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VPS: The emergence of B100 (FAME) in a volatile distillate market

Paul Hoather of VPS highlighted the emergence of B100 as a marine fuel, in light of the volatile pricing of marine distillates driven by the Middle East conflict and the closure of the Strait of Hormuz.

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Paul Hoather, UK Sales Manager of marine fuels testing company VPS, on Wednesday (8 April) highlighted the emergence of B100 as a marine fuel, in light of the volatile pricing of marine distillates driven by the Middle East conflict and the closure of the Strait of Hormuz. 

He also outlined the fuel management considerations required to mitigate the potential risks associated with using B100 (FAME) as a marine fuel: 

Distillate Price Volatility Makes B100 (FAME) a Viable Option

The 2026 Middle East conflict, including the closure of the Strait of Hormuz, through which 25% of the world’s oil & 20% of LNG flows, has triggered one of the largest global energy supply disruptions in modern history. This narrow waterway is the world’s most critical energy chokepoint, with over 80% of its oil and natural gas shipments bound for Asia.

The closure of the Strait has caused supply shortages and transport paralysis with tanker traffic nearly halted. Although the Middle East conflict situation remains fluid, if this continues to worsen, then commentators have suggested that crude oil could reach record levels.

Marine Distillates are particularly exposed, with roughly 1.15 million b/d of middle distillates being impacted by the Hormuz disruption, coupled with further price drivers such as insurance premiums making distillate supply a premium.

With distillates now at historically high levels, this has given rise to attractively priced alternative Marine Fuel sources, which are not as directly affected by Middle East crude disruptions. As Biodiesel pricing is driven in part by agricultural feedstocks, the pricing gap between B100 FAME and distillates has reduced. Thus, even if B100’s nominal price per tonne remains slightly higher than distillate, the effective cost per voyage is now materially lower or near-parity. The added environmental and legislative benefits of CO2 reduction by using B100 also leads to reduced carbon taxation due to emissions pooling under FuelEU maritime regulation.

Effectively Shipowners now see a smaller economic penalty – and in some cases a net benefit for switching to B100.

Recommended Approach for Introducing B100 FAME

VPS is seeing an increase in B100 FAME usage, although fossil fuels remain the dominant marine fuels. The use of B100 has however increased in response to the aforementioned dynamics. As the standard blend configuration, we see Bio-blends in the form of B30 being used with 70% fossil fuels, such as distillate, very low sulphur fuel oil (VLSFO) and heavy fuel oil (HSFO). These fuel blends present limited risk in terms of operational use and handling. However, Biofuels including B100, require specific fuel management considerations, which VPS has highlighted in past articles available at: Articles | VPS.

These challenges include: 

  • Lower energy value compared to fossil fuels. 
  • Susceptibility to Oxidation, making prolonged storage unsuitable and future condition uncertain. 
  • Oxidation can also result in increased Acid Number which increases the risk of corrosion within the fuel system, including components such as fuel pumps and injectors, in addition to potential storage tank corrosion.
  • B100 FAME, has a natural hygroscopic tendency which can increase water absorption. This, in turn provides a suitable breeding ground for Microbial growth.
  • A final point of consideration is the  behaviour of B100 FAME in fuel/lubricant interaction. While distillate fuels generally have a lower viscosity than FAME, FAME is less volatile due to its heavier molecular structure and higher boiling range (typically around 272°C compared to approximately 170°C for distillates). As a result where fuel ingress occurs due to leakage or incomplete combustion, B100 is more likely to remain in the lubricating oil rather than evaporate. This can lead to dilution of the lubricating oil, particularly in 4-stroke engines, resulting in a reduction in oil viscosity and potential operational problems.

That said, B100 (FAME) is already in use by many clients, and we have seen very few technical issues. This indicates that with appropriate fuel management and handling practices, B100 can be successfully used as a drop-in fuel.

To support successful implementation and operation, VPS recommends the following:

Ideally, B100 should be introduced after tanks have been drained and flushed to minimise the presence of water that could promote, fuel instability and microbial activity. Where possible thorough tank cleaning is recommended, as there is a likelihood that tanks may contain unpumpable residues from previous fossil fuel bunkers. These residues can become mobilised due to the relatively high solvency properties of FAME, lifting tank-bottom deposits when first introduced and potentially overloading purifiers during the initial stages.

Where possible, VPS recommends compatibility (spot) analysis prior to use. Onboard blending is not recommended. However, if operationally unavoidable, B100 should be bunkered and stored in a separate tank, blended in small portions, with performance and fuel quality being evaluated before progressing to higher ratios.

Verify compatibility of the fuel system components, including seals, gaskets, hoses & coatings. Pay particular attention to elastomers and painted surfaces. Confirm suitability with the OEM for main and auxiliary engines. Ensure any required changes are reflected in the Ship Technical File (SEEMP).

When B100 must be bunkered directly into tanks containing existing MGO, the following guidance should be followed:

Operational Guidance for Changeover from MGO to B100 (100% FAME)

  • Monitor engine performance: B100 (FAME) has a lower calorific value than MGO, so adjustments will be required to maintain power output. This can be noticed through elevated exhaust gas temperatures, requiring the fuel rack to be adjusted.
  • Minimise water in fuel tanks: Drain tanks regularly, especially considering condensation from weather variations. Water promotes microbial growth.
  • If fuel is not consumed within 3-4 months: take a representative tank sample for a quality assessment including Oxidation Stability, Iodine Value, Total Acid Number, Water Content, Cloud Point and Bacteria, Yeast and Fungi. 
  • Carryout the VPS recommended APS-FAME test suite, as it covers the key analyses required to assess FAME quality in line with EN14214, which is referenced under ISO8217:2024. A summary of the APS key test parameters is discussed later in this paper.
  • Monitor for fuel degradation. As a bio derived product, B100 degrades faster than MGO which can oxidise quickly resulting in increasing Acid Number & Iodine value over time which is a common indicator. Where possible, check gaskets and O rings for signs of wear.
  • Continuous operation on B100 may increase the likelihood of fuel dilution in the used engine oil, due to fuel ingress that remains entrained in the lubricating oil, particularly in four-stroke engines. This may result in reduction in engine oil viscosity and premature degradation of the oil, leading to reduced running hours between oil changes.
  • Avoid excessive heating of fuel. Ensure fuel is suitable for ambient conditions (cold flow considerations). 
  • Operate separators and filters as per normal procedures. During initial use, increase monitoring of filter condition and differential pressure and separator performance.

VPS Support through Additional Protection Service – APS-FAME

VPS additional protection service was established to provide greater understanding and insight of marine biofuel quality. Whilst the introduction of ISO8217:2024 now caters for Biofuel & Bio-blends, it is still not an all-encompassing test slate, as it places the onus on suppliers to ensure that the FAME component used for blending, or supplied as B100, complies with EN14214 or ASTM D6751. APS-FAME is therefore recommended to provide a more comprehensive assessment of fuel quality.

APS-FAME – Key Analytical Parameters Overview for B100/FAME

APS-FAME provides deeper insight beyond the ISO8217:2024 specification with respect to the quality, stability, and suitability of FAME-based marine biofuels through the following parameters:

  • Corrosion @ 50°C (Steel)
    Assesses the corrosive potential of the fuel system on metallic components such as fuel pumps & fuel injectors at elevated temperatures. This helps to spot early signs of corrosivity
  • Iodine Value
    Indicates the level of unsaturation (double bonds) in fatty acid chains.  A higher iodine value reflects greater unsaturation, which can reduce fuel stability and affect storage behaviour. 
  • Oxidation Stability
    FAME can break down overtime; this test evaluates how resistant the fuel is to degradation during onboard storage.
  • Net Heat of Combustion
    For blends greater 10% FAME, the D240 method provides the only means to accurately determine the fuel’s energy content.
  • Total Contamination (Particulates)
    Measures particulate levels that may lead to:
    o    Filter plugging
    o    Injector wear
    o    System fouling
  • Bacteria, Yeast, and Fungi
    A crucial parameter for FAME, due to its affinity to water, which creates favourable conditions for microbial growth.

The ongoing Middle East conflict is giving rise to serious concerns for many shipowner-operators. The significant volatility in Marine Gas Oil and Distillate pricing, as well as a potential impact on product availability, are factors driving vessel operators to seek alternative solutions.

In this environment, the commercial case for B100/FAME is expected to strengthen. Supported by a narrowing fuel price differential, plus a positive contribution towards both emerging and existing regulatory requirements, this drop-in fuel is gaining momentum as a viable marine fuel option.

While the use of B100/FAME requires more cautious fuel handling and operational considerations in order to mitigate operational risks, customers can rely upon VPS  to provide insightful support throughout this transition. Our market-leading experience and expertise in marine fuel testing provides detailed fuel quality analysis, supported by sound scientific and marine engineering advice. All of this will help our customers make more informed decisions and operate with more confidence.

 

Photo credit: VPS
Published: 9 April, 2026

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Port & Regulatory

Singapore: MPA issues circular on resolutions adopted by IMO MEPC 84

MPA urges the shipping community to prepare for the implementation of these resolutions, which includes use of multiple engine operational profiles for a marine diesel engine.

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The Maritime and Port Authority of Singapore (MPA) on Tuesday (14 July) issued Shipping Circular No. 7 of 2026 to inform on the resolutions adopted by MEPC 84, which was held from 27 April to 1 May 2026:

This circular informs the shipping community of the resolutions adopted by MEPC 84 and urges the shipping community to prepare for the implementation of these resolutions.

MEPC 84 adopted the following mandatory resolutions:

  • Resolution MEPC.407(84) – Amendments to MARPOL Annex VI (Clarification of entries in data reporting required by Regulations 27 and 28, designation of the North-East Atlantic as an Emission  Control Area for Nitrogen Oxides, Sulphur Oxides and Particulate Matter, accessibility to the IMO Ship Fuel Oil Consumption Database, and review clause of the short-term GHG reduction measure)

This resolution adopts amendments to MARPOL Annex VI, concerning the clarification of entries in data reporting required by regulations 27 and 28, the designation of the North-East Atlantic as an Emission Control Area for Sulphur Oxides, Particulate Matter and Nitrogen Oxides, the accessibility of the IMO Ship Fuel Oil Consumption Database (IMO DCS), and the review clause of the short-term GHG reduction measure. The amendments will enter into force on 1 September 2027 and will be given effect through the Prevention of Pollution of the Sea (Air) Regulations.

  • Resolution MEPC.408(84) – Amendments to MARPOL Annex VI (Use of multiple engine operational profiles for a marine diesel engine, including clarifying engine test cycles)

This resolution adopts amendments to MARPOL Annex VI concerning the use of multiple engine operational profiles for a marine diesel engine, including clarifying the engine test cycles. The amendments will enter into force on 1 September 2027 and will be given effect through the Prevention of Pollution of the Sea (Air) Regulations.

MEPC 84 also adopted the following resolutions:

  • Resolution MEPC.406(84) – Actions to ensure the protection of the marine environment in the Arabian Sea, Sea of Oman and the Gulf Region, particularly in and around the Strait of Hormuz, resulting from the unlawful activities of the Islamic Republic of Iran

This resolution condemns the attacks against commercial and merchant vessels and maritime infrastructure in the Gulf region. The resolution expresses deep concern over the risks these attacks pose to the marine environment, while encouraging member States to strengthen pollution preparedness and response cooperation.

  • Resolution MEPC.409(84) – 2026 Guidelines for Ballast Water Management (BWM) and Development of BWM Plans (G4)

This resolution adopts the 2026 Guidelines for BWM and development of BWM Plans, as part of the BWM Convention review. The Committee resolves to revoke the Guidelines for ballast water management and development of BWM Plans adopted by resolution MEPC.127(53) and amended by resolutions MEPC.306(73) and MEPC.370(80) when the amendments to the BWM Convention approved at MEPC 84 enter into force.

  • Resolution MEPC.410(84) – Amendments to the 2022 Guidelines on the Method of Calculation of the Attained Energy Efficiency Design Index (EEDI) for New Ships

This resolution adopts the amendments to the 2022 Guidelines on the method of calculation of the attained EEDI for new ships, to address dual-fuel engines using two liquid fuels, particularly methanol and ethanol, in the EEDI framework.

  • Resolution MEPC.411(84) – 2026 Guidelines on Survey and Certification of EEDI

This resolution adopts the 2026 Guidelines on survey and certification of the EEDI, to address dual-fuel engines using two liquid fuels, particularly methanol and ethanol, in the EEDI framework.

These Guidelines supersede the 2022 Guidelines on survey and certification of the EEDI (resolution MEPC.365(79), as amended by resolutions MEPC.374(80) and MEPC.403(83)).

  • Resolution MEPC.412(84) – Amendments to the 2022 Guidelines on Operational Carbon Intensity Indicators and the Calculation Methods (CII Guidelines, G1)

This resolution adopts the amendments to the 2022 CII Guidelines, G1, relating to the clarification of CII calculation obligations in the context of enhanced IMO DCS granularity reporting, specifically on “Transport work (W)”.

  • Resolution MEPC.413(84) – Amendments to the 2024 Guidelines for the development of a Ship Energy Efficiency Management Plan (2024 SEEMP Guidelines)

This resolution adopts amendments to the 2024 SEEMP Guidelines, relating to the clarification of CII calculation obligations in the context of enhanced IMO DCS granularity reporting, specifically on the “Distance travelled”.

  • Resolution MEPC.414(84) – 2026 Guidelines for test-bed and onboard measurements of methane (CH4) and/or nitrous oxide (N2O) emissions from marine diesel engines

This resolution adopts the 2026 Guidelines for test-bed and onboard measurements of methane (CH4) and/or nitrous oxide (N2O) emissions from marine diesel engines, and supersede the earlier Guidelines adopted by resolution MEPC.402(83).

  • Resolution MEPC.415(84) – Guidelines for engine load monitoring (ELM) and calculation of emission values

This resolution adopts the Guidelines for ELM and calculation of emission values, to specify the method for ELM to establish factors that reflect the actual operation of a marine diesel engine, and for the calculation of emission values.

  • Resolution MEPC.416(84) – Guidelines for continuous emission monitoring systems (CEMS) used to quantify methane (CH4) and/or nitrous oxide (N2O) emissions from marine diesel engines

This resolution adopts the Guidelines for CEMS used to quantify methane (CH4) and/or nitrous oxide (N2O) emissions from marine diesel engines, which aim to provide a uniform framework for the onboard measurement and mass basis quantification of emissions.

  • Resolution MEPC.417(84) – 2026 Strategy and the Action Plan to Address Marine Plastic Litter from Ships

This resolution adopts the 2026 Strategy and the Action Plan to Address Marine Plastic Litter from Ships.

Any queries relating to this circular should be directed to MPA Shipping Division via email at [email protected].

 

Photo credit: Maritime and Port Authority of Singapore
Published: 14 July, 2026

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Alternative Fuels

Port of Santos hosts Brazil’s first bioethanol bunkering of deep-sea containership

Copersucar, CMA CGM Group, AGEO Terminais, Santos Brasil and Bunker One completed a bioethanol bunkering operation for “CMA CGM IRON”, the first 13,000 TEU tri-fuel certified engine containership.

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Port of Santos hosts Brazil's first bioethanol bunkering of deep-sea containership

Sugar and bioethanol trading company Copersucar on Monday (13 July) said the company and its partners successfully completed a bioethanol bunkering operation for the CMA CGM IRON, the first 13,000 TEU tri-fuel certified engine containership, at the Port of Santos on 12 July.

The partners are CMA CGM Group, AGEO Terminais, the largest liquid bulk storage operator at the Port of Santos; Santos Brasil, the biggest container terminal in Brazil; and Bunker Holding subsidiary Bunker One. 

Copersucar said the operation represents a major milestone for the decarbonisation of maritime transport, positions Brazil among the countries capable of carrying out this type of bunkering operation, and reinforces bioethanol as a readily available solution to reduce greenhouse gas emissions from the shipping sector.

The bioethanol supplied by Copersucar benefits from a certified supply chain. Sugarcane expansion takes place mainly on degraded pastureland, while Brazil’s RenovaBio program establishes stringent sustainability and zero-deforestation requirements.

The bunkering required logistical and operational coordination among multiple stakeholders across the value chain, involving the transport of bioethanol to the Port of Santos, its storage in dedicated infrastructure, and its transfer to the vessel via a specialized barge.

“The operation provides practical evidence that bioethanol offers the attributes needed to accelerate the decarbonisation of maritime transport,” the company said. 

Beyond this first demonstration, the Port of Santos and Santos Brasil container terminal are positioning themselves and Brazil as a future low-carbon marine fuels hub for South America. As the continent’s largest port and a major gateway for global trade, Santos has the potential to connect Brazil’s renewable energy resources with international shipping demand. 

The CMA CGM IRON, delivered in 2025, is the Group’s first vessel in a series of twelve 13,000 TEU containerships, equipped with the world’s first tri-fuel engine certified to operate on bioethanol: Everllence-B&W G95ME-C10.5-LGIM.

“Together with our partners, we have shown that innovation can move from the laboratory to real maritime operations. The certification of our first tri-fuel vessel is a major technological milestone for CMA CGM. It opens the way for the broader use of lower-carbon fuels and gives us new options to accelerate the decarbonisation of our shipping activities” said Christine Cabau Woehrel, Executive Vice President Assets & Operations, CMA CGM.

“This operation demonstrates Copersucar’s ability to connect production, logistics and markets to enable bioenergy solutions at scale. More than a pioneering bunkering operation, we are creating the conditions for bioethanol to become a competitive component of the maritime energy mix, further strengthening Brazil’s leadership in the transition to a low-carbon economy,” said Tomás Manzano, CEO of Copersucar.

“This operation can be considered a milestone in the global maritime industry’s energy transition, as the sector begins to adapt to this new model. Today, Around 70 vessels of the global fleet are capable of operating on methanol and, consequently, with bioethanol. Over the next few years, however, an additional 400 vessels are expected to be delivered from shipyards ready to sail using a non-fossil fuel,” said Flavio Ribeiro, CEO of Bunker One.

 

Photo credit: Copersucar
Published: 14 July, 2026

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Alternative Fuels

Peninsula supplies bio-LNG bunker fuel to Royal Caribbean cruise ship

Company has successfully completed the delivery of bio-LNG to Royal Caribbean Group’s newest Icon-class cruise ship, “Legend of the Seas”, in Cádiz, Spain.

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Peninsula completes delivery of bioLNG bunker fuel to Royal Caribbean cruise ship

Marine fuel supplier Peninsula on Monday (13 July) said it has successfully completed the delivery of bio-LNG to Royal Caribbean Group’s newest Icon-class cruise ship, Legend of the Seas, in Cádiz, Spain.

This marked Peninsula’s first bioLNG distribution in the Port of Cádiz. The milestone was met with amplified significance as the company has now supplied all three Icon-class vessels, further strengthening its long-standing relationship with Royal Caribbean Group.

Nacho de Miguel, Head of Alternative Fuels and Sustainability at Peninsula, said: “This supply highlights the strength of our planning, coordination and execution at scale. As cruise operators introduce increasingly advanced vessels, our focus remains on delivering safe, reliable and efficient fuel supply, aligned with evolving operational and environmental demands.”

The delivery was carried out through coordination with all stakeholders, including the Port of Cadiz and Royal Caribbean Group. 

 

Photo credit: Peninsula
Published: 14 July, 2026

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