A common definition for a sustainable additive has not been made. All additives to varying degrees contribute to sustainability.
Determination of whether an additive is sustainable can be conducted through a series of evaluation processes, including a sustainability impact assessment methodology followed by a life cycle assessment.
Sustainable lubricant additives are needed not just in environmentally sensitive applications but in most lubricant applications to improve efficiency.
The ongoing trend to sustainability is prompting lubricant manufacturers to determine how their products are sourced, manufactured, used and then hopefully recycled so they can continue to provide benefits even in a different application. This “cradle-to-cradle” approach provides the best opportunity for lubricant manufacturers to minimize their carbon footprint and achieve carbon neutrality.
The hopeful result is for lubricant manufacturers to contribute to a “Circular Economy.” A significant aspect in determining if a specific lubricant will contribute to carbon neutrality is to understand the sourcing and manufacturing of the raw materials used in the manufacturing process. While a good deal of attention has been paid to evaluating the carbon footprint of base stocks because they comprise the largest percentage of any lubricant formulation, additives also need to be taken into consideration because of the strong contribution they make to the performance of lubricants.
Additives need to be evaluated for sustainability both on the merits of their manufacture and how they are used to improve the functioning and durability of a specific lubricant. The second characteristic may be just as important because if an additive facilitates a significant improvement in the lifetime of a lubricant, this will improve its sustainability profile.
Insight on the current state of sustainable additives and what the future holds was obtained from the following individuals.
1.
Benn Heatley, Afton Chemical
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Dr. Min Chen, ANGUS Chemical Co.
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Dr. Gemma Stephenson, Cargill Bioindustrial
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Stephanie Cole, Clariant
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Joerg Simon, Infineum
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Jim Cancila, Ingevity
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Thomas Wolak, The Lubrizol Corp.
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Dr. Jun Dong, SONGWON Industrial Group.
Definition of a sustainable additive
Dr. Gemma Stephenson, technical marketing manager – performance technologies for Cargill Bioindustrial in Snaith, UK, indicates that there is no single definition for a sustainable additive but rather a range of views and opinions. She says, “In Europe, European Union (EU) policymakers for the Chemicals Strategy for Sustainability (CSS) envision that sustainable chemicals are ‘used and produced in such a way that maximizes their benefits to society while avowing harm to planet and people.’
1 The ambition of the European Commission is to support the transition to an economy where chemicals, materials and their use in products are safe and sustainable, taking consideration of the entire life cycle: production, use and end of life.”
Stephenson continues, “In taking this approach, industry must think beyond the intrinsic properties of additives (e.g., biodegradability, toxicity and bioaccumulation) and consider their use-phase and their ultimate-fate. The EU’s proposal framework, ‘Safe and Sustainable by Design (SSbD),’
2 is currently progressing through a consultation phase, with an expectation that the voluntary framework will be finalized in 2022. When published, this framework will provide the most comprehensive definition of safe and sustainable for chemicals (including lubricant additives) and materials.”
Joerg Simon, sustainability implementation lead for Infineum in Milton Hill, UK, agrees that there is no commonly agreed definition of a sustainable additive. He says, “Sustainable and non-sustainable is not as clear cut as some might think. Sustainability is a holistic view, not a rigid classification that limits sustainability to just a single specific market segment criterion. Additives are added to improve the application, and, in the case of lubricants, most are added to improve lubrication, e.g., reduce friction losses and increase durability. The statement can be made that all additives contribute in varying degrees to sustainability—some more, some less.”
Simon continues, “In seeking a suitable definition, the three aspects of sustainability (social, environmental and economic) must be taken into consideration. The focus should be on determining the impact of an additive across its life cycle, and evaluating the in-use benefits provided to a specific lubricant. In-use benefit analysis is particularly important because a specific additive may not have a better environmental footprint, but it may generate sustainability/environmental benefits through its use or enable more sustainable operation/application. An additive can be defined as sustainable where the in-use benefits outweigh the impact of the product itself, e.g., in terms of carbon footprint.”
Benn Heatley, sustainability leader of Afton Chemical in Bracknell, UK, believes the definition of a sustainable additive can be found through evaluation of three issues. He says, “The role of additives is to reduce emissions, improve fuel economy and extend engine and equipment life. Improving reliability and efficiency, while reducing the use of fossil fuels, can decrease the carbon footprint for the end-user and is critical in establishing sustainability credentials for a specific additive.”
Heatley continues, “Minimizing the overall carbon footprint through evaluation of the additive’s manufacturing process and supply chain also must be taken into consideration. A final factor in defining a sustainable additive is considering its environmental profile by eliminating chemicals of concern, considering bio-derived substances and their sources and increasing circularity.”
STLE member Thomas Wolak, industrial technology development manager for The Lubrizol Corp. in Wickliffe, Ohio, says, “Our definition of a sustainable additive includes minimizing the additive’s footprint compared to available alternatives while maximizing the handprint or performance of the finished lubricant to allow fluid suppliers to meet and exceed customers’ and other end-users’ performance and sustainability goals.”
STLE member Stephanie Cole, senior formulation chemist for Clariant in Mount Holly, N.C., believes that a sustainable additive must touch one or more of the three pillars of sustainability: people (social), planet (environmental) and performance (economic). She says, “The ideal additive would touch all pillars of sustainability, but working toward touching at least one is ideal. An additive is felt to be favorable toward the social pillar if it does not contribute to human hazard warning labels in the finished lubricant. Increasing energy efficiency, by reducing energy usage, would address the environmental pillar, and the improving lubricant performance meets expectations for the economic pillar. Multifunctional additives that contribute to less formulation complexity and help leave room in the formulation for cost-effective components also would be considered sustainable.”
STLE member Dr. Min Chen, global business manager – metalworking fluids for ANGUS Chemical in Buffalo Grove, Ill., defines a sustainable additive as being benign by design and encompasses the manufacture and use of efficient, effective, safe and environmentally responsible chemistry. He says, “In metalworking fluids, an example of a sustainable additive is one that extends the life of the lubricant and tools that use it. Another example is an additive that improves the overall labeling and sustainability scorecard of the finished lubricant.”
STLE member Jim Cancila, account manager for Ingevity in North Charleston, S.C., indicates that sustainable additives are derived from materials of biological origin. He says, “Essentially, these materials come from living organisms, capable of reproduction. Every definition of ‘sustainable’ excludes materials from fossil sources and/or geological formations. Any manufacturing or refining procedures are restricted to natural processes (for example, fermentation).”
STLE member Dr. Jun Dong, global technology manager fuels and lubricant additives (FLA) at SONGWON Industrial Group provides the following definition, “A performance enhancing additive for lubricants that can be sourced, manufactured, transported, utilized and disposed/recycled in sustainable ways.”
How to determine if an additive is sustainable?
To answer this question, Cole feels that it may be easier to determine if an additive is not sustainable. She says, “With all of the news of supply chain issues, global warming and social issues readily available, it is easier to determine what is not working. We can isolate why it is not working and determine what could work instead. Among the common buzzwords of green ingredients, bio-derived formulations, carbon-neutral or net-zero carbon, it is easy to get lost in the actual requirements and needs.”
Dong furnishes a list of five criteria for whether an additive is sustainable. He says, “An additive can be sustainable if it exhibits one or more characteristics that include the following:”
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The raw materials used to make the additive are from renewable resources or recycled.
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The manufacturing process utilizes green energy.
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The additive can help with fuel economy, thus reducing dependency on natural resources and cutting carbon dioxide emissions.
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The additive prolongs the useful life of lubricants, thus reducing the environmental impact of lubricants.
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The additive is biodegradable and environmentally friendly.
Chen offers a similar set of criteria for whether an additive is sustainable in the form of questions.
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Does the additive offer an improved environmental health and safety (EHS) profile compared to alternative chemistries that helps reduce hazardous exposure to workers/operators and reduce overall impact to the environment?
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Does the additive help enhance the sustainability performance of the fluid formulation such as extending fluid longevity, which reduces the total waste of finished lubricants?
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Can the additive better enable the formulation of biobased products by enhancing overall stability of formulation to create a fluid with an improved environmental/biobased profile while maintaining performance?
Cancila indicates that programs are available that define whether an additive is sustainable. He says, “These programs are voluntary, and not every additive supplier is required to use these resources. Examples include the USDA BioPreferred® Program and the EU Ecolabel.”
Wolak says, “When assessing the sustainability of an additive, a life cycle assessment (LCA) is performed, which includes a review of both its environmental footprint (for example, consumption of natural resources during the manufacturing process and any environmental impacts measured in carbon dioxide equivalents per kilogram [CO
2 equivalent per kilogram]) as well as the handprint (or performance benefits the additive enables in the finished lubricant).”
Heatley believes that taking a life cycle approach is important in assessing whether an additive is sustainable. He says, “The life cycle approach considers high priority topics such as carbon impact and broader topics including eutrophication, particulate matter and water consumption. This deep understanding of the additive allows proper consideration of its attributes and allows for continuous development. Studying broader topics such as circularity, responsible sourcing and end-of-life considerations also are important.”
Simon and Stephenson both cite the World Business Council for Sustainable Development (WBCSD) as establishing a framework for how sustainable performance of chemicals can be evaluated.
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Simon says, “The WBCSD framework can be tailored to fit the needs of the lubricant industry and translate relevant criteria into tangible parameters by taking into account the environmental footprint of the product, in-use benefits, market relevant criteria such as the regulatory environment and key stakeholder activities. It can be tailored to compare the products of specific lubricant additives, in particular, applications against a reference in several sustainability aspects such as climate impact, renewable materials and circularity. The same logic can be applied during product development by comparison to an existing product or similar baseline to ensure sustainability also is considered at this early stage of an additive’s life cycle.”
Simon reveals that the sustainability can change during an additive’s useful lifetime, which means there is no guarantee that a highly sustainable additive introduced at a specific time will be rated in this manner over time. An example is additives that enable fuel economy. He says, “Consider an additive that delivered fuel economy improvements of 1%, which was seen as a more sustainable solution. Nowadays, the market requires a fuel economy performance of 3% and more, which means that this additive delivering 1% fuel economy improvement is less sustainable.”
Stephenson says, “In the absence of agreed definitions or prescribed sustainability frameworks for innovation, companies are adopting their own ‘in-house Portfolio Sustainability Assessments (PSAs)’ to accompany new product development, and scorecards are becoming commonplace to help assess the sustainability credentials of products during the product design phase. Forward-thinking companies are acting now and integrating the fundamental principles of the SSbD initiative into their corporate and research and development strategies.”
Stephenson continues, “Determining if an additive is sustainable should be conducted through a series of evaluation processes starting with an initial sustainability impact assessment (SIA) methodology for scoring and comparing products against various sustainability metrics, followed by advancement to widely recognized LCAs. This process helps to guide internal decision-making through a new product development process but is only one consideration. An ideal design also must take into consideration the creation of products that can be suitably reused or recycled at the end of their useful life. For lubricant additives, however, creating circularity can be challenging to impossible. Additives are typically included at low levels in finished lubricant formulations, and it can be generally assumed that their fate is part of a linear economy; they may be consumed during the use phase of the lubricant; destroyed during a re-refining phase; or they can be burned when the lubricant is collected and incinerated, in order to generate heat or electricity.”
The aim in developing and commercializing a new additive is to hit the “sweet spot” among sustainability, safety and performance according to Stephenson
(see Figure 1). This is the objective of SSbD.
Figure 1. The objective of the “Safe and Sustainable by Design” (SSbD) initiative is to hit the “sweet spot” among sustainability, safety and performance. Figure courtesy of Cargill Bioindustrial.
Stephenson says, “Intrinsic hazards of a specific additive should be minimized while simultaneously maximizing the additive’s in-use benefits. Performance benefits to be evaluated include improved energy efficiency, reduced greenhouse gas (GHG) emissions and improved durability, while maximizing safety and sustainability credentials. The lubricant manufacturer and end-user also should be considered when a new additive is developed.”
One example given by Stephenson is for corrosion inhibitors that can provide excellent performance benefits, but some types may be classified as dangerous for the environment and may pose a threat to human health. She says, “In many applications, the risk associated with using harmful additives is mitigated by the fact that they are used in a controlled manner, with little to no opportunity for human or environmental contact, if used correctly.”
Strong need for sustainable additives
After providing a definition for sustainable additive and determining a process for whether a specific component used in a lubricant formulation is sustainable, the contributors were asked to identify in which lubricant applications is there a strong need for such an additive.
Cancila says, “All lubricant applications have a need for sustainable additives. However, there are situations where the lubricant is consumed, rather than being contaminated and reused. Lubricant applications that do not contain and reuse the lubricant, such as wire rope dressing or roller chain fluids, should be prioritized for sustainable formulations.”
Heatley highlights electric vehicles and wind turbines as two high-profile examples where sustainable additives can facilitate the development of technological advances required to meet the world’s challenges. He says, “Beyond these new applications, the world still needs to keep moving, which means that existing machines and vehicles, such as existing vehicle fleets and heavy-duty applications, also will require continuing focus. In all areas of lubricants, many stakeholders have an increasing desire to see continually improving products and services. The need for sustainable additives is across the industry and at all levels of the supply chain.”
Stephenson believes there are applications where sustainable additives are justifiably inescapable such as when used lubricants are utilized in environmentally sensitive areas where there is the risk of leakage to the environment. An example is vehicles operating in agricultural or forest environments will be better served by lubricant additives with minimal effect on the surrounding ecosystems.
Stephenson says, “Today, there are schemes in place that provide more prescriptions and/or limitations as to what can and cannot be used, including but not limited to the Convention for the Protection of the Marine Environment of the North-East Atlantic (OSPAR), Vessel General Permit (VG) and the European Ecolabel for Lubricants. The latter is a voluntary scheme that rewards products and services for having a reduced impact on the environment, and Ecolabel approval is achieved through a verification process, usually referred to as a “certification.” Lubricant products satisfying the Ecolabel must be biodegradable, have low aquatic toxicity and bioaccumulation potential and must be sustainable sourced. While these initiatives promote the use of less toxic substances in environmentally sensitive areas, they do not make any end-of-life commitments regarding the fate of a specific lubricant and the components contained in its formulation.”
Cole says, “Initially, applications with lubricants formulated at high-additive treat rates, possible spillage or environmental contamination and higher fluid changeover will have a strong need for sustainable additives. Examples include compressor fluids, gear oils, greases, hydraulic fluids, metalworking fluids and transmission fluids. Eventually, all industrial lubricant applications will require only sustainable additives.”
Wolak indicates that environmentally acceptable lubricants get much of the attention at this time, mainly because of existing regulations that are either voluntary or enforceable. He says, “The main lubricant applications in environmentally sensitive areas are industrial in nature and are usually bio-derived: hydraulic fluids, industrial gear oils and chain saw oils.”
Simon states that all lubricant applications that increase efficiency are in need of more sustainable additives. He says, “This is true for mature applications such as automotive engine oils and more recent ones such as electric vehicle fluids and for future applications. Efficiency increases can be achieved in various ways, e.g., through using lower additive treat rates or using additives in lubricants that display greater durability. For example, increasing fuel economy is a sustainable contribution and so is the extension of the lifetime of a heavy-duty engine. While battery electric power may emerge as more of a major contributor to automobiles, additives that can contribute to reducing frictional losses and/or destructive processes in internal combustion engines by reducing the amount of fuel not burned now and optimizing energy consumption will be sustainable. They can facilitate the reduction in GHG emissions and limit global temperature rise. Existing lubricant applications will be around for some time, and improvements must be made to move toward sustainability while waiting for future technologies to be applied more broadly and others to be commercialized.”
Simon continues, “Specific lubricant applications exist where certain sustainable attributes are required. For example, the lubricant used in chain saws will be released into the environment during use. In this case, aspects of no harm occur in the environment during use, and biodegradability requirements play a very specific role.”
Chen says, “There is strong need to reduce waste, minimize hazard exposure and develop environmentally responsible lubricants in total-loss and partial-loss applications, as well as accidental loss lubricants, such as metalworking fluids and hydraulic fluids.”
Dong lists three applications that require sustainable lubricant additives. He says, “Automotive lubricants due to their sheer volume. Marine and forestry machinery lubricants due to their use in environmentally sensitive areas.”
Sustainable versus environmentally friendly
One aspect of a sustainable additive that can be confusing is whether it needs to be environmentally friendly. Drawing a distinction between the two terms can be challenging.
Stephenson says, “This question pre-supposes that there are well-defined meanings for environmentally friendly and biobased additives. It is generally understood that ‘environmentally friendly’ refers to additives that impart minimal or no harm upon the environment. But to make such a claim, a point of reference is required, be that tests by which additives are assessed, or the quantity in which they are used. Several schemes apply substance exclusions and limitations based on human and environmental hazards, and some include a positive list such as the European Ecolabel Lubricant Substance Classification List (LuSC).”
Stephenson continues, “Biobased additives are derived from living organisms or biomass, e.g., crops, wood or algae. There is no guarantee that the raw materials used in producing these additives or these additives themselves are sustainable. As an example, biobased materials that are grown on areas of deforestation or on land defined as critical for human food consumption should not be considered sustainable, as the overall environmental benefit can be considerably worse than leaving the land area unchanged.”
As shown in Figure 2, one approach for working with sustainable and environmentally friendly is to find a “sweet spot” among these two terms and biobased. Stephenson says, “The three terms in Figure 2 can be closely linked but are independent concepts. A sweet spot among the three terms can be reached, but these concepts are not necessarily mutually inclusive.”
Figure 2. Sustainable, environmentally friendly and biobased are independent concepts that may not necessarily be linked together. One approach for working with all three terms is to find a “sweet spot” for a specific additive. Figure courtesy of Cargill Bioindustrial.
With the lack of definitions or standards for these terms, Simon believes that sustainable moves beyond environmentally friendly to include people, planet and profit. He says, “This can range, e.g., from making sure the additive is produced in a safe way and limiting the use and exposure of highly hazardous substances, especially to non-professionals, to the avoidance of child labor in the whole supply chain.”
Simon contents that “biobased” on its own does not make for a sustainable additive. He explains, “A biobased raw material might need a different, higher carbon intensive processing or might not be recyclable, and, at the bottom line, even when you take the GHG benefits into the account as the raw material is made, the LCA might be worse than a non-biobased alternative. Other parameters such as water consumption also must be taken into consideration.”
Heatley believes that it is important to not focus on one feature or metric when considering terms such as sustainable and environmentally friendly that have unclear or varying definitions. He says, “Continuing the journey toward sustainable lubricant additives will require careful consideration of many factors from where the raw materials are sourced (biobased or otherwise), to where and how they are manufactured. Other factors include how the end-user utilizes the finished lubricant and end-of-life treatment. All along the life cycle, potential impacts require consideration and careful balance. Only through dedicated R&D, extensive engagement with stakeholders and detailed life cycle analysis can all the aims of a sustainable additive be met.”
Chen says, “A sustainable additive can be derived from raw materials that are not categorized as ‘environmentally friendly’ or biobased but can improve the overall sustainability scorecard of a formulation by extending fluid longevity to reduce waste or improving the overall carbon footprint of the finished lubricant.”
Chen continues, “A sustainable additive also can take into account the impact reduction along the life cycle of the additive (e.g., manufacture, use and disposal). Since an environmentally friendly raw material implies it is not harmful to the environment and a biobased component is derived from renewable, carbon-based biological sources, both can contribute to a specific lubricant additive’s overall sustainability profile.”
Dong says, “Sustainable additives refer to a wider range of products that show sustainable characteristics for their entire life cycles. Biobased or environmentally friendly additives can be sustainable.”
Cancila draws a distinction between an environmentally friendly and a sustainable additive. He says, “It is possible for an additive to be ‘environmentally friendly’ but not sustainable. An environmentally friendly additive may be non-toxic and biodegradable but not derived from a sustainable source.”
Cole gives an example of a biobased additive that is not sustainable and a non-biobased additive that is sustainable. She says, “The production of palm oil has involved the destruction of animal habitats in order to grow palm trees. This is not a sustainable solution, and organizations such as the Roundtable on Sustainable Palm Oil (RSPO) have been established to ensure palm oil production is more sustainable. An ethoxylated amine, prepared from non-biobased components, is a sustainable additive because it helps to improve metalworking fluid durability in a recirculating system. The result is that an end-user should realize lower operating and fluid disposal costs and should benefit from greater productivity due to lower downtime.”
Wolak indicates that a sustainable additive can be environmentally friendly, but there are examples where an environmentally friendly additive can have a larger carbon footprint and not be that sustainable. He says, “Often additive and base oil attributes required to meet environmentally friendly status (biodegradable, non-toxic, non-persistent in the environment, etc.) take precedence over the LCA value in terms of carbon dioxide equivalents per kilogram of the finished lubricant. Therefore, an environmentally friendly lubricant could have a larger footprint and contribute more carbon dioxide equivalents per kilogram compared to conventional lubricants.”
Sustainable but not biobased
Distinguishing between sustainable and biobased is an important issue because there are additives used that are not derived from biobased raw materials yet can be considered sustainable.
Wolak says, “Biobased raw materials are not always the most sustainable from a LCA perspective. For example, synthetic esters may be bio-derived, but the energy intensity used to make an ester base stock is usually much higher compared to a Group I or Group II derived base oil especially when scale of the operation is a major factor.”
Figure 3 shows a decision tree that can be used to not only determine if a sustainable lubricant is needed for a specific application but also distinguishes between biolubricants and non-biolubricants.
Figure 3. A decision tree approach for determining if a sustainable lubricant is required for a particular application and how to distinguish between whether a biolubricant or a non-biolubricant should be used is shown. Figure courtesy of The Lubrizol Corp.
Cancila states that an additive that does not meet the definition of sustainable may contribute to the overall sustainability of a lubricant or a process. He explains, “This point is illustrated routinely in metalworking fluid applications. The concept of sustainability is being translated into ‘sustainability plans’ with specific goals by many lubricant end-users. Additives that extend the useful life of a metalworking charge contribute toward achieving the sustainability goals of the end-user. Extending metalworking fluid ‘sump life’ achieves many sustainability goals.”
Heatley feels that in determining whether an additive is sustainable, a balanced approach will often need to consider the nature of the raw materials, the product life cycle and the product’s overall performance. He says, “Sourcing biobased raw materials is one way a product’s carbon impact can be reduced across its life cycle. However, there is rarely a single solution to every issue or a one-size-fits-all approach. Biobased raw materials are not without their challenges. Careful consideration must be made to ensure that prioritizing biobased feedstocks does not unintentionally compromise the wider environment. When using alternative products, it also is important to thoroughly explore their effectiveness and efficiency.”
Simon believes that evaluating the ability of an additive to be circular and act to enable more sustainable applications are two other strategies that can be used in determining sustainability without relying on whether the additive is biobased. He says, “Examples of additives that enable sustainability are those that maximize in-use benefits such as fuel economy and extending oil drain intervals. An essential element of sustainability is circularity or the circular economy, i.e., reusing and extending the lifetime of materials and products for as long as possible. Re-refined base oils, as an alternative for virgin base oils, represent one example since base oils make up a part of modern additive components and a substantial part of finished formulations. Converting components present in waste streams for use in additives or additives at the end of life in one application into another application are additional examples of sustainability.”
Chen indicates that non-biobased additives are widely used today to improve the sustainability profile of a lubricant by extending the fluid longevity, or improving the compatibility of the fluid for recyclability to reduce the overall waste. He says, “The use of lubricants formulated with non-biobased additives can facilitate highly efficient manufacturing processes that lead to less waste and strain on natural resources. Biobased additives used in lubricants are from renewable sources and are biodegradable but, frequently, they do not display the performance requirements needed particularly from the standpoint of oxidative stability. This issue has been investigated for more than 50 years, and higher total costs from the economic and environmental standpoints can be found in using biobased additives compared to non-biobased alternatives.”
Stephenson says, “Figure 1 outlines the basic design profile for developing a specific additive based on safety, sustainability and performance. Performance is normally well-defined with regards to what is expected of the additive and the lubricant in which it is included, be that energy efficiency, lubricant lifetime or equipment durability. If higher performance and, therefore, greater environmental benefit can be derived from using petrochemical raw materials, then the impact of petrochemically derived additives can be considered a step forward in terms of sustainability compared to alternatives.”
Stephenson also believes that “biobased” does not translate to “100% biobased.” She explains, “There are many examples of additives that are derived from a combination of both biobased and petrochemical raw materials, the raw materials being chosen to derive the maximum performance from the additive.”
Examples of sustainable additives
Dong indicates that a primary aromatic amine antioxidant is a good example of a sustainable additive. He says, “As shown in Figure 4, this additive exhibits a low global warming potential of 2 kilograms of carbon dioxide equivalent per 1 kilogram of product. There are zero impacts to environmental areas including photochemical oxidation, abiotic depletion, acidification, eutrophication and ozone depletion potentials.”
Figure 4. The low global warming potential for a primary aromatic amine antioxidant is an indication that this component is a sustainable additive. Figure courtesy of SONGWON Industrial Group.
The major contribution to global warming potential for this additive is the raw materials used in its manufacture with the rest coming from the energy used. Dong says, “Utilization of primary amine antioxidants to prolong the useful life of lubricants and extend drain intervals demonstrates how this additive type can be sustainable by reducing crude oil consumption and minimizing the environmental impact incurred from disposal.”
Another example showing how extending the life of a lubricant makes an additive sustainable comes from the use of alkanolamines in metalworking fluids. Figure 5 shows how seven amines (AMP, 4AA, AB/AEPD, DGA, MIPA, MEA and TEA) and sodium hydroxide (NaOH) effect the life of a metalworking fluid over time in weeks. Three of the amines display double the operating life compared to the other additives.
Figure 5. Three amines demonstrated the characteristics of a sustainable additive in a microbial challenge test when formulated into a metalworking fluid. The three amines are 2-amino-2-methyl-1-propanol (AMP); a blend of 2-amino-2-methyl-1-propanol, 2-amino-1-butanol, 2-amino-2-ethyl-1,3-propanediol and 2-amino-2-methyl-1,3-propanediol (AA); and a blend of 2 amino-1-butanol (AB) and 2-amino-ethylpropanediol (AEPD). The other candidates tested included monoisopropanolamine (MIPA), diglycolamine (DGA), monoethanolamine (MEA), sodium hydroxide (NaOH) and triethanolamine (TEA). Figure courtesy of ANGUS Chemical.
Chen says, “Three of the amines listed in Figure 5 can be considered to have a higher sustainability profile due to their ability to improve the longevity of metalworking fluids and reduce waste.”
Cancila states that a carboxylic acid dimer shows sustainability by providing improved corrosion and rust inhibition, enhanced emulsion stability and increased lubricity in metalworking fluids. Figure 6 illustrates the performance of the carboxylic acid dimer versus other carboxylic acids in reducing the staining of 7050 aluminum. He says, “Wettability of metal surfaces enhances metalworking fluid lubricity. As shown in Figure 7, the carboxylic acid dimer produces better wettability through lower contact angles than other carboxylic acids.”
Figure 6. A carboxylic acid dimer displays superior performance compared to three other carboxylic acids in reducing staining on 7050 aluminum. Figure courtesy of Ingevity.
Figure 7. The wettability of a carboxylic acid dimer as measured by contact angle is superior to two other carboxylic acids on one carbon steel, three aluminum and two copper alloys. Figure courtesy of Ingevity.
Stephenson considers esters to be a good example of sustainable additives that offer a variety of functions. She says, “Esters can be designed so that they are inherently environmentally acceptable or ‘intrinsically sustainable.’ Many are highly biodegradable, non-toxic and non-bioaccumulative, making them excellent technologies for use in environmentally sensitive areas, where lubricant leakage may be a concern.”
A second example offered by Stephenson is friction modifiers that have excellent built-in sustainability credentials (for example, a low carbon footprint) and bring outstanding benefits in use. She says, “Friction modifiers have long been used in engine oil formulations to deliver low levels of boundary and mixed lubrication friction and, thereby, better fuel economy, which translates into reduced or avoided carbon dioxide emissions from passenger cars.”
Cole feels that polyalkylene glycols (PAGs) are a good example of a sustainable additive. She says, “PAGs exhibit superior lubricating properties, corrosion protection and work with other lubricant additives to lower energy cost at end-user facilities.”
Heatley furnishes two examples of lubricant applications that will be using sustainable additives. He says, “New technologies are rapidly being developed to enable the electric vehicle market growth to help reduce carbon emissions. The need for future lubricants to consider conductivity, the effect of electric fields, low friction/high speed, noise and battery cooling or copper wire drawing are performance attributes to consider.”
A second example is wind turbine oil solutions that reliably support the growing renewable energy market. Heatley says, “Wind turbine manufacturers and gearbox suppliers can achieve more efficient output and productivity with the right additives. With many countries turning to wind energy as an alternate electricity source, the demand for efficient and reliable lubrication will continue to grow.”
Simon points to efforts that are continuing to balance lubricant additive packages to maximize the performance of finished lubricants. He says, “In my view, an additive package and a final oil formulation need to be seen as one, as this is the final application. As the majority of a lubricant is base oil, changing the sustainability credentials of this component might have a bigger impact on the sustainability of the finished lubricant than most changes done to additives. With a lubricant additive package, the right balance of all components is vital. Many components in the additive package contribute to the sustainability performance of the finished lubricant. For example, antiwear additives protect surfaces to extend the lifetime of the engine. While the focus of in-use improvements to the additive package is to increase performance, the potential impact on the social, environmental and economic aspects must be kept in mind to find the right balance.”
Wolak indicates that sulfurized vegetable oils are an example of a sustainable additive. He says, “These additives contain renewable carbon content and improve the lubricant’s handprint by providing excellent extreme pressure and antiwear (EP/AW) performance to extend tool life and surface finish in metal-removal processes.”
Effectiveness of sustainable versus non-sustainable additives
Simon considers sustainability to be not as simple as determining whether additives are sustainable or non-sustainable. He says, “An additive is more or less sustainable depending among others upon its benefits in the application and environmental footprint. If a discussion about sustainability is limited to just the carbon footprint, then there is little difference in the technical performance between less sustainable and more sustainable additives at this stage. Additive solutions are created to deliver a certain performance that can be reached with more or less sustainable solutions. Looking forward, a better understanding of any dilemma that might occur between rising technical and sustainable expectations must be realized to find the optimal balance of technical and sustainability performance meeting future requirements. These dilemmas might arise from higher technical performance requirements or more sustainable solutions that are less effective.”
Stephenson states that the priority factor in designing an additive is performance, whether the specific component is sustainable or non-sustainable. Biobased additives can provide good performance not because of their content but because their in-use benefits are maximized.
She says, “An increasingly competitive advantage stems from designing more sustainable solutions, perhaps using biobased raw materials or more efficient production processes, but which maintain or increase performance benefits. The age-old perception can be that a biobased additive will be less effective than its petrochemically derived counterpart, but defining what this means needs to be clarified. It could be due to function, or due to the same molecule being produced from both biobased and petrochemically derived raw materials.”
Stephenson continues, “Currently, the biobased raw material portfolio is limited, and the choice of naturally derived building blocks available to lubricant formulators is small. However, it is rapidly widening, and it is hoped there will soon be a broader offering of biobased raw materials that can be used as drop-in replacements for petrochemical building blocks, as well as more unique building blocks found in nature. A good example is ethylene oxide, a key precursor to many additive components in lubricant formulations. Ethylene oxide has traditionally been produced from petrochemical resources but can now be produced using bioethanol to make 100% biobased emulsifiers, wetting agents and dispersants with no sacrifice in performance.”
Specific needs for sustainable additives
Wolak gives two examples of specific needs for sustainable additives. He says, “Additive chemistry is required to unlock the performance of sustainable base oils in order to first meet industry, OEM and end-user performance requirements and second to meet sustainability goals as measured by improved LCAs versus conventional lubricants.”
Cancila also feels that sustainable additive needs are linked to the properties of base oils. He says, “The biggest formulation component need for sustainable material is base fluids. An assessment of the capabilities of and chemistry of the base fluid must determine what other additives will be required in a specific formulation.”
Chen lists four examples of areas where sustainable additives are needed.
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Extend metalworking fluid life to reduce waste
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Additives to improve worker health through reducing exposure to hazardous components
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The need to improve formulation and stability of plant-based lubricants
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Sustainable additives for use in food-grade lubricants, total-loss lubricants and one-time-use lubricants.
Dong states that antioxidants and friction modifiers are two additive types that contribute sustainability to lubricants. He says, “Antioxidants prolong the useful life of lubricants and extend drain intervals, thus effectively reducing crude oil consumption and minimizing the environmental impact of disposal. Friction modifiers improve fuel economy in automotive lubricants, reducing energy consumption and carbon dioxide emissions.”
Stephenson says, “Within an industrial setting, additives are needed to deliver crucial in-house benefits such as greater efficiency, maximizing output, reducing equipment downtime, conserving energy and reducing waste (rejected components). These concepts are central to a large number of market sectors including electric vehicles, wind turbine gearbox lubricants, manufacturing and high temperature chain oils. Formulators are increasingly keeping these issues in mind because they are now starting to prioritize the sustainability credentials of their products.”
Simon believes that the development and selection of additive components need to follow specific sustainable deliverables, including increasing energy efficiencies, and for use in lubricants with known release to the environment. He says, “Categories that involve boosting energy efficiency (such as increasing fuel economy improvement expectations) and where the needs and lifetime of products and materials can be optimized (use less, reuse, recycle and biobased), are the ones that can make the biggest contribution to a more sustainable world. Additional examples are lubricants that enable more sustainable applications (such as e-fluids) and those that can be directly released to the environment (for example, chain saw fluids).”
Future use of sustainable additives
Heatley says, “Stakeholders throughout the lubricant value chain are likely to continue striving to improve the sustainable credentials of additives and lubricants. New additive technologies will be needed to meet the world’s future challenges to continue reducing emissions, improving fuel economy and extending engine and equipment life. These challenges have the potential to offer great opportunities to meet and exceed the needs of end-users and OEMs.”
Simon highlights the role that end-users and OEMs are taking in raising their sustainability ambitions as leading to the growth in the use of sustainable additives. He says, “With the majority of industries and industry stakeholders setting GHG reduction targets, supplier expectations and net-zero ambitions as a means to move toward sustainability, additives will play a vital role. Demand for more sustainable additives is anticipated to grow significantly in the future, especially the ones impacting carbon emissions positively. This driver will occur through circularity, energy efficiency improvements, extending product and material lifetime or enabling more sustainable applications. Additional applications will accelerate growth in the use of sustainable additives through specific criteria such as biodegradability and ecotoxicity.”
Stephenson points out that the past objective of developing additives, base oils and finished lubricants based on performance will not be sufficient, and there will be a greater push toward additives that also do not compromise on safety and sustainability aspects. She says, “Companies in the EU are beginning to weave elements of the SSbD and other anticipated initiatives into their product development processes as implementation will be taking place in the near future. Innovation to find the ‘sweet spot’ among safety, sustainability and performance
(see Figure 1) is now being accelerated.”
Stephenson continues, “The entire lubricants value chain is on a journey toward sustainable growth through better use of resources and the materials that make up lubricant formulations used today. Demands from end-users intertwined with tightening legislation to meet climate ambitions are forcing OEMs and the rest of the value chain to rethink and redesign their products to fit the new sustainability agenda.”
Dong says, “Demand for sustainable additives is expected to rise due to more stringent legislation, customer demands, industry trends and growing public awareness for sustainability. Applications where sustainable additives will be needed are automotive lubricants, environmentally friendly lubricants and fuels, including biofuels.”
Chen says, “With the growing concern around the sustainability profile of the individual components as well as the overall formulations themselves, formulators, manufacturers and end-users are increasingly focused on the use of sustainable additives and lubricants. Their use will be accelerated in total-/partial-loss fluid applications, food-grade lubricants and medical device manufacturing.”
Cancila says, “Corporate sustainability plans are gradually defining sustainability initiatives for larger lubricant and metalworking fluid end-users. Optimized management of lubricants and metalworking fluids are more valuable at this point than the use of sustainable additives. Lubricant formulators and end-users will ultimately judge the measurable benefits of sustainable additives to the application and ‘cost of use.’”
Wolak says, “The call to a more sustainable future is here. Whether that means using existing additive chemistry to enable increased usage of sustainable base stocks or simply lowering the footprint of additive chemistry in general, fluid marketers and governments are setting expectations and goals to reach sustainable targets now and in the future. As a result, sustainable lubricants are forecasted to grow significantly faster than conventional lubricants.”
The growing use of sustainable additives will be spurred by end-users and regulations. This will lead to a systematic move toward lubricant additives that cannot only demonstrate the required performance to meet specific application requirements but also meet criteria that are being established for sustainability.
REFERENCES
1.
Chemicals Strategy for Sustainability Towards a Toxic-Free Environment, Annex to the European Green Deal, COM (2020), 667 Final, Oct., 14 2020.
2.
Caldeira, C., Farcal, R., Moretti, C., et al., (2022), “Safe and sustainable by design chemicals and materials: review of safety and sustainability dimensions, aspect, methods, indicators and tools,” European Commission, Joint Research Centre.
3.
Chemical Industry Methodology for Portfolio Sustainability Assessments (PSA), WBCSD, April 2018.