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Set to usher in a new era for net-zero oceanography and advanced international marine research, Plymouth Marine Laboratory (PML) has revealed designs for the world’s first long-range autonomous research vessel.

Supported by funding from the Natural Environment Research Council, the uncrewed Oceanus has been designed as a self-righting, lightweight, monohulled autonomous vessel capable of carrying an array of monitoring sensors to collect data for research into areas such as climate change, biodiversity, fisheries, and biogeochemistry.

“This is a hugely exciting venture,” said Icarus Allen, the chief executive of PML, “with the capacity to revolutionize the way we carry out marine research expeditions and support the drive towards net zero.”

Designed primarily to make the trans-Atlantic sampling voyage from the UK to the Falklands, the Oceanus will carry an advanced scientific payload and use artificial intelligence (AI) technology to help navigate the best course to its target location, with real-time input from weather forecasts and other marine data feeds.

“The Oceanus will exploit the very latest in AI technology, enabling us to push the frontiers of marine science and open up new opportunities in how we monitor the ocean environment,” Allen said. “Not that long ago, this would have been the stuff of science-fiction fantasy, but through the design and development of the Oceanus, we are really unlocking the future of ocean-going marine research.”

Currently, most oceanographic sampling is performed either through fully manned research trips or with moored data buoys and smaller autonomous devices. Although still important for validation purposes and more-complex tasks, research trips are costly and logistically challenging and have a significant environmental footprint while smaller autonomous devices are restricted in their range.

PML said the Oceanus represents a vision of how long-range marine research can be conducted in a more environmentally benign way. While a fuel-efficient diesel engine still will be used, it will be complemented by on-board micro-energy generation devices and solar panels on the deck. The removal of people and living facilities also will reduce weight and, thus, fuel consumption compared with traditional manned research vessels.

The command center for Oceanus will be hosted at PML and will display oceanographic conditions in near-real time across the ship’s transect, providing scientists and other users with open access to the latest oceanographic data.

In-situ sampling still will be needed at times to validate the autonomously collected data and to perform more-complex monitoring and experiments that require proximity to the sample sources. Autonomy on this scale, however, will allow for radically more-responsive and more-frequent data collections at a wider range than currently possible, helping to plug any gaps in data sets and improve marine modeling.

The idea for the vessel was borne in the wake of the Mayflower autonomous ship, also developed and built in Plymouth, UK, by M Subs and partners including IBM. The vessel’s name, Oceanus, was the name of the first child born on the original Mayflower in 1620.

The Oceanus is expected to be a platform for innovation, and the team said it hopes the vessel eventually will enable a remote Atlantic Meridional Transect (AMT), an annual marine research expedition along the length of the Atlantic Ocean that embarked on its first voyage in 1995. An autonomous AMT could lead to multiple data-collection missions a year to give a much better understanding of the dynamics of the ocean environment.

“The voyages of exploration the RV Oceanus will undertake are matched in intensity by the parallel technological voyage to bring into being a new era in climate science—at lower fiscal and ecological cost,” said Brett A. Phaneuf, the managing director of M Subs.

Source: PML


IMO’s MEPC has reiterated its commitment to review and strengthen the IMO Initial Strategy on the reduction of GHG emissions from shipping, with a view to adopting a revised strategy in mid-2023.

However, the agreement to establish the International Maritime Research Board (IMRB) and the proposed $5 billion International Maritime Research Fund (IMRF) was not achieved at MEPC 78.

The adoption of the industry-financed and IMO-led R&D fund has been seen as a key step to accelerating the development of technologies for zero-carbon shipping.

Under the proposal made in 2019, the core funding would be collected over a ten-year period via a mandatory $2 R&D contribution per tonne of fuel oil purchased for consumption. The fund would be supervised by the IMO.

Following the conclusion of last week’s meeting, the International Chamber of Shipping (ICS), representing 80% of the world’s merchant fleet, issued a statement.

By refusing to take forward the shipping industry’s proposed research and development fund, the IMO has wasted its opportunity to kick start a rapid transition to zero-carbon technologies which will be vital if we are to decarbonise completely by 2050,” Guy Platten, ICS Secretary General, commented.

“Despite the support of many IMO States, we have been frustrated by short-sighted political manoeuvring which has led to the proposal in effect being killed. The signal this sends means that the financial risk associated with green investment will remain high, slowing down efforts to switch to zero-carbon fuels as soon as possible.”

“Some claimed that the fund was a market-based measure and did not go far enough, deliberately misinterpreting our intention. The fund was never presented as a carbon pricing measure, which, although being an additional measure which we also fully support, is politically far more complex and will take many more years to develop. If governments had shown the political will, the separate R&D fund could have been up and running next year, raising billions of dollars from industry at no cost to governments,” Platten added.

“Despite the lack of government leadership at the IMO, the shipping industry remains committed to finding ways of achieving net zero carbon emissions by 2050.”

“In addition to providing half a billion dollars per year to support global R&D programmes, the fund would have provided $50 million per year to support maritime greenhouse gas reduction projects in developing countries – a ten-fold increase to the current IMO technical cooperation budget. Sadly, it seems this opportunity to provide immediate help to the likes of Small Island Developing States has also now been lost,” Simon Bennett, Deputy Secretary General of ICS, added:

“On the positive side, the possibility remains for the IMO to make use of the fund’s proposed regulatory architecture to underpin a future global carbon levy on shipping’s CO2 emissions, to close the price gap with zero-carbon fuels when they become available and provide significant funds to help expedite the transition to net zero by 2050.”

“If the contribution system which we have developed can speed up implementation of a global carbon levy for shipping, we may yet be able to look back on this setback at the IMO as a significant moment of success.”


IMO will be hosting a seminar to share insights on regulatory barriers and uncertainties encountered by national Administrations and industry for Maritime Autonomous Surface Ships (MASS) projects currently undertaken or planned for the future. It will explore how such obstacles can be overcome by establishing an international legal framework to regulate the operation of MASS.

The Seminar will be held online from Monday, 5 September 2022 to Tuesday, 6 September 2022, from 11.00 a.m. to 2 p.m. (UTC+1). The event is open to all interested parties and will be conducted in English without interpretation.

Attendees at the MASS seminar can expect to hear from IMO Member States, international organizations and academic institutions. Topics to be covered will include approaches taken to address MASS on a national level and how work could be progressed at IMO.

Panel discussions, addressing all relevant aspects of the development of a regulatory framework for MASS, will allow for an exchange of views on the additional opportunities and international efforts needed to support IMO in its effort to ensure the safe and legally sound operation of MASS.

This seminar follows in the footsteps of the recently completed regulatory scoping exercises (RSE) for the use of MASS by the Maritime Safety Committee (MSC), the Legal Committee (LEG) and the Facilitation Committee. Work has commenced in the three Committees to address the regulation of MASS in the instruments under their purview.

MSC 105 agreed to develop a non-mandatory goal-based MASS Code, which would provide the basis for the development of a future mandatory instrument. LEG 109 and FAL 46 agreed to work on measures to address MASS in the instruments under their purview.

The outcome of the Seminar will be reported to the first meeting of the Joint MSC/LEG/FAL Working Group on MASS, which has been scheduled to take place from 7 to 9 September 2022. The outcome will also be reported to the MSC, the LEG and FAL Committees.


ike many English words and phrases, the description of something reliable as “copper-bottomed” has a maritime origin.

It dates from the 18th century, when seafarers had long struggled with unwanted plants and animals that stuck to the wooden hulls of their ships and slowed them down.

In 1761, the Royal Navy plated the hull of its frigate HMS Alarm in thin copper, which kept away weeds and tube worms so successfully that the practice – and the praise of something risk-free as copper-bottomed – became widespread. At least it did until the launch of iron ships a century later, which unfortunately could not be copper-plated because that encouraged corrosion.

Today’s sailors still struggle with the same problem. More formally called biofouling, the unwanted build-up of sea life on the hulls of everything from pleasure boats to aircraft carriers causes drag through the water. This slows speeds and so necessitates the burning of more fuel, producing both higher costs and more carbon emissions. (The skins of sea creatures from whales to sea snakes can also become encrusted with barnacles in a similar way.)

Biofouling can have a more direct environmental impact as well. As ships criss-cross the oceans, their submarine stowaways can pose real problems to ecosystems that must suddenly learn to live with the new arrivals.

“Pretty much any surface that you put into the ocean is going to get growth on it. It’s going to accumulate biofouling,” says Kelli Hunsucker, an oceanographer at the Florida Institute of Technology. “It’s when that growth becomes too cumbersome that we see these problems. And they are the same problems that the Greeks and the Romans had. They all had issues with biofouling.”

Barnacles and other stowaways

Studies have recorded some 2,000 different species living in these shipbound communities, the barnacle family probably being the best known. Related to crabs and lobsters, these adhesive crustaceans have become shorthand for a sticky nagging problem that’s hard to remove.

Barnacles start life much more mobile, released in their tens of thousands as tiny larvae. Although they can survive for several weeks floating in the sea, to develop into adults they must fix onto a hard surface, which they do with relish. They are such a common feature of life at sea that they were once used in a punishment called keelhauling, in which an unfortunate seaman would be dragged along the underside of the ship’s keel by a rope, and so across fields of razor-sharp shells. The longer the biofouled ship had gone without being beached and cleaned, the worse the experience.

Closeup of striped barnacles or purple acorn barnacles (Amphibalanus amphitrite) on a ship hull. Biofouling, biological fouling.
To develop into adults, barnacles must fix onto a hard surface, such as a whale or a ship’s hull (Image: Jaime Franch Wildlife Photo / Alamy)

Still, the high-profile barnacle is just the most visible form of biofouling, and one that tends to appear relatively late in the process. Microscopic bacteria and algae get there earlier, feeding on the cocktail of chemicals that seawater contains.

“As soon as you put a surface in the water, organic molecules will start to adhere to it. Then within minutes or hours you get bacteria forming,” Hunsucker says. “And then it goes from there to different types of unicellular organisms, algae and quickly up to larger life like barnacles and oysters. It forms this beautiful three-dimensional community with even crabs and shrimps living in there.”

Beautiful to a marine scientist, perhaps, but not to a ship’s captain. A microbial biofilm just a few millimetres thick is enough to significantly increase drag, Hunsucker says. One study suggested that a ship with a medium level of barnacle encrustation would need 36% more power to sustain its speed than a clean one. Dry dock inspections of some 249 ships between 2015 and 2019 found that over 40% had barnacle coverage of 10% or more.

“I think this is going to become a bigger issue for the shipping companies and the cruise lines who are going to be really hit by the drastic increase in the cost of fuel,” Hunsucker says. “You don’t have to reduce your biofouling by much, but if you can reduce it then you can save a lot of money on gas.”

You don’t have to reduce your biofouling by much to save a lot of money on gas

Kelli Hunsucker, oceanographer at the Florida Institute of Technology

How to do that is the “million-dollar question” Hunsucker adds. And it’s a question a lot of people have tried to answer. Many still rely on the old method of hauling ships out of the water and scraping the shells and slime away. That’s effective, but not very efficient. A better strategy is to stop the biofouling forming in the first place. And to do that, besides the Royal Navy and its copper plates, shipowners have tried everything from special paints to ultrasonic waves.

In the 1960s and 1970s, such paints relied on a toxic chemical called tributyl, which is now banned because of its wider negative impact on marine life. Newer paints often rely on copper, which is also drawing criticism for possible environmental damage. Sweden has already introduced restrictions on the use of copper-based paints in some waters.

Yigit Demirel, a naval architect and marine engineer at Strathclyde University, says there could be a more environmentally friendly route to stop biofouling. As the problem is worse where water moves slowly – giving organisms an easier time attaching – Demirel is looking into optimising ship design to speed up water flow across and around the hull, and especially those regions with sluggish flow, such as towards the stern.

“Maybe we can introduce some controlled roughness, or weird shapes, to increase the diversity of the flow. Or maybe we can dramatically change the ship shape and come up with some novel profiles,” he says.

Low fuel costs have meant ship designers have not focused too closely on how to prevent biofouling, he says. The emphasis on climate change and controlling greenhouse gas emissions is changing that. So too is the understanding that biofouling ecosystems transported across the seas themselves pose a threat.

In June this year, Australia will introduce new restrictions on biofouling to prevent the entry of invasive species. These can include the need to thoroughly clean the hull of a ship in the month prior to arrival. New Zealand already operates similar rules, and other places are considering them.

It’s only a matter of time before wider international rules are in place to control hull biofouling, Demirel predicts. It’s a logical next step, given the regulatory crackdown in recent years on the movement of invasive species through ballast water.

The problem within ballast water

Ballast is needed to stabilise ships, even very big ones, in rough weather. Depending on what cargo they carry, vessels typically pump millions of gallons of water into huge tanks before starting a voyage, and then discharge it when they reach their destination. As they pump in water, they also grab whatever sea life happens to be around. When they pump it out again, many of these creatures are still very much alive – and sometimes very unwelcome in the new surroundings.

“Ships have been transporting ballast water for hundreds of years and there are a few examples where it has had severe adverse effects” says Okko Outinen, a marine scientist at the Finnish Environmental Institute, with a special interest in ballast water.

Among the worst incidents was the 1982 introduction of an American jellyfish called a sea walnut to a port in the Black Sea. The creatures flourished, depriving local species of zooplankton, and spreading all the way to the Caspian Sea. Local fisheries, which had been worth hundreds of millions of dollars each year, were wrecked.

Maybe we can dramatically change the ship shape and come up with some novel profiles

In the other direction, ships travelling west across the Atlantic managed to introduce zebra mussels from Europe to the Great Lakes of Canada and the US, where they have caused havoc. “They have very sharp shells that swimmers cut their feet on, and they are able to reproduce quickly and may occur in very high densities, as well as block underwater pipes used in cooling systems by local industries,” Outinen says.

In response to the growing threat and costs of invasive species spread by biofoulled ballast water, the International Maritime Organisation (IMO) drew up regulations in 2004. These came into force in 2017 and declare that “ships must manage their ballast water so that harmful aquatic organisms and pathogens are removed or rendered harmless before” it is released.

It’s a big change for ship operators, Outinen points out. “So, at the moment we are in an implementation and experience-building stage, with the penalisation rules not being fully implemented or enforced yet,” he says. “We’re now figuring out everything related to how ballast water treatment systems work in different freshwater and marine waters. How do we monitor and sample ballast waters in a reliable, quick and cost-efficient manner? How do we detect how many organisms are viable or living? And many other similar practical details.” Once these issues have been worked out, the rules are scheduled to be more rigorously enforced in 2024, he adds.

Some of the problems posed by biofouling and ballast water, such as the transfer of invasive species, are the same. So are some of the possible solutions. One is using ultraviolet light to kill unwanted sea life. In an echo of the Royal Navy’s brainwave to install copper sheets back in 1761, some are experimenting with high-tech tiles that contain ultraviolet light bulbs, which can be fitted to a ship’s hull. If it catches on, then who knows maybe “UV bottomed” will be the latest maritime phrase to enter the English language.


In view of the need to reduce greenhouse gas (GHG) emissions from the maritime sector, MEPC. 76 adopted comprehensive short-term measures including the so-called Energy Efficiency Index for Existing Ships (EEXI) and the Carbon Intensity Index (CII).  The goal is to enhance the energy efficiency of ships through the implementation of these measures.

EEXI is expected to be very similar to EEDI as it is based on the 2018 Calculation guideline of the EEDI, with some adaptations for existing vessels. EEXI describes CO2 emissions per cargo ton and per mile for existing ships of 400 gross tonnage and above. It determines normalized CO2 emissions based on installed engine power, transport capacity and vessel speed. EEXI is a design index, not an operational index. It is not related to readings from previous years and does not require onboard measurements; the index refers only to the design of the vessel.

On the other hand, CII represents an annual operational rating based on the required CII verification.  MEPC 76 agreed to establish a progressive, non-linear scale of CII reductions up to 1% per year until 2023, and then between 2023 and 2027, 2% per annum, and further CII reductions, until 2030, will be decided in the review by 2026.

Depending on the proximity, a rating is recorded in the vessel’s SEEMP to indicate the level of performance as A, B ,C ,D or E.

Vessels rating classification D for three consecutive years or E in one year will need to submit a corrective action plan to put forward how the objective CII would be achieved.

Note that 2030 is the year of the intermediate emissions reduction target set in the IMO’s initial strategy (IMO, 2018) to reduce CO2 emissions per transport work by at least 40% compared to 2008.

Operational carbon intensity

Attained and required annual operational carbon intensity indicator (attained annual operational CII).

After the end of calendar year 2023 and after the end of each following calendar year, each ship of 5,000 gross tonnage shall calculate the attained annual operational CII over a 12-month period from 1 January to 31 December for the preceding calendar year.

Within three months after the end of each calendar year, the ship shall report to its Administration, or any organization duly authorized by it, the attained annual operational CII via electronic communication and using a standardized format to be developed by the Organization.

The attained annual operational CII shall be documented and verified against the required annual operational CII to determine operational carbon intensity rating A, B, C, D or E, indicating a major superior, minor superior, moderate, minor inferior, or inferior performance level, either by the Administration or by any organization duly authorized by it, taking into account the guidelines developed by the Organization.

Corrective actions and incentives

A ship rated as D for three consecutive years or rated as E shall develop a plan of corrective actions to achieve the required annual operational CII.

The SEEMP shall be reviewed to include the plan of corrective actions accordingly, taking into account the guidelines to be developed by the Organization. The enhanced SEEMP (SEEMP III) shall be submitted to the Administration or any organization duly authorized by it for verification, preferably together with, but in no case later than 1 month after reporting the attained annual operational CII.

A ship rated as D for three consecutive years or rated as E shall duly undertake the planned corrective actions in accordance with the SEEMP III.

Administrations, port authorities and other stakeholders as appropriate, are encouraged to provide incentives to ships rated as A or B.

Attained energy efficiency existing ship index (EEXI)

EEXI regulation applies to existing ships of 400 gross tonnage and above. Vessels to which this regulation applies must calculate an EEXI value (i.e. attained EEXI) for each vessel and this value must be equal to or less than the maximum allowable value (i.e. required EEXI). In addition, if the achieved EEXI does not meet the required EEXI, the ship should take all countermeasures, such as: Shaft power limitation (SHaPoLi), engine power limitation (EPL), energy saving devices (ESV), etc.

The attained EEXI should be calculated in accordance with regulation 23 of MARPOL Annex VI and the 2021 Guidelines on the method of calculation of the attained Energy Efficiency Existing Ship Index (EEXI) – (resolution MEPC.333(76)) (EEXI Calculation Guidelines).

The 2013 Guidance on treatment of innovative energy efficiency technologies for calculation and verification of the attained EEDI (MEPC.1/Circ.815) should be applied for calculation of the attained EEXI, if applicable.

For verification of the attained EEXI, an application for a survey and, an EEXI Technical File containing the necessary information for the verification and other relevant background documents should be submitted to a verifier.

In cases of a major conversion of a ship taking place at or after the completion date of the survey for EEXI verification specified in regulation 5.4.7 of MARPOL Annex VI, the ship-owner should submit to a verifier an application for a general or partial survey with the EEXI Technical File duly revised, based on the conversion made and other relevant background documents. The verifier should review the revised EEXI Technical File and other documents submitted and verify the calculation process of the attained EEXI to ensure that it is technically sound and reasonable and follows regulation 23 of MARPOL Annex VI and the EEXI Calculation Guidelines. For verification of the attained EEXI after the major conversion, speed trials of the ship may be conducted, as necessary.

Ships affected by EEXI must demonstrate compliance at their next International Air Pollution Control Certificate (IAPPC) survey (annual, intermediate or renewal) or at the initial survey before the ship is put into service to obtain an International Energy Efficiency Certificate (IEEC) issued on or after January 1, 2023, whichever comes first. The effective date is November 01, 2022.

Conclusion

The shipping industry is a major contributor to global climate change, accounting for almost 3% of total CO2 emissions. This is sufficient for the implementation of IMO’s rigorous criteria. The maritime industry is under a lot of pressure to reduce CO2 emissions. Numerous studies are being conducted to increase the efficiency of this industry in order to mitigate the potential risks that may arise in the future.

 

The environment is the biggest winner. Due to the fact that the worldwide fleet renewal rate is so sluggish, regulating the energy efficiency of new vessels through EEDI is simply too slow to have an impact on total emissions.  Likewise, increasing regulatory pressure to improve the energy efficiency of new ships may reduce interest in renewing the existing global fleet. Existing and new ships are subject to the same regulations, leveling the playing field.

In 2023, the Carbon Intensity Indicator (CII) will be implemented alongside with the EEXI regulation. This indicator takes into account actual CO2 emissions from ship operations.

The IMO Marine Environmental Protection Committee (MEPC) has scheduled its 78th session from 6 to 10 June 2022, presenting an executive summary with more technical information and explanations on regulations regarding IMO GHG Strategy.


Nigeria’s largest container terminal, APM Terminals Apapa, on Thursday signed a Memorandum of Understanding (MoU) with an indigenous firm, FREEE Recycle Limited, to recycle its used tyres.

In December 2021, APM Terminals Apapa carried out a successful trial by using pavement blocks produced out of recycled and compressed used tyres for exterior flooring.

Speaking during the MoU signing ceremony in Lagos on Thursday, the Terminal Manager, APM Terminals Apapa, Steen Knudsen, said the MoU is in furtherance of the company’s contribution to reducing the harmful effects of industrial wastes on the environment.

He said, “We are reducing environmental footprint in Nigeria, and I am super excited we have FREEE Recycle Limited to partner with. We are recycling the tyres into materials that can be used in other parts of the supply chain.

“It is important to partner with companies that have different expertise to complement our efforts to ensure that together, we reduce the environmental footprint in our businesses.”

The Procurement Manager of APM Terminals Apapa, Chinyere Adenaike, said the leading terminal operator remains committed to sustainability and protection of the environment.

“We are committed to always taking constant care to ensure responsible operational practices that minimise, reduce and prevent negative environmental impact in the community. At the leadership level at Apapa, we have committed to a thorough review of our capital investments in equipment to ensure it is in line with our Maersk global ambition of zero CO2 Emission by 2040.

“The commitment is not just on equipment, we are also looking into the lifecycle of our rolling stock, from cradle to grave. We are happy to have partners who share our ambition towards environment, and a port authority that firmly supports these initiatives,” Adenaike said.

The Managing Director of FREEE Recycle Limited, Ifedolapo Runsewe, commended APM Terminals Apapa for taking the lead in reducing solid waste in the country, and said that the MoU will enhance a collaborative effort in recycling tyres into reusable products.

She said, “This MoU will allow both parties to work together towards recycling of tyres, and we are excited that APM Terminals decided to take the forefront of this. We will be working with them for the next five years to ensure that all tyres generated within the facility are recycled into reusable products and re-used. We hope that more organisations will come onboard.”

The Chief Operating Officer of FREEE Recycle, Theopilus Okoyomon, said, “We know the dangers tyres pose to our environment. They lead to emissions of CO2 and they are a breathing space for malaria mosquitoes. APM Terminals leading the way is more like a clarion call to all other companies to step forward.”

A representative of the Nigerian Ports Authority (NPA), Maryann Okeke, commended the tyre recycling initiative.

“We do get a lot of tyres from Lagos channels. Our commitment to consistent dredging has opened us to solid waste that can be recycled, we are having discussions with the Lagos State Government and carrying out sensitization on the removal of solid waste from the habour. Sometimes, truck drivers would come to the harbour, exchange tyres and leave the damaged ones there. But having such partnership in place will help us to make use of those solid wastes,” Okeke said.

A representative of BASF West Africa, Oyewale Akeredolu, said, “For us at BASF, business success tomorrow means creating value for our customers, partners and environment today. I am glad to be here with FREEE Recycle and APM Terminals today – I believe, on behalf of BASF, that they are doing something quite remarkable. We are happy to be a part of the story for FREEE Recycle by providing them with environmentally friendly systems and technology to be able to convert waste tyres into reusable products. Not every company will find their wastes efficiently managed, recycled and reused.”

APM Terminals Apapa is the largest container terminal in Nigeria. With an investment of over USD438 million in equipment, the terminal has continued to introduce new innovations to help both shipping lines and landside customers achieve improved supply chain efficiency, flexibility and dependability in a cost-effective manner.


At the spring meetings of the International Maritime Organization (IMO), we prepared international regulation, standardisation and guidelines. Global regulation ensures that ships, their systems and responsibilities are subject to the same requirements everywhere. By promoting digitalisation and automation, Finland strives for efficiency, safety and sustainability. In this way, we promote sustainable business and service development.

Automation can be used in shipping to improve the wellbeing and occupational safety of crew, among other things. Partial automation or remote performance of lookout tasks would allow for more flexible resting periods. The most dangerous work situations can be reduced, for example, by means of autonomous rescue vessels or remote pilotage.

Finland supports global electronic data exchange

At the meeting of the Facilitation Committee (FAL) in May, amendments were adopted, which require public authorities to have a system for the electronic transmission of the data required during a port call, to ensure that information only needs to be submitted once.  In addition, rules on health safety were adopted based on lessons learned from the pandemic. The amendments are due to enter into force on 1 January 2024.

The Committee also decided to extend the IMO Compendium with five new data sets on ship reporting systems, ship and company certificates and port state control inspections. The Committee decided to prioritise passenger data and the electronic or ocean bill of lading in its continued drafting. The bill of lading is a key document for merchant shipping and logistics chains. Finland supports the maintenance of the Compendium in 2023.

The harmonisation of data aims at interoperability of systems. By providing the information in digital format through interfaces only once, we enhance the exchange of information and transports. The main benefits are achieved at system level, so the exchange of port information and reporting formalities are an important part of the work of the IMO. By utilising data, consignments can be optimised, for example, by sharing route, time and cargo information, as well as by using AI-based applications.

Roadmap for automation guidelines and regulation

The IMO’s Maritime Safety Committee (MSC) has decided to prepare guidelines on maritime automation in accordance with a common roadmap with the ultimate goal of binding legislation. The guidelines will initially cover cargo ships and will subsequently be assessed for application to passenger ships. Finland supports technology neutrality, that is, a balanced approach to the use of different technologies, in the preparation of regulation.

The roadmap contains not only the key themes identified in the inventory of regulatory barriers, but also possible new themes. In our opinion, these themes should include artificial intelligence, cybersecurity and other principles enabling trust in automation.

The aim is for the guidelines to support the preparation of binding regulations on automation. Application developers must design their systems in such a way that they can be approved for use as reliable and the authority can verify that they are compliant and safe. Simulation and experiments are key tools in this work. The authorities, for their part, develop risk assessment, which requires that they receive sufficient information about, for example, automation experiments. Cooperation between business and public authorities is very important.

The Maritime Safety Committee’s automation roadmap supports Finland’s view on the progress of automation. It is not yet time to decide whether a vessel can be completely unmanned. First, solutions and equipment that support safe decision-making must be made available. Drawing the line between what new legislation is needed and what existing legislation is applicable is still ongoing. We need a debate on what a Maritime Autonomous Surface Ship (MASS) is from the point of view of IMO legislation.

The work of the Maritime Safety Committee will continue in the correspondence group, in which we need the views of industry and other authorities on the needs and objectives of the guidelines. The most challenging issues will be dealt with in cooperation by the Maritime Safety Committee, the Facilitation Committee and the Legal Committee (LEG), as the cross-cutting issues concern conventions for which they are all responsible. Important issues are related, for example, to the roles and responsibilities of the shipmaster, crew and other stakeholders, starting with the question of whether a vessel may be controlled from outside the vessel. In Finland legislation already allows, for example, remote maintenance.

Possible national introduction before international regulation

The guidelines may be used in national waters, where applicable, even before the entry into force of binding international legislation. We are currently carrying out a preliminary study of the needs and possibilities for amending national legislation if necessary. Opportunities could be offered in the coming years by, for example, an autonomous tug, a cable ferry, a taxi boat, remote pilotage or a road ferry on which experiments have already been carried out. Finnish expertise is also of a high standard in port automation.

Nationally, work will continue in the direction indicated by the resolution on promoting automation in the transport sector, which includes the maritime sector. We warmly welcome all interested parties to participate in the development work.


Twelve of the 25 signatories to the Sea Cargo Charter succeeded in matching International Maritime Organization decarbonisation targets for their sector in 2021.

But according to the first Disclosure Report released earlier today., there was a wide range of results, extending from plus 46.2 to minus 26.1.

However, in the introduction to the Report, Cargill’s Jan Dieleman and Trafigura’s Rasmus Bach Nielsen, respectively Chair and Vice Chair of the Sea Cargo Charter Association, urged readers not to see the first Report as a league table. All signatories have very different profiles and activities, they noted, and comparisons are thus difficult. “What we do share is our belief that there is a positive feedback loop between transparency and action and our intention to limit adverse environmental impact,” they said.

Together, the 25 companies comprise major charterers and customers of shipping services in energy, agriculture, mining, and commodity trading. They account for about 15% of total bulk cargo shipped by sea last year.

Sea Cargo Charter’s membership has now grown to 33 but only those who signed up prior to September 2021 have reported in the first Disclosure Report. The organisation, which describes itself as a global framework for aligning ship chartering activities with society’s goals, is actively scouting for more members.

In a statement, Dieleman said: “Thanks to unprecedented levels of data sharing, we better understand the climate impacts of our business activities at a much more granular level, and can back up operational and strategic decision-making with real data. Signatories of the Sea Cargo Charter have diverse profiles and activities and this report holds us accountable to our targets and allows us all to play our part in addressing the environmental impacts of global maritime trade on people and the planet.”


A consortium between by U.S. classification society American Bureau of Shipping (ABS) and U.K.’s consultancy provider Arcsilea has won a tender from the European Commission to carry out a technical study on the future of ship energy efficiency measures introduced by the International Maritime Organization (IMO).

As disclosed, the partners won the tender from the European Commission’s Directorate-General for Mobility and Transport (DG MOVE).

The 15-month-long project will analyze the IMO’s Carbon Intensity Indicator (CII), Energy Efficiency Existing Ship Index (EEXI) and Energy Efficiency Design Index (EEDI) framework.

Moreover, the parties will provide recommendations for further development, effective implementation and enforcement.

The initiative is part of the Smart and Sustainable Mobility Strategy adopted by the European Commission, which calls for the European Union (EU) to establish sustainability standards with the IMO.

The strategy was adopted to meet the target set under the European Green Deal, which is to reduce transport-related greenhouse gas emissions by 90% by 2050.

“Energy efficiency measures are cumulatively changing the shape of our industry before our eyes. We can see how they are driving change on fleets and operations as owners understand how to adapt their existing assets and new orders to perform in the new business environment they create,” said Georgios Plevrakis, ABS Vice President, Global Sustainability.

“We are very pleased to continue our collaboration with DG MOVE and ABS to help drive practical improvements to the IMO short-term measures,” Edwin Pang, Arcsilea Founder and Principal Consultant added.

Last year, IMO agreed on a set of draft guidelines to support mandatory measures approved by the Marine Environment Protection Committee (MEPC) to cut the carbon footprint of all ships.

IMO’s MEPC 78, held from 6 June to 10 June 2022, saw the organization addressing short-term measures to reduce GHG emissions, mid-term measures including strengthening the carbon intensity indicator for ships and start considering a revision of the IMO’s GHG strategy.


IBIA believes full Well-to-Wake lifecycle emissions should be taken into account to ensure the IMO’s greenhouse gas policy is holistic, and continued efforts to decarbonise shipping doesn’t end up causing increased overall GHG emissions.

At its 78th session, the Marine Environment Protection Committee (MEPC 78, 6-10 June) held a truncated discussion on this complex subject due to time constraints.

Rather than having a full consideration of proposals, MEPC 78 agreed instead to establish a correspondence group on marine fuel lifecycle GHG analysis to further the work. The correspondence group will submit an interim report to MEPC 79, and final draft guidelines to be adopted by MEPC 80.

The majority view at the IMO is that the LCA guidelines will allow for a Well-to-Wake calculation, including Well-to-Tank and Tank-to-Wake emission factors, of total GHG emissions related to the production and use of alternative marine fuels.

Discussions also include which type of GHGs to be calculated (e.g. not just CO2 but possibly also methane, nitrous oxide, black carbon) and whether to include 20-year global warming potential (GWP) as well as 100-year GWP for each type of fuel and its GHG emissions for comparison purposes.

At present, IMO regulations only deal with Tank-to-Wake emissions from ships.

Apart from the complexity surrounding the LCA guidelines, in particular how to certify the Well-to-Tank part of emissions, the big question is how such LCA guidelines are eventually incorporated into IMO regulations.

The correspondence group has been asked to further develop the draft guidelines on lifecycle GHG intensity of marine fuels (draft LCA guidelines), and in doing so:

– Identify main initial fuel production pathways and feedstocks for inclusion
– Further consider sustainability criteria issues and further develop the Fuel Lifecycle Label (FLL)
– Develop methodologies that allow for the calculation of Well-to-Tank, Tank-to-Wake and entire Well-to-Wake GHG emissions default values
– Develop procedures that allow for continuous review of GHG emissions default values
– Develop guidance for third-party verification and certification schemes


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