Sunday, February 06, 2022

Op-Ed: Is a Fossil-Free Future for Shipping a Realistic Goal?

Without extreme caution, we may pull high-carbon fuels into the value chain in pursuit of the zero-emissions dream.


suiso frontier
The world's first hydrogen tanker loads its first cargo of coal-based H2 for the Japanese-Australian HESC project, January 2022 (HESC)
PUBLISHED FEB 4, 2022 4:15 PM BY PAUL BLOMERUS


LONG READ


 

Countries around the world are adopting greenhouse gas (GHG) emissions targets of zero emissions by 2050. The global marine shipping industry is also evaluating whether to increase the current International Maritime Organization agreed target of a 50 percent reduction by 2050 to a 100 percent reduction. Large international shipping companies such as Maersk, MSC and CMA CGM, have already committed to achieve carbon neutrality by 2050 or sooner.

Replacing the current fossil fuels used in ships – such as heavy fuel oil – with cleaner alternative fuels could provide solutions to the challenge of decarbonization and Clear Seas’ ongoing research on reducing GHGs from marine fuels provides some valuable insights.

Electrify the fuel

To find a path to zero-carbon marine shipping, the complete system from fuel production through to its consumption to propel the ship needs to be considered. Fortunately, years of innovation have made ships the most efficient form of transport worldwide, and allowed the development of the most fuel-efficient engines and propeller drives. Energy efficiency measures – such as using high tech sails – can help reduce the amount of fuel ships need, but the remaining energy needed to power ships has to come from somewhere. Could renewable electricity be used as a clean source of power?

Electrification holds great promise for reducing GHG emissions from a whole range of existing fossil fuel intensive processes in industry, home heating and vehicles. This is because renewable low-carbon electricity from wind and solar has fallen in cost to make it a plentiful and economically viable alternative.

But how do we get this cleaner electricity from the source to the ships? Batteries are a great option for short trips on vessels like ferries and pleasure boats, but for large-scale ocean transport they are too heavy and bulky to store the required energy. This is where alternative fuels come in. By converting electricity into fuels – so called e-fuels – there is a potential means to solve the problem of how to transport the electricity to the ships.

Hydrogen as a building block

The best way scientists and engineers have found to convert electricity into a fuel is through a process called electrolysis that splits water (H2O) into the hydrogen and oxygen it is made of by running electricity through it in an electrolyzer. Large amounts of electricity are required for this process – the entire daily average electricity consumed by a Canadian household would only make half a kilogram of hydrogen through electrolysis, with the equivalent energy content to drive a family car just 12 miles. But the result is hydrogen gas produced without any fossil fuels – referred to as “green” hydrogen.

Unfortunately, hydrogen alone is not a very good fuel for ships. Though hydrogen can be burned quite efficiently in the ship’s engine, refueling and storage onboard the ship presents a significant challenge. Hydrogen is a highly flammable, lighter than air gas and, even when pressurized into cylinders or liquified through a cooling process, it remains too bulky in the quantities required to replace regular marine fuel. Hydrogen storage tanks are also costly, heavy and energy intensive to fill.

Example of a hydrogen factory concept powered with renewable energy sources. The hydrogen plant to be built in Varennes, Quebec, will use hydroelectric power.

But all is not lost for alternative fuels. By combining the green hydrogen produced through electrolysis with other gases like nitrogen, carbon dioxide and oxygen, found in the atmosphere, simple compounds like ammonia, methanol and methane can be manufactured and more easily stored in ship fuel tanks in the quantities required. These chemical compounds can still be burned in existing ship engines if small modifications are made to their design and construction. But to make these synthetic alternative fuels out of hydrogen, sustainable sources of the other chemical elements are needed.

Ammonia fuel is a front runner but it’s toxic

Of the synthetic alternative fuels under consideration, manufacturing ammonia from green hydrogen is perhaps the easiest. The process is widely used today for fertilizer manufacturing and the only other element required for ammonia, chemical formula NH3, is nitrogen – and this is in plentiful supply in the air that surrounds us. The bad news is that separating the nitrogen from the air is an energy intensive process, as is the ammonia manufacture. Another challenge with ammonia is that if spilled, it can turn into a toxic vapour cloud that is deadly for humans and animals. So why is ammonia even considered? Its ease of manufacture on a vast industrial scale and our experience in safely transporting it in bulk on ships, trains and trucks for the fertilizer industry are good reasons to back ammonia in the alternative fuels race.

The ammonia molecule (formula NH3)

Burning ammonia in a ship engine has been proven to be possible, and although there are concerns regarding GHG emissions from the nitrous oxides produced in its exhaust as well as the smog-producing nitrogen oxides (NOx), these look like they can be managed. Ammonia gas can be turned into liquid for transportation and storage by chilling it to a relatively modest -27 degrees F.

Methane fuel draws on fossil fuel experience

Synthetic e-methane has an advantage over ammonia in that its fossil precursor has already been widely used as a ship fuel in the form of liquefied natural gas. This means that we already have processes, standards and regulations for the safe design and operation of ships using methane as a fuel. However, one major drawback of synthetic methane is that, like the prime component of fossil natural gas, it is itself a greenhouse gas. Though relatively short lived compared to carbon dioxide, its unintended release would need to be vigilantly prevented in a similar way to other synthetic GHGs like refrigerants.

The second disadvantage is one that it shares with methanol: manufacturing methane (chemical formula CH4) requires the addition of carbon represented by C in the formula. Although carbon in the form of carbon dioxide emissions from fossil fuel combustion surrounds us, capturing it and using this source of carbon does not produce zero GHG fuel because the carbon originates from a fossil source.

Instead, manufacturers of zero GHG methane need to either capture carbon dioxide (CO2) from the combustion of plant matter, for example at pulp mills or wood-fired power plants, or capture it directly from the atmosphere.

The supply of carbon dioxide from biological sources like wood that captured the carbon dioxide from the atmosphere through natural processes is limited, so long-term solutions for zero GHG marine fuels would need to rely on so-called direct air capture methods that chemically extract carbon dioxide from the atmosphere. It remains to be seen if the cost of carbon captured this way can be decreased low enough through scaling up of these processes to make synthetic fuels containing direct air captured carbon dioxide.

The methane molecule (formula CH4)

Methane’s main advantage over other synthetic fuels is that it can be used in existing LNG-fuelled ships without modification and can utilize the existing and growing infrastructure built for the transportation of fossil fuels. The same infrastructure and fuel tanks could potentially also be used to store ammonia, even though its storage temperature of -27 F is not nearly as low as the -260 F that is required for LNG. Ammonia has a higher density than liquefied methane, so this would also need to be factored in to designs of LNG fuel infrastructure.

Methanol fuel is a complex but easier to manage alternative

Methanol, while still toxic, would be easier to manage than both ammonia and methane because it is a liquid at room temperature. There is significant experience safely transporting it in bulk on ships for the global chemical trade and burning it in an engine seems to present few problems.

Methanex Corp., of Vancouver, B.C., operates the largest fleet of methanol tankers in the world, a growing proportion of which are now equipped with methanol burning engines. Unfortunately, the methanol burned in these engines is produced from fossil natural gas, and Clear Seas research has revealed that more GHG emissions come from this fossil methanol than from existing fossil fuels produced from oil.

But the fossil methanol production infrastructure also presents an opportunity. Usually, industrial methanol is produced using hydrogen made by splitting fossil natural gas in a steam methane reformer. The first step in producing zero GHG methanol is to substitute the hydrogen from fossil natural gas with green hydrogen produced from electrolysis. Unfortunately, like methane, methanol also requires a source of carbon because its chemical formula (CH3OH) contains a C for carbon. Like e-methane, direct air capture of atmospheric carbon dioxide would once again need to be deployed to manufacture e-methanol.

The methanol molecule (formula CH3OH)

The challenge of scaling up green hydrogen production from electrolysis

Ammonia, methane, and methanol rely on a plentiful supply of green hydrogen from electrolysis. This is the crucial and potentially weakest link in the chain. Plans are starting to be put into effect to develop a network of green hydrogen production facilities and Canada’s low-carbon electricity grid supplied through hydroelectric power makes it an attractive location. Varennes, Que., will be the site of one of the world’s largest green hydrogen facilities. Costing $200 million, the plant will consume 88 megawatts of electricity and produce 11,000 tonnes of hydrogen annually. But this only equates to enough energy to supply just over half the fuel needed for a single large container ship with pure hydrogen.

Clearly, it’s not economically viable or practical for each ship to have two $200 million fuel production facilities supplying it. Advances in electrolysis technology will be required to improve the output, but fundamental limitations created by the chemical energy required to split water molecules make this a challenge – a maximum of just 26 grams of hydrogen for every kilowatt hour of electricity consumed. So, if the Varennes plant could be made 100 percent efficient and ran 24 hours a day, its output would only increase to 20,000 tonnes of hydrogen per year, enough for one container ship. Making the synthetic ammonia, methanol or methane with the hydrogen does make it go a little further, but making enough green hydrogen to decarbonize the global marine shipping industry remains a significant challenge.

Could hydrogen from fossil natural gas bridge the gap?

Hydrogen for the petrochemical industry is usually produced by heating fossil natural gas in the presence of steam – so called steam methane reforming. Could this be used to substitute for the green hydrogen until electrolysis technology is improved? Clear Seas research indicates that hydrogen produced through this method emits more GHGs than conventional marine fuel produced from oil. It should not be considered as an alternative.

Carbon capture and sequestration is often proposed to fix this problem of excessive carbon dioxide emissions created when hydrogen is produced from natural gas. Canada is the site of one of the largest carbon capture and sequestration plants in the world. Shell Canada’s Quest facility near Edmonton, Alberta cost $1.35 billion and can capture and store just over 1 million tonnes of carbon dioxide per year in underground caverns. This may sound like a lot of carbon dioxide, but in reality, it equates to the annual carbon dioxide emissions of just five large container ships.

Although Shell plans to expand the capacity for carbon dioxide capture and sequestration to almost 10 times the Quest facility, these projects are primarily designed to deal with the emissions from Shell’s gas processing and oil refineries and could never cope with the emissions from large-scale hydrogen production for marine fuel. And even if capture and sequestration could be scaled up, there is uncertainty in the scientific community about the ability of the underground rock formations to sequester carbon dioxide without it leaking out over time.

Canadian renewable energy company Ekona Power Inc., of Burnaby, B.C., is piloting an alternative technology called pyrolysis that splits the methane in natural gas into hydrogen and carbon dust. This carbon dust could be more easily managed and disposed of than carbon dioxide gas, but the technology is still at a very early stage of development.

How about biofuels?

Biofuel versions of both methane and methanol can be produced from any organic material. Plants are where most organic material comes from, and they capture carbon dioxide from the atmosphere as they grow, so when they are turned into fuel to be burned it is considered carbon neutral.

Bio-methanol can be produced by heating wood chips until they produce a gas and then cleaning and purifying that gas to create the final product. Methanol is also produced in wood pulp mills as a by-product of the pulping process, but this is usually burned by the pulp mills to generate energy. In theory, these sources of bio-methanol could be directed to providing ship fuel. But global production of bio-methanol is currently extremely limited and is estimated at only 0.2 million tonnes per year by the International Renewable Energy Association. This would only be enough fuel for fewer than two large container ships.

Bio-methane is more common than bio-methanol, and the Canadian Biogas Association calculates that six petajoules of gas is currently produced at 280 sites across Canada alone. These include digesters of animal waste as well as gas captured from landfills and sewage treatment works. For context, six petajoules is only enough gas to fuel two or three large container ships.

These two examples illustrate the immense scale of the challenge to provide biofuels for use in the marine shipping industry. With increasing demand for net-zero emission fuels, competition for the organic raw materials for fuel production will only intensify. Dedicated sources of organic matter for fuels like genetically engineered algae have failed to deliver, and concerns about the local ecological and climate change impacts of land-use changes from new vegetation plantations make these options less and less viable. Though biofuels might play a role in the transition to zero GHG marine fuels, it will likely only be a limited one.

More work is needed to achieve zero greenhouse gas emissions from marine fuels

Considering the full energy system from fuel production through to energy use on the ship, ship technology is not necessarily the weak link in the chain. Solutions for fuel tanks and engines that can store and burn zero GHG emissions alternative fuels are ready now or have development programs well underway. Retrofitting the large 2-stroke engines predominately used in ocean-going ships to allow them to burn any combination of alternative fuels looks to be relatively easily accomplished, and ship designers are responding to the challenge of modularization of fuel storage to allow methane, ammonia or methanol tanks to be installed in existing ships.

The critical gaps seem to be upstream in the fuel production part of the value chain, and the large-scale production of green hydrogen from electrolysis. Current solutions will need significant advances to scale up to the volumes of production needed. If methane or methanol are to be used, then major advances in direct air capture of carbon dioxide will also be needed to provide the other raw materials for the fuel. Biofuels can help in the interim, but only a tiny amount and they don’t present a solution for the full-scale decarbonization of marine shipping.

It appears that extending our reliance on fossil fuels with carbon capture and sequestration of either carbon dioxide or solid carbon may need to be considered as a least bad interim option, but extreme caution is needed to guard against unintentionally bringing higher carbon intensity fuels into the value chain in the pursuit of the zero GHG emissions marine fuel dream that may never be truly realized.

Although synthesized alternative fuels provide a potential pathway to zero GHG marine shipping by 2050, it is still a narrow and treacherous one, and there is certainly scope for innovation and more radical solutions to help open the way to a truly fossil fuel free future.

Paul Blomerus is the Executive Director of Clear Seas and an internationally-experienced researcher and leader in innovation with a proven track record in industry and university research management. He holds a Ph. D. in Engineering Science from the University of Oxford, England, and a Mechanical Engineering degree with first-class honors from the University of Cape Town, in South Africa.

This article appears courtesy of Clear Seas and may be found in its original form here.

The opinions expressed herein are the author's and not necessarily those of The Maritime Executive.

Two Research Teams Face Off Over the Wreck of HMB Endeavour

endeavour
Reproduced plans for Endeavour (Australian National Maritime Museum)

PUBLISHED FEB 3, 2022 9:23 PM BY THE MARITIME EXECUTIVE

 

The head of the Australian National Maritime Museum announced Wednesday that he believes his team has identified the wreck of the famed sailing vessel HM Bark Endeavour, which carried Capt. James Cook and his crew on their voyage of exploration to Australia and New Zealand. However, the museum's American partners have pushed back, calling the announcement "premature."

The Australian team has not found the ship's bell, or any other object that would conclusively link site number RI-2394 to Endeavour - but "the preponderance of evidence" suggests that this particular wreck is indeed the long-sought historic ship, said Kieran Hosty, a marine archaeologist with the museum. "We've found lots of things that tick the box for it to be Endeavour, and nothing on the site that says it's not," he said. 

In particular, the dimensions of the ship's scantlings are nearly identical to the dimensions on historical shipyard plans, including unique joinery elements at the vessel's stem, Hosty said. 

After Cook's voyages ended, Endeavour was sold and renamed Lord Sandwich, and historians believe that she saw service as a British prison ship during the American Revolutionary War. In 1778, she was present for the siege of Newport, Rhode Island, and the Royal Navy intentionally scuttled her and four other ships in order to prevent vessels from sailing into the harbor. This might explain why so few objects have been found at the wreck site, the museum's archaeologists believe. 

"Anything that was of value would have been stripped out of that ship before it was sunk," said Dr, James Hunter, an archaeologist with the museum. "What has been recovered up to this point is indicative of an 18th-century timeframe."

Based on this evidence, Kevin Sumption, Director and CEO of the Australian National Maritime Museum (ANMM), decided to announce Wednesday that the Endeavour has been found. The decision did not sit well with the Rhode Island Marine Archaeology Project (RIMAP), the lead institution for the wreck site. 

"The ANMM announcement today is a breach of the contract between RIMAP and the ANMM for the conduct of this research and how its results are to be shared with the public," said Dr. Kathy Abbass, the head of the American team. "What we see on the shipwreck site under study is consistent with what might be expected of the Endeavour, but there has been no indisputable data found to prove the site is that iconic vessel."

The ANMM dismissed Abbass' criticism. "She can have her opinion and we've got ours," the spokesperson told the Daily Mail. "We don't believe we are in breach of contract."

ANMM's team plans to put out a paper on their research for peer review soon, "and so further insights will be made as happens with all archaeological projects," the spokesperson said. 

Argentina Deploys New Patrol Ships to Ward Off China's Squid Fleet

iuu fishing argentine navy
Boarding teams from ARA Bouchard (P-51) and ARA Piedrabuena (P-52) inspect fishing vessels in the Argentine Sea (Photo credit: Argentine Navy)

PUBLISHED FEB 6, 2022 2:28 PM BY CIMSEC

 

[By Wilder Alejandro Sanchez]

The Argentine Navy has deployed its two newest offshore patrol vessels (OPVs), ARA Bouchard (P-51) and ARA Piedrabuena (P-52), to monitor an international fishing fleet traveling close to the country’s exclusive economic zone (EEZ) en route to the South Atlantic. While there have been no confirmed reports of these vessels engaging in illegal, unregulated, or unreported (IUU) fishing, recent history suggests that this is occurring or will occur soon.

Putting the new units to good use

Bouchard and Piedrabuena are assigned to the Argentine Navy’s maritime patrol division (División de Patrullado Marítimo: DVPM). Along with a Beechcraft B-200 Super King Air aircraft assigned to the naval air squadron for maritime surveillance (Escuadrilla Aeronaval de Vigilancia Marítima), the two units monitored vessels traveling through the Magellan Strait en route to open seas in the South Atlantic, according to a 23 December press release. After departing from Admiral Zar base in Trelew, Chubut Province, the B-200 flew over “the fishing fleet, in coordination with the patrol boats, maintaining surveillance… of the activities carried out by these ships of different nationalities.”

The support vessel ARA Estrecho de San Carlos (A-22) has reportedly replaced Bouchard as the main vessel assigned to Ushuaia, the capital of Tierra del Fuego province, which is near the Beagle Channel and Argentina’s border with Chile.

Argentina has acquired four Gowind-class OPVs from France, manufactured by Naval Group. The third unit, ARA Storni (P-53), was delivered in October 2021, while the fourth and final ship, ARA Bartolomé Cordero, was launched in September 2021 and will likely be delivered sometime in early 2022. The four units will help the Argentine Navy improve its patrol and surveillance operations.

There have also been developments from a bureaucratic standpoint. In late February 2021, the Ministry of Defence created the Joint Maritime Command (Comando Conjunto Marítimo: CCM) to “patrol and control of [Argentina’s] maritime and fluvial areas.” The MoD announced that starting this past 1 January, the CCM assumed command of surveillance maritime operations, which includes monitoring the international fishing fleet that is sailing near the country’s EEZ.

Good and Bad News

The Argentine Navy will have additional air and surface units in the near future. In late December, the Argentine government announced that the local shipyard Tandanor will construct a new icebreaker for Antarctic operations to replace the aging icebreaker Almirante Irízar (Q-5). In the same month, the Ministry of Defence announced that two refurbished Sikorsky SH-3H Sea King medium helicopters will be acquired to improve capabilities and operations, including search and rescue, in the country’s southern areas and during Antarctic operations. The price of the two helicopters, including personnel training and spare parts, is $12.8 million.

Alas, the service still has no operational submarines. Moreover, apart from the four new OPVs, the rest of the fleet has yet to be modernized, which limits the service’s capabilities for constant, long-range patrol operations to monitor illegal activities by the international fishing fleet.

IUU Fishing

Argentina has a history of combating IUU fishing. For example, in 2016, the Mantilla-class patrol boat Prefecto Derbes (GC-28) shot and sank the Chinese fishing vessel Lu Yan Yuan Yu 010. The ship had reportedly ignored warning shots and attempted to flee, only to ram the Argentine patrol vessel. Lu Yan Yuan Yu was reportedly fishing without authorization in Argentina’s EEZ close to Chubut Province.

The author of this article has written several essays for CIMSEC about IUU fishing in Latin American waters (See 2016’s “Latin American Navies Combat Illegal Fishing,” and 2020’s “The Ecuadorian Navy’s Constant Struggle Against IUU Fishing.” Regional cooperation is vital to solving this security challenge, which can be achieved by modernizing the Inter-American Treaty of Reciprocal Assistance (Tratado Interamericano de Asistencia Recíproca: TIAR) into a 21st-century agreement that is also tasked with combating IUU fishing.

Turning TIAR into TIAR 21, as the author suggested in a July 2021 Regional Insight paper for the William J. Perry Center for hemispheric Defense Studies at the US National Defense University, would be an essential step forward to more effectively monitor South America’s vast waters and prevent the ongoing maritime pillaging of precious marine resources by extra-regional fishing fleets.

An international fishing fleet, comprising vessels from countries such as China, Spain, South Korea, and Taiwan, continuously operates throughout South America, moving with the season. For example, the same fleet operated around Ecuador, close to the Galapagos Islands, in July-August 2021, then traveled south through Peru and Ecuador. It is currently crossing the Magellan Strait to operate in the South Atlantic for the summer months below the Equator. In Argentina, fishing vessels are focused on fishing squid, spider crab (centolla), and crab.

According to a December report by the Argentine daily La Nación, the “fishing season” commenced in early December, as some 180 vessels, “mostly from China,” crossed the Magellan Strait after operating in waters close to Chile and Peru. “By April, there will be approximately 500 ships operating in the area,” explained Major Néstor Alberto Kiferling, head of Argentina’s maritime traffic service. As modern as the Gowind class ships are, the international fishing fleet vastly outnumbers the Argentine Navy’s current capabilities, even with support from aerial units and other vessels.

Conclusion

It has been argued that Argentina is in a better situation vis-à-vis IUU fishing today compared to five years ago. Indeed, the Argentine Navy is putting its two new OPVs to good use by deploying them to the Magellan Strait to monitor the international fishing fleet crossing through the country’s EEZs en route to the South Atlantic. As with many other South American countries, one of Argentina’s major environmental challenges is IUU fishing, But while IUU Fishing is problematic when perpetrated at low-scale by fishing vessels from Argentina or a neighboring country, it can become truly catastrophic when done so by hundreds of international fishing vessels with no interest in preserving the maritime environment.

Wilder Alejandro Sánchez is an analyst who focuses on international security and geopolitics. The views expressed in this article belong the author alone and do not necessarily reflect those of any institutions with which the author is associated.

This article appears courtesy of CIMSEC and may be found in its original form here.

 

Alang Ship Recyclers Make Renewed Push for Green Standards

bansal
Image courtesy Bansal Shipbreakers

PUBLISHED FEB 6, 2022 8:23 PM BY ARJUN BANERJEE

 

Alang is seeing a renewed push to develop ship recycling standards above the requirements of regulators and classification societies.This development stems from shipowners' own requirements for recycling of their vessels.

These shipowners require ClassNK HKC certification as the basic standard and are looking to audit or pre-evaluate existing ship recycling yards. Some owners list out their own responsible ship recycling standards, and they are looking for yards that have gone beyond the requirements of the classification society and perform LTI-free operations.
 
Some of the standards required for the ship recycling facility beyond regulatory requirements include:

1.       Complete impermeable floor 
2.       Stormwater collection system for complete containment of any seepage to the sea
3.       Large heavy-lift cranes for better control over the dismantling of large units
4.       Environmentally sound downstream waste management and auditing of subcontractors. 

All the above require financial investments for ship recyclers to implement. One recycling yard that is making this investment is Bansal Shipbreakers at Plot No. 25 and 39. 

"As of today, the text adopted in the Hong Kong Convention is interpreted in different ways by different shipowners.  For example, some may interpret the impermeable floor as the cutting zone concreted, and others may say that the entire facility is to be made impermeable by the use of concretization," says Mr. Rubal Bansal, the company's director. "It is in our best interest to go for the higher benchmark of green recycling even when it may require substantial financial investments in terms of construction of the facility or procurement of equipment (large heavy lift cranes). We always go for the higher regulation/requirement."

ClassNK issued Bansal a certificate of HKC compliance in 2018, and now they are on their way to getting certification from Lloyd's Register for compliance with the HKC and the standards of the EU SRR. The Bansal yard has also been audited by leading shipowners as part of their pre-evaluation for the recycling of vessels. 

Alang’s push for green ship recycling has been relatively subdued since the Basel Ban Amendment took effect in 2019, but the effort is now being renewed. The impetus comes directly from the shipowners themselves, and it is set to translat into safe and environmentally sound ship recycling.

Arjun Banerjee is an environmental compliance consultant and hazmat manager, and he has worked with cash buyers and ship recyclers for the past seven years. He holds a post-graduate degree in environment and sustainable development, a degree in civil engineering, and is a lead auditor for ISO 9001, 14001 and 45001 certified by Lloyds Register. 

ICYMI

Photos of Spilled Catch Shock European Fisheries Regulators

dead whiting
Courtesy Sea Shepherd France

PUBLISHED FEB 6, 2022 9:57 PM BY THE MARITIME EXECUTIVE

 

The environmental group Sea Shepherd has obtained aerial footage of a large-scale release of dead fish off the coast of France, drawing scrutiny from the public and from regulators.

The Sea Shepherd patrol vessel Age of Union is operating in the Bay of Biscay off La Rochelle, monitoring four factory trawlers to collect evidence of dolphin bycatch. On her most recent patrol, the vessel observed a release of thousands of blue whiting into the ocean. This catch came from the Margiris, the second largest trawler in the world. 

Sea Shepherd asserted that the fish were illegally dumped over the side, but the Pelagic Freezer-Trawler Association (PFA) - which represents Margulis' operator - told media that the release was an accidental "fishing incident" involving a ruptured net. 

"We would like to clarify that around 0550 on 3 February 2022, an amount of blue whiting was involuntarily released into the sea from the Margiris vessel, due to a rupture in the cod-end part of its net. Such an accident is a rare occurrence and in this case was caused by the unexpectedly large size of the fish caught," said the PFA in a statement to media. 

 

Regulators from France and the EU are asking for more information. 

"At the sight of the images shared by [Sea Shepherd France], I asked the National Fisheries Monitoring Center to shed light on this subject in order to identify the cause of these discards of fish. Of course, these images are shocking," said French Minister of the Sea Annick Girardin. "France supports sustainable fishing and this isn't reflected here. Should an infraction have occurred, sanctions would be taken against the responsible shipowner that will be identified."

Virginijus Sinkevi?ius, EU commissioner for the environment, oceans and fisheries, said in a statement that his office is collecting "exhaustive information and evidence" about the release. 

On February 6, Margiris departed the fishing grounds and headed towards Falmouth, England, outside of the European Union. There she rendezvoused with another trawler operated by the same firm, the Alina, then departed again, according to Sea Shepherd. 

Dutch Detain Captain and Mate for Abandoning Drifting Bulker

Dutch detain captain after abandoning drifting bulker in storm
Julietta D being towed to Rotterdam ( FlyingFocus photo courtesy of Coastguard of the Netherlands)

PUBLISHED FEB 1, 2022 9:09 PM BY THE MARITIME EXECUTIVE

 

In a strange twist to yesterday’s dramatic sea rescue of the crew from a drifting bulker during a raging storm, Dutch authorities are now detaining the captain and chief mate from the Julietta D. The vessel was secured by a salvage crew from Boskalis and brought to port, but the investigation is questioning the actions of the captain for leaving the vessel.

The Coastguard of the Netherlands reports that it responded to a call received from the 37,200 dwt bulker requesting assistance and a spokesperson told the Dutch news outlet NOS that the Coastguard in those situations does not question the captain’s judgment that there is an emergency. The Maltese-flagged bulker reported that its anchor chain had parted causing the vessel to hit an anchored chemical tanker creating a small hole in the hull. They were told that the ship was drifting out of control in the storm where winds were gusting up to 75 mph and the seas were running 16 to 20 feet.

Two Dutch helicopters along with lifeboats of the Royal Dutch Rescue Society (KNRM) were dispatched into the storm during. They also requested assistance from the Belgian Coast Guard, and they were able to locate the bulker between 15 and 20 miles off the coast. An airlift took place removing the 18 crew members including the captain and chief mate from the vessel.

Dutch media reports that last night the police detained the captain and chief mate as part of an investigation. They are reporting that the authorities are saying that the captain and mate should have remained aboard the vessel for as long as possible and only left if there was imminent danger. They are being investigated for prematurely abandoning the vessel that could then have gone aground on the Dutch coast.

The investigation will also look at the damage caused by the bulker when it hit the foundation for a transformer in the under construction Hollande Kust Zud wind farm. Tennet that is building the platforms for the Vattenfall project reports that there was no one on the transformer that was hit. Once the storm subsides, they are planning to inspect the site to see if there was any damage due to the impact.

The Julietta D remained afloat and adrift causing an offshore oil platform also to be abandoned before a joint salvage operation between Boskalis and Multraship got underway that same afternoon. The Sovereign, a large Boskalis tug, arrived on the scene about four hours after the ship was abandoned. Four salvors from Boskalis’ salvage division, SMIT Salvage, were airlifted onto the Julietta D by helicopter and were able to secure a towline to prevent the vessel from going aground. The Julietta D was pulled further out to sea as a precaution.

A second tug, the seagoing Multratug 18 operated by Multraship also arrived and secured a line, but due to the extreme wave height, the connection did not hold. Dutch media are saying the Coastguard reported that one person on the tug and a second on one of the KNRM’s lifeboats both received minor injuries during the attempt to secure the second line. The Multratug 18 remained on stand-by overnight to assist. A second large Boskalis tug, the Manta, loaded with salvage equipment and additional personnel, was also sent to the bulker and at sunrise today the Multratug 18 was able to attach a stern line to provide course guidance during the tow. The tugs were then able to bring the Julietta D to Rotterdam as the wind reduced and the waves were lower.

The tanker Pechora Star that was hit by the Julietta D remained at anchor and moored in the port of Amsterdam on Tuesday morning under its own power.

The German shipping company that owns the Julietta D thanked everyone involved for their efforts and promised to cooperate fully with the investigation.

 

Multraship tug connected to the Julietta D providing course guidance during the tow (Multraship/Flying Focus photo)

 

One of Maersk’s Largest Boxships Grounds off Germany

Mumbai Mersk aground off Germany
Mumbai Maersk went aground near the mouth of the Weser approaching Bremerhaven (Havariekommando)

PUBLISHED FEB 3, 2022 12:24 PM BY THE MARITIME EXECUTIVE

 

One of the largest containerships in Maersk’s fleet went aground last night, February 2, as it was approaching the German port of Bremerhaven. There are no signs of a hull breach or pollution, but a first attempt to refloat the ultra-large boxship was unsuccessful and additional resources are being assembled while the vessel's ballast tanks were also emptied before a second attempt to pull the vessel back into the shipping channel near the mouth of the Weser.

Maersk confirmed reports from Germany’s Central Command for Maritime Emergencies (Havariekommando) advising customers that the 210,000 dwt Mumbai Maersk was inbound to Germany with containers shipped in Asia heading for Germany and the Scandinavian countries. With a capacity of approximately 20,000 TEU, the Mumbai Maersk is part of the line’s Triple E class introduced in 2018 and one of the largest vessels in the fleet. The vessel had previously unloaded at Rotterdam before proceeding to Germany, so it is unclear how many containers are currently aboard.

The German authorities reported at just after 11 p.m. local time approaching the mouth of Weser the vessel ran aground on a shallow patch. The 1,309 foot Mumbai Maersk reported no injuries in the grounding but remained stuck. The vessel has a normal average draft of approximately 46.5 feet, but pictures released by CCME show it to be higher in the water. Reports in the local media suggest that vessel currently has a draft under 43 feet and that it may have experienced a problem with its rudder while in the fairway approaching the port. The media is reporting that the vessel made a loop taking her south of the fairway into an area used for dredged material from the shipping lane.

A total of seven vessels were sent to provide assistance, including a towing assistance team, which CCME says typically consists of four people trained to manage situations such as this grounding. A first attempt by the tugs overnight to free the containership was unsuccessful.

 

Mumbai Maersk remains on a shallow patch off Bremerhaven, Germany (Havariekommando)

 

The Mumbai Maersk’s current position is reported not to be obstructing the entrance to the Weser as the route to Bremerhaven. Port traffic is reported to be operating normally.

CCME said that Maersk retained a salvage company and that they were working with the shipping line planning additional efforts to refloat the containership. The authorities ordered a sounding of the site to get up-to-date information on the water depths in the area. The current plan calls for additional tugs to be added to the effort and a new attempt to refloat the vessel on the coming high tide around midnight on February 3. CCME reports a higher than normal tide is expected tonight with the next higher than normal tide expected Saturday night.

Maersk is advising customers with outbound cargos to be loaded in Bremerhaven that it will determine actions if the next refloating attempt does not prove to be successful. “We will look into alternative means of transport to move this cargo to its intended destinations,” Maersk wrote in its customer advisory.

The Mumbai Maersk was introduced in 2018 and claimed a new record for Maersk, loading what at the time they said was the largest number of containers. In August 2018, the containership departed Asia with a capacity load of 19,038 TEU bound for Europe.

 

Facing Scrutiny on CO2, Rotterdam Starts Tracking Vessel Emissions

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Rotterdam handles about 100m tonnes of oil per year for refineries in the port and nearby. Its tracking program covers 14m tonnes per year of shipping emissions (Rik Schuiling / CC BY SA 3.0)

PUBLISHED FEB 4, 2022 8:36 PM BY THE MARITIME EXECUTIVE

 

Responding to scrutiny from an environmental watchdog over its carbon emissions, Europe’s largest and busiest port says that it intends to make its impact more transparent.

On the day that NGO Transport & Environment (T&E) revealed that the port of Rotterdam was associated with almost 14 million tonnes of CO2 emissions annually, making it the most carbon-emitting port in Europe, the Port of Rotterdam Authority said it has partnered with the consultancy BigMile to develop a digital platform to identify and track transport-related emissions within its waters.

Over the next six months, the authority and BigMile will undertake a pilot project to calculate seagoing and inland vessel movements within the port with the aim of better understanding its emissions levels.

The port intends to use AIS data to precisely calculate transport sector emissions. The emission platform will help the port and business community make better choices and implement strategies to make the facility a carbon-neutral port. Findings from the project will be shared with shipping companies and terminals in the second half of the year.

“With millions of transport movements, we are the largest port in Europe. This means that our activities can have a huge impact on making logistics more sustainable,” said Nico van Dooren, who is responsible for the Port of Rotterdam Authority’s energy transition program.

He added the port is working on a series of related projects to make the industry and logistics more sustainable, from determining optimal connections via the most sustainable modality to the production of alternative fuels and promoting fast and efficient port call handling.

As Europe’s largest and busiest port, Rotterdam has been handling an average of 14.5 million TEU throughput annually. It is an absolute leader in crude oil handling and storage in Northwest Europe, moving 100 million tonnes of oil every year, almost entirely for refineries within the port and the nearby region. 

A new study by T&E shows that transport emissions at Rotterdam are also somewhat significant at 13.7 million metric tonnes - nearly twice its largest competitor, Antwerp.

With the digital platform, Rotterdam said it is taking a step towards using sound data to manage its emissions reduction strategy. BigMile has developed a calculation and analysis platform to help shippers and logistics service providers optimize and report on the multi-modal transport-related carbon emissions of their transport. Its platform, which already has over 200 users, helps logistics firms comply with carbon reporting requirements and regulations. 

“In the first project phase, we are focusing on area emissions in the port of Rotterdam area, from 60 kilometres offshore to the Brienenoordbrug. We are literally ‘charting’ sea-going and inland shipping’s actual emissions based on vessel and vehicle movements,” explained Wouter Nering Bögel, BigMile project manager.

ICS Finds Drop-Off in Flag States' Labor Standards Reporting

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File image courtesy Clear Seas

PUBLISHED FEB 3, 2022 11:39 PM BY THE MARITIME EXECUTIVE

 

The International Chamber of Shipping has issued its annual report card on flag state performance, and while the signs are positive in general, there is one category where some states are underperforming: their labor standards reporting. ICS' analysis of flag states’ reporting on ILO labor standards, including the Maritime Labor Convention, showed a six percentage point drop in flag states meeting their obligations. 

“The pandemic has been a challenge for us all and one that Flag States have also had to weather. However, the drop off in reporting against ILO Labour Standards, including the MLC, is further evidence that seafarer wellbeing has been an unintended casualty of the pandemic," said ICS Secretary General Guy Platten. “Hundreds of thousands of seafarers have been trapped on ships for many months beyond their scheduled tours of duty throughout the last two years. This report is a reminder that flag states must keep seafarer wellbeing as a top priority.”

The dropoff reflects a trend of reporting challenges for governments generally, not just flag state administrations. Out of the 2,004 reports on labor standards requested by the International Labor Organization from governments in 2021, only 43 percent of these requests were granted. This is a sharp drop compared with the 71 percent reporting rate in 2020, during the height of the pandemic. "This has been a challenging year for many governments resulting in a limited capacity to report," the ILO noted. 

According to ICS, this shows both the unusual administrative pressures of the pandemic and the impact of the crew change crisis on seafarers, governments and the industry. 

However, according to ICS, this one shortcoming was an outlier, and most flags showed a generally strong performance on port state control inspections and ratification of international conventions. This includes positive developments at the biggest flags. 

"Amongst the 10 largest ships registers (by dead weight tonnage), covering more than 75 percent of the world fleet, none have more than two indicators of potentially negative performance, and five have no negative indicators at all," ICS reported. "The findings also suggest that distinctions between ‘traditional’ flags and open registers are no longer meaningful, with many open registers amongst the very top performers."