Author: Awwal Idris, Environmental Expert at Water Revolution Foundation
Highlights
- HVO offers up to a 90% reduction in CO₂ emissions (Well-to-Wheel) compared to fossil diesel; the CO₂ produced during HVO combustion is biogenic in origin and reabsorbed in the carbon cycle, unlike fossil diesel, whose CO₂ remains in the atmosphere, capturing heat.
- HVO is fully compatible with existing diesel engines, requiring no modifications, and is already certified by leading engine manufacturers like MTU.
- HVO reduces harmful local air pollutants, including particulate matter and nitrogen oxides (NOx), while containing no sulphur or PAHs.
- Sustainable sourcing and certifications like ISCC or REDcert ensure HVO is produced responsibly, minimizing environmental impact and supporting a circular economy.
Introduction
The internal combustion engines, mostly powered by fossil fuels, is still the primary energy source for many industries, including the boating and yachting industry.
But as our society evolves and the scientific community measures reliably the impact of our reliance—its significant urban air pollution and greenhouse gas emissions—our industry is at the forefront to respond to the urgent need for new technology and policy changes.
This article explores HVO as one opportunity for transition, its potential role in reducing emissions within the superyacht industry including specific examples for superyachts.
Phasing out diesel
In Europe and worldwide, diesel engines are widely used for their greater efficiency, which allows them to produce 10–40% less CO2 than gasoline engines. However, diesel engines, including those on yachts, struggle to meet strict emissions standards, such as the International Maritime Organization Tier III, which sets limits on nitrogen oxide (NOx) emissions from marine diesel engines. This challenge arises from the unique operational hours of yachts, which often involves prolonged periods at low engine regimes. As a result, emissions control systems like selective catalytic reduction (SCR)—which needs to attain a high temperature for efficacy (240-450 °C)—are less effective in reducing NOx and particulate pollution.
Plant-based biofuels offer a promising way to reduce emissions. Biodiesel, often called FAME (fatty acid methyl esters), a first-generation biofuel, is the most common alternative to regular diesel. It’s made from crops like soy or rapeseed using a process called transesterification. Biodiesel helps reduce pollutants like carbon monoxide, unburned hydrocarbon (HC), and particle emissions. However, it has drawbacks: it breaks down more easily, performs poorly in cold weather, and can damage fuel system parts. Due to these issues, the EU limit biodiesel blends with regular diesel to a maximum of 7%.
Hydrotreated Vegetable Oil (HVO)—a paraffinic fuel made from diverse bio-based feedstocks (second generation), such as plant oils, animal fats and waste materials—avoids many of biodiesel’s problems. Made by treating vegetable oils with hydrogen, HVO produces fuel similar to regular diesel but without sulfur or other pollutants. Making HVO is also cheaper than making biodiesel, and it works easily in standard diesel engines without any modifications required. Most prominent engine manufacturers such as the MTU have recently certified most of their engine models for HVO. In fact, HVO can be mixed with diesel in any amount or even used 100% on its own without major engine adjustments. Many research studies [1,2] have highlighted the potential advantages of HVO with respect to FAME and regular diesel.
What is HVO (Hydrotreated Vegetable Oil)?
Hydrotreated Vegetable Oil, commonly known as HVO, is a renewable fuel produced from feedstocks like vegetable oils, waste fats, and animal fats. HVO is created through a process that treats these feedstocks with hydrogen in the presence of a catalyst, removing oxygen and producing hydrocarbons similar to those in traditional diesel. The resulting fuel has properties that closely resemble fossil diesel, but lacks sulphur and other harmful compounds like Polycyclic Aromatic Hydrocarbons (PAHs) which are present in fossil diesel. HVO has much lower carbon footprint over its entire lifecycle because it uses renewable resources and emits fewer GHGs.
Key benefits of HVO
One major advantage of using HVO as fuel is the significant reduction in CO₂ emissions it offers. Take, for example, a 90-meter superyacht, which will typically consume about 300 litres of fuel per hour while cruising. This type of vessel will generally operate for about 1,500 hours annually, equating to only 10% of its time, as the remaining 90% is spent anchored or at a marina. If this superyacht runs on conventional diesel, its CO₂ emissions would be around 1,206,000 kg each year. This is roughly equivalent to the emissions of 743 average European cars or the annual carbon footprint of about 166 European citizens [see references for calculation details here].
It’s important to note that these emissions account only for diesel combustion in the yacht’s engines used for propulsion in a year and do not include the “hotel load”—the other 50% of the yacht’s energy consumption. The hotel load powers essential non-propulsion needs onboard, such as heating, cooling, lighting, and appliances, all of which are vital to the comfort and functionality of the vessel. If we were to factor in both propulsion and hotel load, the total emissions would effectively double, highlighting the environmental impact of operating such a superyacht. When viewed in the context of the global superyacht fleet, these emissions highlight the importance of pursuing solutions that can mitigate carbon footprints.
HVO offers a promising solution for reducing emissions, with up to a 90% reduction in CO₂ emissions compared to diesel over its entire lifecycle. This includes emissions from sourcing and production (Well-to-Tank) to combustion in the engine (Tank-to-Wheel). The exact reduction percentage can vary based on factors such as feedstock type, production process, and specific supply chain emissions.
While HVO and diesel release comparable amounts of CO₂ during combustion, the key difference lies in the source of the carbon. HVO emits biogenic CO₂, which comes from plant-based materials that absorbed CO₂ during their growth. This creates a short-term carbon cycle, where the CO₂ released is reabsorbed through natural processes like photosynthesis. In contrast, the CO₂ from diesel combustion comes from fossil fuels—carbon that has been locked away for millions of years. Once released, this CO₂ remains in the atmosphere, adding to the long-term carbon load and contributing to climate change.
HVO’s lower carbon intensity is particularly evident in the Well-to-Tank stage, especially when sustainable, waste-based feedstocks are used.
By switching to HVO with a conservative 80% CO₂ saving (Well-to-Wheel), this superyacht could save approximately 1,026,000 kg of CO₂ annually—a reduction equal to the yearly emissions of about 141 EU citizens (with an average citizen emitting 7,259 kg of CO₂ per year). This saving is also comparable to the emissions from around 632 average European cars, each of which emits approximately 108.2 g of CO₂ per kilometre and drives about 15,000 kilometres per year.
The potential reduction in CO₂ emissions achieved by transitioning to HVO demonstrates the significant positive impact low-carbon fuels can have on the yachting industry’s overall carbon footprint. As more vessels adopt HVO, this shift could play a crucial role in advancing the sector’s decarbonization efforts.
Renewable and Sustainable Feedstocks: HVO is produced from renewable sources, primarily waste oils and fats, which significantly reduces our reliance on fossil fuels. It’s important to differentiate between primary (or virgin) feedstocks, like soybean or palm oil, and byproducts from waste materials. Virgin feedstocks require considerable land, water, and energy to produce, often leading to environmental concerns such as deforestation and competition with food crops. In contrast, byproducts like Used Cooking Oil (UCO) and animal fats are often discarded; using these materials not only minimizes waste but also reduces the need for new resources. This approach helps achieve greater carbon savings, as waste-derived feedstocks typically have lower lifecycle emissions. By prioritizing these more sustainable options, HVO production supports a circular economy, demonstrating a commitment to environmental responsibility while providing a cleaner energy solution. Yet the secondary status of the feedstock is critical for this to work as such.
Cleaner Emissions. When used in diesel engines, HVO produces much less air pollution compared to regular diesel. HVO can cut carbon dioxide emissions by up to 90% ( W-T-W, depending on its feedstock and production), reduce particulate matter by 26-46% and lower nitrogen oxides (NOx) by 9-14% [3]. Additionally, it contains no sulfur or PAH compounds, making it a cleaner alternative overall.
Compatibility with Diesel Engines: HVO can be used in existing diesel engines without modification, making it an immediately applicable solution for reducing emissions across the superyacht industry. This is particularly advantageous for the existing superyachts in the fleet, where environmental upgrades to engines can add cost and complexity. HVO might come at an upcharge in some countries, but more adoption of HVO will result in a lower cost. The yachting community can pioneer the uptake of HVO, for the larger society to benefit from increased availability and more competitive pricing.
Certification
The Renewable Energy Directive (RED), introduced by the European Commission in 2008, sets mandatory sustainability standards for biofuels, including HVO. These standards establish minimum requirements for reducing greenhouse gas emissions and guidelines for assessing the risks of Indirect Land Use Change (ILUC) associated with different feedstocks.
When first-generation biofuel are produced from crops grown on existing farmland, the demand for food and feed crops doesn’t disappear. This can lead to increased food production in other areas, potentially resulting in land use changes, such as converting forests into agricultural land, with deforestation, significant release of CO2 emissions and biodiversity loss as a result. For second-generation biofuels such as HVO, these are produced from non-food sources, like agricultural waste, wood chips, and other residual biomass. Since they do not rely on food crops, they typically have a lower impact on food supply and are less likely to drive land-use change for agriculture. However, if second-generation biofuel production scales up significantly, it could still indirectly influence land use by increasing demand for certain waste products or residuals, but this is still generally less impactful compared to first generation biofuel.
Certification for first-generation biofuel verifies that feedstocks are responsibly sourced, minimizing competition with food crops and reducing negative land-use impact like deforestation. It also verifies that the biofuel meets required GHG savings. For second generation biofuels, certification guarantees that feedstocks come from non- food, waste or residual sources, helping avoid land-use changes related to food production. It ensures transparency and traceability in the supply chain, proving that materials are sustainably sourced.
To verify that biofuels (both first and second generation) are truly a sustainable alternative to fossil fuels, RED II outlines specific criteria for the sourcing and environmental impact of biofuels sold in the EU. The key requirements under RED II are:
- Transport biofuels must achieve a greenhouse gas (GHG) savings of at least 65% compared to diesel.
- Biofuels used for electricity, heating, and cooling need to have a GHG savings of at least 80%.
Biofuel producers must obtain certification from an independent third party to demonstrate compliance with these standards. This certification process includes auditing the entire supply chain to ensure that sustainability and sourcing criteria are met. Additionally, producers and suppliers are required to submit regular reports to confirm ongoing compliance to the certification requirements and RED II regulations.
What does it mean for me as a superyacht owner or operator?
For superyacht owners and operators looking to purchase HVO fuel, it is essential to know what questions to ask suppliers when ordering HVO. Below are some key considerations for due diligence that yacht owners and operators should keep in mind or inquire about when sourcing HVO fuel:
Ask for a certification scheme recognized by the EU RED: There are several certification organizations that comply with RED II regulations and criteria. Some of the most well-known include the International Sustainability and Carbon Certification (ISCC), REDcert, and the Roundtable on Sustainable Biomaterials (RSB). These certifying bodies not only adhere to the standards set by RED II, but they also engage independent third parties to conduct audits and certify compliance with both RED II and their own certification schemes. By choosing certified suppliers, you can ensure a thorough audit of the supply chain that aligns with regulations and contributes to real CO2 savings.
Request impact assessment documentation: More biofuel producing companies are now focused on calculating the actual greenhouse gas (GHG) emissions across their entire supply chain using a full Life Cycle assessment (LCA) approach. This allows them to effectively communicate their environmental footprint to stakeholders and customers, as lower emission-intensity fuels are increasingly advantageous for business owners. By reviewing this information, one can gain insight into the GHG savings associated with their biofuels, as well as the potential Indirect Land Use Change (ILUC) impacts linked to their supply chain. A low ILUC risk suggests that the production of biofuels did not interfere with food production or encroach on ecologically sensitive areas like forests.
As we work towards the goal of net-zero emissions by 2050, the operation of yachts is evolving.
Using HVO can offer an immediate reduction in emissions and thus needs to be adopted widely by the industry.