mass produce nuclear power plants of smaller power output (e.g. the OPEN100 project aims for a 100 Megawatt pressurized water reactor whereas currently available Generation III+ reactors like the EPR have nameplate capacities in excess of a Gigawatt, or 1600 Megawatts in the case of the EPR) and lower cost could make nuclear marine propulsion more economic. Given a current global reactor fleet of just over 400 commercial nuclear power plants, shipping represents a potentially much larger market than land based power has been to date.

Net zero fuels could be used.[43][44] Green hydrogen and ammonia produced from zero-carbon electricity (solar or wind power), are "the most promising options ... to decarbonize shipping" in 2022, according to the World Bank.[43] Biofuels can be net-zero fuels if "the production of fuel removes a quantity of carbon dioxide from the atmosphere that is equivalent to the amount of carbon dioxide emitted during combustion."[43][45] On July 21, 2022, Carnival's AIDAprima "became the first larger scale cruise ship to be bunkered with a blend of marine biofuel ... made from 100% sustainable raw materials such as waste cooking oil, and marine gas oil (MGO)."[46] As of April 2022, "ammonia, methanol and methane are viable deep sea shipping fuels, while compressed and liquid hydrogen are not", according to a World Economic Forum article.[47] The world's first hydrogen-powered tugboat was launched in May 2022, at the Astilleros Armon shipyard in Navia, Spain, and is scheduled to enter service in the Port of Antwerp-Bruges in December 2022.[48][49] Dual fuels engines, fuel storage options, and retrofit readiness[50] are important to ensure adaptability.[47][51] Stena was the first shipowner in the world to retrofit a large vessel for methanol, converting its ro-pax Stena Germanica in 2015.[52][53] Stena is partnering with methanol producer Proman and with MAN Energy Solutions to retrofit engines for dual-fuel operation on diesel and methanol.[54][55]

Wind power is a traditional choice for shipping. Wallenius Marine is "developing the Oceanbird, a cargo ship powered by wind that can carry 7,000 cars."[56] K Line is installing Seawing wind propulsion systems on five of its bulk carriers. The kite parafoils, which fly about 300 meters above the sea level, are estimated to reduce emissions by about 20%.[57]

Battery power is useful for short trips. Sparky, an "all-electric 70 tonne bollard pull harbor tugboat", is "the first e-tug of its type in the world." Sparky was christened in Auckland in August 2022.[58] The world's first hybrid tugboat, the Foss tug Carolyn Dorothy, began operation in 2009 in the Port of Los Angeles and the Port of Long Beach.[59][60] The tour boat Kvitbjørn, ("polar bear"), operates in Svalbard, just a few hundred miles from the North Pole, piloting a newly developed Volvo Penta hybrid-electric propulsion system.[61] In June 2022, the Danish electric ferry Ellen made a record 90 km voyage on a single charge.[62]

In 2021 the Center for Strategic and International Studies stated that governments and shipping industry leaders, such as Maersk, Mediterranean Shipping Company, and France’s CMA CGM "have shown interest in decarbonization projects."[63][64][65][66] In 2021 the European Union (EU) signaled "strong policy support for maritime decarbonization through their ‘Fit For 55’ (FF55) proposal, a package of 14 legislative proposals."[67] However, as of June 2022, "only 33 out of 94 (35%) of the major shipping companies have a clearly expressed target to be net zero by latest 2050 and/or have committed to IMO targets of 50% absolute reduction in 2050 compared to the 2008 level."[68]

Groups that represent more than 90% of the global shipping industry have called for a globally applicable carbon tax on the shipping industry's emissions, in order to provide financial incentives for implementation of new technologies, and provide necessary funding for research and development.[69]

A 2021 article states that extensive research and development is needed, as well as retrofitting and operational changes.[70]

The rapidly changing industry response to decarbonization can be monitored in a weekly newsletter,[71] several conferences,[72][73][74][75][76][77][78] and a two day overview online course.[79]

"Delay beyond 2023 would mean the future transition for international shipping is too rapid to be feasible," says Alice Larkin. "It has to be all hands on deck for international shipping now.”[70]

Oil spills

Most commonly associated with ship pollution are oil spills.[1] While less frequent than the pollution that occurs from daily operations, oil spills have devastating effects. While being toxic to marine life, polycyclic aromatic hydrocarbons (PAHs), the components in crude oil, are very difficult to clean up, and last for years in the sediment and marine environment.[80] Marine species constantly exposed to PAHs can exhibit developmental problems, susceptibility to disease, and abnormal reproductive cycles. One of the more widely known spills was the Exxon Valdez incident in Alaska. The ship ran aground and dumped a massive amount of oil into the ocean in March 1989. Despite efforts of scientists, managers and volunteers, over 400,000 seabirds, about 1,000 sea otters, and immense numbers of fish were killed.[80]

Wastewater

The cruise line industry dumps 970,000 litres (255,000 US gal) of greywater and 110,000 litres (30,000 US gal) of blackwater into the sea every day.[1]

Blackwater is sewage, wastewater from toilets and medical facilities, which can contain harmful bacteria, pathogens, viruses, intestinal parasites, and harmful nutrients. Discharges of untreated or inadequately treated sewage can cause bacterial and viral contamination of fisheries and shellfish beds, producing risks to public health. Nutrients in sewage, such as nitrogen and phosphorus, promote excessive algal blooms, which consumes oxygen in the water and can lead to fish kills and destruction of other aquatic life. A large cruise ship (3,000 passengers and crew) generates an estimated 55,000 to 110,000 liters per day of blackwater waste.[81]: 13 

Greywater is wastewater from the sinks, showers, galleys, laundry, and cleaning activities aboard a ship. It can contain a variety of pollutant substances, including fecal coliforms, detergents, oil and grease, metals, organic compounds, petroleum hydrocarbons, nutrients, food waste, medical and dental waste. Sampling done by EPA and the state of Alaska found that untreated greywater from cruise ships can contain pollutants at variable strengths and that it can contain levels of fecal coliform bacteria several times greater than is typically found in untreated domestic wastewater.[82] Greywater has potential to cause adverse environmental effects because of concentrations of nutrients and other oxygen-demanding materials, in particular. Greywater is typically the largest source of liquid waste generated by cruise ships (90 to 95 percent of the total). Estimates of greywater range from 110 to 320 liters per day per person, or 330,000 to 960,000 liters per day for a 3,000-person cruise ship.[81]: 15 

MARPOL annex IV was brought into force September 2003 strictly limiting untreated waste discharge. Modern cruise ships are most commonly installed with a membrane bioreactor type treatment plant for all blackwater and greywater, such as G&O, Zenon or Rochem bioreactors which produce near drinkable quality effluent to be re-used in the machinery spaces as technical water.

Solid waste

Solid waste generated on a ship includes glass, paper, cardboard, aluminium and steel cans, and plastics.[1] It can be either non-hazardous or hazardous in nature. Solid waste that enters the ocean may become marine debris, and can then pose a threat to marine organisms, humans, coastal communities, and industries that utilize marine waters. Cruise ships typically manage solid waste by a combination of source reduction, waste minimization, and recycling. However, as much as 75 percent of solid waste is incinerated on board, and the ash typically is discharged at sea, although some is landed ashore for disposal or recycling. Marine mammals, fish, sea turtles, and birds can be injured or killed from entanglement with plastics and other solid waste that may be released or disposed off of cruise ships. On average, each cruise ship passenger generates at least two pounds of non-hazardous solid waste per day.[83] With large cruise ships carrying several thousand passengers, the amount of waste generated in a day can be massive. For a large cruise ship, about 8 tons of solid waste are generated during a one-week cruise.[84] It has been estimated that 24% of the solid waste generated by vessels worldwide (by weight) comes from cruise ships.[85]: 38–39 : Table 2–3  Most cruise ship garbage is treated on board (incinerated, pulped, or ground up) for discharge overboard. When garbage must be off-loaded (for example, because glass and aluminium cannot be incinerated), cruise ships can put a strain on port reception facilities, which are rarely adequate to the task of serving a large passenger vessel.[85]: 126 

Bilge water

On a ship, oil often leaks from engine and machinery spaces or from engine maintenance activities and mixes with water in the bilge, the lowest part of the hull of the ship. Though bilge water is filtered and cleaned before being discharged,[1] oil in even minute concentrations can kill fish or have various sub-lethal chronic effects. Bilge water also may contain solid wastes and pollutants containing high levels of oxygen-demanding material, oil and other chemicals. A typically large cruise ship will generate an average of 8 tonnes of oily bilge water for each 24 hours of operation.[86] To maintain ship stability and eliminate potentially hazardous conditions from oil vapors in these areas, the bilge spaces need to be flushed and periodically pumped dry. However, before a bilge can be cleared out and the water discharged, the oil that has been accumulated needs to be extracted from the bilge water, after which the extracted oil can be reused, incinerated, and/or offloaded in port. If a separator, which is normally used to extract the oil, is faulty or is deliberately bypassed, untreated oily bilge water could be discharged directly into the ocean, where it can damage marine life.[citation needed]

Some shipping companies, including large cruise shipping lines, have sometimes violated regulations by illegally bypassing the onboard oily water separator and discharging untreated oily wastewater. In the US these violations by means of a so-called "magic pipe" have been prosecuted and resulted in large fines, but in other countries enforcement has been mixed.[87][88]

International regulation

Further information: MARPOL 73/78

Some of the major international efforts in the form of treaties are the Marine Pollution Treaty, Honolulu, which deals with regulating marine pollution from ships, and the UN Convention on Law of the Sea, which deals with marine species and pollution.[89] While plenty of local and international regulations have been introduced throughout maritime history, much of the current regulations are considered inadequate. "In general, the treaties tend to emphasize the technical features of safety and pollution control measures without going to the root causes of sub-standard shipping, the absence of incentives for compliance and the lack of enforceability of measures."[90]

The most common problems encountered with international shipping arise from paperwork errors and customs brokers not having the proper information about the items.[91] Cruise ships, for example, are exempt from regulation under the US discharge permit system (NPDES, under the Clean Water Act) that requires compliance with technology-based standards.[80] In the Caribbean, many ports lack proper waste disposal facilities, and many ships dump their waste at sea.[92]

Moreover, due to the complexities of shipping trade and the difficulties involved in regulating this business, a comprehensive and generally acceptable regulatory framework on corporate responsibility for reducing GHG emissions is unlikely to be achieved soon. In fact, emissions are continuing to increase. A 2016 journal article recommends that under such circumstances, it is necessary for the states, the shipping industry and global organizations to explore and discuss market based mechanisms for vessel-sourced GHG emissions reduction.[6]

Issues by region

Asia

European Union

United Kingdom

United States

It is expected that, (from 2004) "...shipping traffic to and from the United States is projected to double by 2020."[30] However, many shipping companies and port operators in North America (Canada and the United States) have adopted the Green Marine Environmental Program to limit operational impacts on the environment.[93]

See also

References

  1. ^ a b c d e f g h i j Walker TR, Adebambo O, Del Aguila Feijoo MC, Elhaimer E, Hossain T, Edwards SJ, Morrison CE, Romo J, Sharma N, Taylor S, Zomorodi S (2019). "Environmental Effects of Marine Transportation". World Seas: An Environmental Evaluation. pp. 505–530. doi:10.1016/B978-0-12-805052-1.00030-9. ISBN 978-0-12-805052-1. S2CID 135422637.
  2. ^ a b Schrooten L, De Vlieger I, Panis LI, Chiffi C, Pastori E (December 2009). "Emissions of maritime transport: a European reference system". The Science of the Total Environment. 408 (2): 318–23. Bibcode:2009ScTEn.408..318S. doi:10.1016/j.scitotenv.2009.07.037. PMID 19840885. S2CID 8271813.
  3. ^ Third IMO GHG Study 2014 (PDF) (Report). London: International Maritime Organization (IMO).
  4. ^ Second IMO GHG Study 2014 (PDF), IMO, archived from the original (PDF) on 19 October 2015
  5. ^ a b Shipping contributes up to 3 percent of worldwide CO2 emissions, says study, Voice of Russia UK. 27 June 2014.
  6. ^ a b Rahim MM, Islam MT, Kuruppu S (2016). "Regulating global shipping corporations' accountability for reducing greenhouse gas emissions in the seas". Marine Policy. 69: 159–170. doi:10.1016/j.marpol.2016.04.018.
  7. ^ High Seas, High Stakes, Final Report. Tyndall Centre for Climate Change Research, Univ. of Manchester, UK. 2014.
  8. ^ "Fuel charges in international aviation and shipping: How high; how; and why?". World Bank Blogs. World Bank. 17 April 2013.
  9. ^ "Fuel taxation". Archived from the original on 17 December 2018. Retrieved 17 December 2018.
  10. ^ Keen, Michael; Parry, Ian; Strand, Jon (9 September 2014). "The (non-) taxation of international aviation and maritime fuels: Anomalies and possibilities". VoxEU. London: Centre for Economic Policy Research.
  11. ^ Urbina, Ian (25 September 2019). "Dumping into the Ocean | #TheOutlawOcean". YouTube.
  12. ^ "Noise could sound the death knell of ocean fish". The Hindu. London. 15 August 2010.
  13. ^ Human Noise Pollution in Ocean Can Lead Fish Away from Good Habitats and Off to Their Death, University of Bristol, 13 August 2010, retrieved 6 March 2011
  14. ^ Simpson SD, Meekan MG, Larsen NJ, McCauley RD, Jeffs A (2010). "Behavioral plasticity in larval reef fish: Orientation is influenced by recent acoustic experiences". Behavioral Ecology. 21 (5): 1098–1105. doi:10.1093/beheco/arq117.
  15. ^ Noise Pollution and Ship-Strikes (PDF), UN Environment Programme-Convention on Migratory Species, archived from the original (PDF) on 22 July 2011, retrieved 6 March 2011
  16. ^ a b Vanderlaan AS, Taggart CT (2007). "Vessel Collisions with Whales: The Probability of Lethal Injury Based on Vessel Speed". Marine Mammal Science. 23: 144–56. doi:10.1111/j.1748-7692.2006.00098.x.
  17. ^ Womersley, Freya C.; et al. (2022). "Global collision-risk hotspots of marine traffic and the world's largest fish, the whale shark". Proceedings of the National Academy of Sciences of the United States of America. 119 (20): e2117440119. Bibcode:2022PNAS..11917440W. doi:10.1073/pnas.2117440119. hdl:10754/676739. PMC 9171791. PMID 35533277.
  18. ^ a b Taylor S, Walker TR (November 2017). "North Atlantic right whales in danger". Science. 358 (6364): 730–31. Bibcode:2017Sci...358..730T. doi:10.1126/science.aar2402. PMID 29123056. S2CID 38041766.
  19. ^ Ward-Geiger LI, Silber GK, Baumstark RD, Pulfer TL (2005). "Characterization of Ship Traffic in Right Whale Critical Habitat". Coastal Management. 33 (3): 263–78. CiteSeerX 10.1.1.170.1740. doi:10.1080/08920750590951965. S2CID 17297189.
  20. ^ Reilly SB, Bannister JL, Best PB, Brown M, Brownell Jr RL, Butterworth DS, Clapham PJ, Cooke J, Donovan GP, Urbán J, Zerbini AN (2010). "Eubalaena glacialis". IUCN Red List of Threatened Species. doi:10.2305/IUCN.UK.2012.RLTS.T41712A17084065.en.
  21. ^ "Shipping threat to endangered whale". BBC News. BBC. 28 August 2001.
  22. ^ "Endangered Fish and Wildlife; Final Rule To Implement Speed Restrictions to Reduce the Threat of Ship Collisions With North Atlantic Right Whales". Federal Register. 10 October 2008.
  23. ^ Gopikrishnan, G. S.; Kuttippurath, Jayanarayanan (30 November 2020). "A decade of satellite observations reveal significant increase in atmospheric formaldehyde from shipping in Indian Ocean". Atmospheric Environment. 246: 118095. doi:10.1016/j.atmosenv.2020.118095. ISSN 1352-2310. S2CID 229387891.
  24. ^ a b US Environmental Protection Agency (EPA), Washington, DC. "Control of Emissions From New Marine Compression-Ignition Engines at or Above 30 Liters Per Cylinder." Final rule. Federal Register, 68 FR 9751, 2003-02-28.
  25. ^ "New sulfur regulations from 2020". marine-electronics.eu. Retrieved 5 April 2018.
  26. ^ Saul, Jonathan (13 December 2019). "Factbox: IMO 2020 - a major shake-up for oil and shipping". Reuters. Retrieved 19 December 2019.
  27. ^ Fletcher, Philippa (12 December 2019). "Shipping industry sails into unknown with new pollution rules". Reuters. Retrieved 19 December 2019.
  28. ^ a b Vidal, John (9 April 2009). "Health risks of shipping pollution have been 'underestimated'". The Guardian. Retrieved 3 July 2009.
  29. ^ a b Harrabin, R. (25 June 2003). "EU faces ship clean-up call." BBC News. Retrieved 1 November 2006, from http://news.bbc.co.uk/2/hi/europe/3019686.stm
  30. ^ a b Watson, T. (30 August 2004). Ship pollution clouds USA's skies. USA Today. Retrieved 1 November 2006, from https://www.usatoday.com/news/nation/2004-08-30-ship-pollution_x.htm
  31. ^ Schmidt, C., & Olicker, J. (20 April 2004). World in the Balance: China Revs Up [Transcript]. PBS: NOVA. Retrieved 26 November 2006, from https://www.pbs.org/wgbh/nova/transcripts/3109_worldbal.html
  32. ^ Sargun, Sethi (22 March 2021). "A Guide To Scrubber Systems On Ships". Marine Insight. Retrieved 3 September 2022.
  33. ^ Liu J, Duru O (2020). "Bayesian probabilistic forecasting for ship emissions". Atmospheric Environment. 231: 117540. Bibcode:2020AtmEn.23117540L. doi:10.1016/j.atmosenv.2020.117540. S2CID 219027704.
  34. ^ Schrooten L, De Vlieger I, Int Panis L, Styns K, Torfs R (2008). "Inventory and forecasting of maritime emissions in the Belgian sea territory, an activity-based emission model". Atmospheric Environment. 42 (4): 667–676. Bibcode:2008AtmEn..42..667S. doi:10.1016/j.atmosenv.2007.09.071. S2CID 93958844.
  35. ^ "Infrastructure Podcast; Decarbonized Shipping". World Bank. 16 March 2022. Retrieved 18 August 2022.
  36. ^ Kersing, Arjen; Stone, Matt (25 January 2022). "Charting global shipping's path to zero carbon". McKinsey. Retrieved 18 August 2022.
  37. ^ Raucci, Carlo (6 June 2019). "Three pathways to shipping's decarbonization". Global Maritime Forum. Retrieved 18 August 2022.
  38. ^ "Working Group Oslo June 2008". IMO. 2008.
  39. ^ "IMO targets greenhouse gas emissions". IMO. 2020.
  40. ^ "The shipping industry attempts to cap carbon emissions". The Economist. Retrieved 10 May 2018.
  41. ^ Saul, Jonathan (18 December 2019). "Ship industry proposes $5 billion research fund to help cut emissions". Reuters. Retrieved 19 December 2019.
  42. ^ "Shipping industry should consider nuclear option for decarbonizing: experts". S&P Global. 4 November 2020. Retrieved 6 November 2020.
  43. ^ a b c Islam, Roumeen; Englert, Dominik (16 March 2022). "Infrastructure Podcast | Decarbonized Shipping". World Bank. Retrieved 18 August 2022.
  44. ^ "Decarbonization of the shipping industry". CIBC Capital Markets. 10 November 2021. Retrieved 18 August 2022.
  45. ^ Brown, Jennifer; Casarotto, Edoardo; Debatin, Maximilian; Ritsch, Nicola (1 July 2021). "Zero-carbon shipping: A sea of opportunities for developing countries". World Bank. Retrieved 18 August 2022.
  46. ^ "Carnival's AIDA Cruises Makes Biofuels Foray". Marine Propulsion. New York, NY: New Wave Media. 27 July 2022. Retrieved 18 August 2022.
  47. ^ a b Bourboulis, Stamatis; Krantz, Randall; Mouftier, Lara (11 April 2022). "3 actions the industry can take to decarbonize shipping". World Economic Forum. Retrieved 18 August 2022.
  48. ^ "Hydrotug: World's First Hydrogen-powered Tug Launched". MarineLink. 23 May 2022. Retrieved 18 August 2022.
  49. ^ "Hydrotug: World's First Hydrogen-powered Tug Launched". Marine Propulsion. 24 May 2022. Retrieved 18 August 2022.
  50. ^ Bourboulis, Stamatis; Krantz, Randall; Mouftier, Lara (9 May 2022). "Alternative fuels: Retrofitting ship engines". Global Maritime Forum. Retrieved 18 August 2022.
  51. ^ Premack, Rachel; Williams, Melissa (11 August 2022). "A Shell executive reveals how the energy giant wants to decarbonize the shipping industry". FreightWaves. Retrieved 18 August 2022.
  52. ^ Ajdin, Adis (21 October 2021). "Stena gets into the methanol retrofit business". Splash247. Retrieved 18 August 2022.
  53. ^ Haines, Chantal (22 October 2021). "Stena partners with methanol producer for wide-ranging retrofit solution". Marine Industry News. Retrieved 18 August 2022.
  54. ^ "Stena Partners with Proman to Develop Methanol Retrofit and Supply Solution". Marine Propulsion. 21 October 2021. Retrieved 18 August 2022.
  55. ^ "MAN, Stena and Proman Join on Methanol Retrofit Project". Clean Shipping International. 11 August 2022. Retrieved 18 August 2022.
  56. ^ Masterson, Victoria (26 July 2022). "From electric ferries to wind-powered boats: here's how the shipping industry can decarbonize". World Economic Forum. Retrieved 18 August 2022.
  57. ^ "'K' Line Orders Airseas Kites for Three More Ships". Marine Propulsion. 20 July 2022. Retrieved 18 August 2022.
  58. ^ "Electric Tug Sparky Chistened in Auckland". Marine Propulsion. 11 August 2022. Retrieved 18 August 2022.
  59. ^ "New Foss Hybrid Tug Steals the Show in LA". Professional Mariner. 9 September 2009. Retrieved 18 August 2022.
  60. ^ "Second Foss Hybrid Tug Headed to SOCAL". Marine Propulsion. 19 January 2012. Retrieved 18 August 2022.
  61. ^ "Svalbard Tour Boat Ushers New Technology—And a New Business Model". Marine Propulsion. 1 August 2022. Retrieved 18 August 2022.
  62. ^ "Danish Electric Ferry Completes World-record 90km Voyage on a Single Charge". Marine Propulsion. 17 August 2022. Retrieved 18 August 2022.
  63. ^ Reinsch, William Alan (13 April 2021). "Hydrogen: The Key to Decarbonizing the Global Shipping Industry?". Washington, D.C.: Center for Strategic and International Studies. Retrieved 18 August 2022.
  64. ^ Munoz, Tony (31 May 2021). "Decarbonizing Shipping: A Conversation with Bo Cerup-Simonsen, CEO, Mærsk Mc-Kinney Møller Center for Zero Carbon Shipping". The Maritime Executive. Retrieved 18 August 2022.
  65. ^ Baker, Marcus. "Deep Dive on Decarbonization of Maritime Industry". New York, NY: Marsh McLennan. Retrieved 18 August 2022.
  66. ^ Mallouppas, George; Yfantis, Elias Ar (2021). "Decarbonization in Shipping Industry: A Review of Research, Technology Development, and Innovation Proposals". Journal of Marine Science and Engineering. 9 (4): 415. doi:10.3390/jmse9040415. ISSN 2077-1312.
  67. ^ ""Fit" for Decarbonizing Maritime Shipping: Improvements Needed to Fuel EU Maritime Proposal to Meet coZEV Corporate Climate Ambitions". Washington, D.C.: The Aspen Institute. 21 March 2022. Retrieved 18 August 2022.
  68. ^ "New analysis: Ready, set, decarbonize!". Copenhagen, DK: Mærsk Mc-Kinney Møller Center for Zero Carbon Shipping. 30 June 2022. Retrieved 18 August 2022.
  69. ^ Josephs, Jonathan (21 April 2021). "Climate change: Shipping industry calls for new global carbon tax". BBC News. Retrieved 18 August 2022.
  70. ^ a b "Shipping Industry Needs More R&D to Meet Decarbonization Goals". Plantation, FL: The Maritime Executive. 3 November 2021.
  71. ^ "Shipping Decarbonization Weekly Insights". Breakwave Advisors. Retrieved 18 August 2022.
  72. ^ "IMO-Singapore Future of Shipping Conference: Decarbonisation 2022". IMO. Retrieved 18 August 2022.
  73. ^ "3rd Decarbonizing Shipping Forum". www.decarbonizingforum.com. Retrieved 18 August 2022.
  74. ^ "DNV Conference – The fuel of the future (January, 2022)". DNV, Det Norske Veritas. Retrieved 18 August 2022.
  75. ^ "Shipping industry announces international decarbonisation conference at COP26". www.ics-shipping.org. 21 July 2021. Retrieved 18 August 2022.
  76. ^ "Decarbonizing Shipping - Turning IMO and EU Regulation Into Action". www.bimco.org. Retrieved 18 August 2022.
  77. ^ "CMA Shipping Conference – Decarbonisation and Alternative Energy". Marsoft. 10 March 2022. Retrieved 18 August 2022.
  78. ^ "SHIPPINGInsight Conference: The Unsung Heroes of Shipping's Decarbonization". ISACOL S.A.S. Ship Agents in Colombia. 16 October 2021. Retrieved 18 August 2022.
  79. ^ "Decarbonizing Shipping (online training). Online blended learning training course that gives an overview of the realistic options that exist to meet the 2050 targets for CO2 reduction". DNV, Det Norske Veritas. Retrieved 18 August 2022.
  80. ^ a b c Panetta, L. E. (Chair) (2003). "America's living oceans: charting a course for sea change." Electronic Version, CD. Pew Oceans Commission.
  81. ^ a b The Ocean Conservancy, "Cruise Control, A Report on How Cruise Ships Affect the Marine Environment," May 2002. - PDF [1] Archived 29 October 2013 at the Wayback Machine
  82. ^ EPA Draft Discharge Assessment Report, pp. 3-5 - 3-6.[incomplete short citation]
  83. ^ The Center for Environmental Leadership in Business, "A Shifting Tide, Environmental Challenges and Cruise Industry Responses," p. 14.
  84. ^ Bluewater Network, "Cruising for Trouble: Stemming the Tide of Cruise Ship Pollution," March 2000, p. 5. A report prepared for an industry group estimated that a 3,000-person cruise ship generates 1.1 million US gallons (4,200 m3) of graywater during a seven-day cruise. Don K. Kim, "Cruise Ship Waste Dispersion Analysis Report on the Analysis of Graywater Discharge," presented to the International Council of Cruise Lines, 14 September 2000.
  85. ^ a b National Research Council (1995). Clean Ships, Clean Ports, Clean Oceans; Controlling Garbage and Plastic Wastes at Sea. Washington, D.C.: National Academies Press. doi:10.17226/4769. ISBN 978-0-309-17677-4.
  86. ^ "Shifting Tide," p. 16.
  87. ^ "The $40m 'magic pipe': Princess Cruises given record fine for dumping oil at sea". The Guardian. 2 December 2016.
  88. ^ Kantharia, Raunek (24 October 2019). "Magic Pipe: The Mystery of the Illegal Activity Still Continues on Ships". Marine Insight. Bangalore, India.
  89. ^ Steger, M. B. (2003). Globalization: A Very Short Introduction. Oxford University Press Inc. New York.
  90. ^ Khee-Jin Tan, A. (2006). Vessel-source marine pollution: the law and politics of international regulation. Cambridge: Cambridge University Press[page needed]
  91. ^ "4 Challenges in International Shipping". CLX Logistics Blog. Blue Bell, PA: CLX Logistics. 11 September 2015. Retrieved 5 April 2018.
  92. ^ United Nations Environment Programme in collaboration with GEF, the University of Kalmar, the Municipality of Kalmar, Sweden, and the Governments of Sweden, Finland and Norway. (2006). Challenges to international waters: regional assessments in a global perspective. Nairobi, Kenya: United Nations Environment Programme. Retrieved 5 January 2010.
  93. ^ Walker TR (April 2016). "Green Marine: An environmental program to establish sustainability in marine transportation". Marine Pollution Bulletin. 105 (1): 199–207. doi:10.1016/j.marpolbul.2016.02.029. PMID 26899158.

Further reading

External links

de:Umweltschutz in der Seeschifffahrt

Retrieved from "https://justapedia.org/index.php?title=Environmental_effects_of_shipping&oldid=1118213865"