Palm Oil
Explore palm oil production across the world and its impacts on the environment.
In a large-scale consumer survey across the UK population on the perceptions of vegetable oils, palm oil was deemed to be the least environmentally friendly.1
It wasn’t even close. 41% of people thought palm oil was ‘environmentally unfriendly,’ compared to 15% for soybean oil, 9% for rapeseed, 5% for sunflower, and 2% for olive oil. 43% also answered ‘Don’t know,’ meaning that almost no one thought it was environmentally friendly.
Retailers know that this is becoming an important driver of consumer choices. From shampoos to detergents and from chocolate to cookies, companies are trying to eliminate palm oil from their products. There are now long lists of companies that have done so [Google ‘palm oil free’ and you will find an endless supply]. Many online grocery stores now offer the option to apply a ‘palm-oil free’ filter when browsing their products.2
Why are consumers turning their back on palm oil? And is this reputation justified?
In this article, I address some key questions about palm oil production: how has it changed, where is it grown, and how has this affected deforestation and biodiversity? The story of palm oil is more complex than it is often portrayed.
Global demand for vegetable oils has increased rapidly over the last 50 years. As palm oil is the most productive oil crop, it has taken up a lot of this production. This has had a negative impact on the environment, particularly in Indonesia and Malaysia. But it’s not clear that the alternatives would have fared any better. In fact, because we can produce up to 20 times as much oil per hectare from palm versus the alternatives, it has probably spared a lot of environmental impacts from elsewhere.
Palm oil production has grown to meet rising demands for vegetable oils
Palm oil production has increased rapidly since the 1960s. Between 1970 and 2020, the world’s production of palm oil increased by about 40 times. Global production went from only 2 million tonnes to around 80 million tonnes. The change in global production is shown in the chart.3
The story of palm oil is less about it as an isolated commodity and more about the rising demand for vegetable oils. Palm oil is a very productive crop; as we will see later, it produces over a third of the world’s oil but uses less than a tenth of croplands devoted to oil production. It has, therefore, been a natural choice to meet this demand.
Who uses palm oil, and what is it used for?
Why has the market for palm and vegetable oils more broadly increased so rapidly? What is it used for?
Palm oil is very versatile and is used in a range of products across the world:
- Foods: over two-thirds (68%) is used in foods ranging from margarine to chocolate, pizzas, bread, cooking oils, and food for farmed animals;
- Industrial applications: 27% is used in industrial applications and consumer products such as soaps, detergents, cosmetics and cleaning agents;
- Bioenergy: 5% is used as biofuels for transport, electricity, or heat.
While food products dominate globally, this breakdown varies from country to country. Some countries use much more palm oil for biofuels than others. In Germany, for example, bioenergy is the largest use, accounting for 41% (more than food at 40%). A push towards increased biofuel consumption in the transport sector has been driving this, despite it being worse for the environment than normal diesel (more on this later).
In the next section, we will look at what countries produce palm oil, but here, we see a map of palm oil imports. Although production is focused in only a few countries across the tropical belt, we see that palm oil is an important product across the world.
Where is palm oil grown?
Oil palm is a tropical plant species. It thrives on high rainfall, adequate sunlight, and humid conditions – this means the best growing areas are around the equator.4 Palm oil is therefore grown in many countries across Africa, South America, and Southeast Asia. In the map, we see the distribution of production across the world.
Small amounts of palm oil are grown in many countries, but the global market is dominated by only two: Indonesia and Malaysia.
In the chart, we see the production of the palm oil plant across a number of countries. Other producers include Thailand, Colombia, and Nigeria. As we’d expect, all of these countries lie along the zone of ‘optimal conditions’ around the equator.
How has land use for palm oil changed over time?
How has the world achieved such a rapid expansion of palm oil production? There are only two ways in which we can produce more of a given crop: increase yields (growing more on a given amount of land) or expand the amount of land we use to grow it.
Global palm oil yields have increased over time but are far short of the increase in demand. This means that over the last 50 years, the amount of land devoted to growing palm oil has greatly increased. In the chart here, we see the change in land use. Between 1970 and 2020, the land the world uses to grow palm has increased by almost ten times, from 3 million to almost 30 million hectares. Indonesia and Malaysia account for around 70% of global land use for palm oil. This is relatively little, considering that these countries account for more than 80% of production. This is because both countries achieve high yields.
Shown in the chart is the amount of land that the world devotes to vegetable oil crop production. Palm oil accounts for a small slice of this land use, which is notable when we consider that it produces the largest share of the oil.
Is palm oil responsible for deforestation?
Land use to grow palm has increased significantly since 1970. But has this expansion come at the expense of tropical forests?
This seems like a simple question, but it is not as straightforward as we might expect. The IUCN (International Union for Conservation of Nature) Oil Palm Task Force conducted an in-depth review of the literature to understand the impact of palm oil on deforestation.5 There was a lot of variability in the results, depending on how a forest was defined, the geographic focus of the analysis, and the timeframe that was considered.
Having done my own review of the literature, I conclude that palm oil has been a significant driver of tropical deforestation, especially in Southeast Asia.
Some studies suggest that palm oil has played a very small role in global forest loss. One study suggests that palm oil is responsible for around 2% of global tree loss.6 Another suggests it is responsible for only 0.2% of intact forest loss.7 This seems very low. But there are a couple of caveats to these figures. Firstly, they measure forest loss, which combines both permanent deforestation (where trees do not regrow) and forest degradation (which is a temporary thinning of forests with subsequent regrowth). As we discuss in our related article on this, deforestation accounts for just one-quarter of global tree loss. Palm oil’s contribution to deforestation – which has greater environmental impacts than degradation – would be higher.
Secondly, the 0.2% figure is based on intact forest loss. Intact forests are a specific subset of primary forests, which are very rich sites of biodiversity and are largely undisturbed by human activity. Only 6% of global intact forest is in Southeast Asia, the hotspot of palm oil expansion. Only 2.8% was in Indonesia, and 0.2% in Malaysia. So, even if all of these countries’ forests were wiped out by palm oil plantations, it would still make very little difference to this metric of global intact forest loss. The authors of the original study make it clear that intact forest loss should not be confused with primary forest loss.
So, how much of palm oil’s expansion has really come at the expense of forests? Let’s focus on the two key countries driving production: Indonesia and Malaysia. In the chart here, we see the drivers of deforestation in Indonesia from 2001 to 2016.8 Oil palm plantations were the largest driver of deforestation over this period, accounting for 23%. However, we also see that its role has declined over the last decade: there was a peak in 2008–2009 when it reached almost 40% of Indonesia's deforestation, but it has since declined to less than 15%.
Part of what makes this question so challenging to answer is that it depends on whether you only consider palm plantations, which immediately and directly replaced existing forests, or whether you include plantations that very quickly replaced forests that had been logged for wood, paper, and pulp. In a paper published in Nature, David Gaveau and colleagues (2016) used satellite imagery to assess what types of land industrial plantations replaced in the Borneo region.9 Industrial plantations include palm oil and pulpwood tree plantations but are dominated by the former.
This is shown for the Indonesian and Malaysian Borneo in the chart.
75% of these plantations were grown on land that was previously forested in 1973. Not all of these plantations were the direct drivers of this replacement. In fact, only one-quarter of post-1973 plantations in Borneo were driven by the rapid conversion of this land to plantations (20–21% oil palm; 4.3–4.8% pulpwood). This is shown in green in the chart. Direct deforestation for palm oil played a larger role in Malaysia; 60% was driven by plantations, whilst in Indonesia, it was only 16%.
This study only looks at the Borneo region. However, this is reasonably consistent with studies that have looked at the expansion of palm plantations more broadly. A global study of palm-driven deforestation found that in Southeast Asia, 45% of oil palm plantations came from areas that were forests in 1989.10 In Indonesia, this was 54%, and in Malaysia, 40%.
These distinctions in how quickly palm oil plantations replaced forests make it difficult to give a clear, single number on how much deforestation it has caused. But, most of the research concludes that, particularly in tropical forests in Southeast Asia, palm oil expansion has played a significant role.
Palm oil versus the alternatives
Palm oil has been an important driver of deforestation. But would the alternatives have fared any better?
There are a couple of reasons why palm oil has been the favored crop to meet the growing demand for vegetable oils. Firstly, it has the lowest production costs.11 Secondly, its composition means it’s versatile and can be used for food and non-food purposes alike: some oils are not suited for cosmetic uses such as shampoos and detergents. Third, it gets incredibly high yields.
If we weren’t meeting global oil demand through palm oil, another oil crop would have to take its place. Would the alternatives be any better for the environment?
We can compare crops in terms of their yields – how much oil we can produce from one hectare of land. This comparison is shown in the chart.12 Palm oil stands out immediately. It achieves a much higher yield than the alternatives. From each hectare of land, you can produce about 2.9 tonnes of palm oil. That’s around four times higher than alternatives such as sunflower or rapeseed oil (where you get about 0.7 tonnes per hectare) and 10 to 15 times higher than popular alternatives such as coconut or groundnut oil.13
Let’s take a look at how this comparison affects the global landscape of oil crops in terms of production and land use. In the chart, we see the breakdown of global vegetable oil production in 2018. On the left, we have each crop’s share of global land use for vegetable oils; on the right, we have its share of production.
We know from our yield comparison that palm oil achieves a much higher yield. What this means is that it accounts for a very high share of oil production without taking up much land. In 2017, it produced 36% of our vegetable oil but took up only 8.6% of the land.
Sunflower oil was almost exactly proportional in terms of how much oil it produced relative to how much land it took up: it produced 9% of oil and required 8.3% of land. Rape and mustard seed oil were also in proportion. The rest – soybean, olive, coconut, groundnut, and sesame seed – used more land than they gave back in oil production. Coconut oil, for example, provided only 1.4% of global oil but required 3.6% of the land.
It’s true, of course, that some crops provide co-products in the process. The non-oil fraction of soybeans, for example, can be allocated to other uses, such as high-protein animal feed. Therefore, using this land to grow crops meets other food demands at the same time. But this doesn’t change the fact that if the world requires a given amount of vegetable oil, it is the oil yield per hectare of each crop that we care about – regardless of whether it provides co-products in the process.
What would be the impact of substituting palm oil?
Palm oil achieves very high yields relative to other oil crops. Why does this matter?
If we want to limit our environmental impact, reducing the amount of land we devote to agriculture is key. To make space for more croplands and pastures, we have been displacing forests, grasslands, and peatlands – areas of rich biodiversity. The less land we need for farming, the better.
The high yields from palm oil mean that it, in some sense, ‘spares’ the world additional farmland we would need if we want to meet global oil demand from the alternatives. We can look at this in terms of the amount of land we would need if the total global demand for vegetable oil was met from a single crop alone. In other words, how much land would be needed if the 218 million tonnes of oil were only produced from palm oil or from rapeseed? This comparison is shown in the chart. As we’d expect, we see vast differences.
Let’s give these numbers some context. Currently, the world devotes around 322 million hectares to oilseed crops. That’s an area similar to the size of India. If global oil were supplied solely from palm, we’d need 77 million hectares, around four times less. If we got it from rapeseed, we’d need an area similar to the size we use today; from coconuts, an area the size of Canada; and in the most extreme case, we’d have to devote 2 billion hectares to sesame seeds – a bit more than Canada, the USA, and India combined.
In this sense, palm oil has been a ‘land-sparing’ crop. Switching to alternatives would mean the world would need to use more farmland and face the environmental costs that come with it. A global boycott of palm oil would not fix the problem; it would simply shift it elsewhere and at a greater scale because the world would need more land to meet demand.
This is true for other tropical oil crops such as coconut, groundnut, or soy. However, we might argue that this oversimplifies the comparison to more temperate crops: it assumes the environmental impact of devoting one hectare of land to sunflower seeds in Europe is the same as cutting down tropical rainforests to grow palm or coconut plantations. We know that tropical forests are incredibly rich in biodiversity and store a lot of carbon from the atmosphere. In some cases, especially for European domestic markets, some substitution for rapeseed or sunflower seed oils could have a positive environmental impact, even if it required using a bit more land.
How can we use palm oil without destroying tropical forests?
There are a number of steps we can take to ensure we meet the global demand for oils without destroying our tropical forests.
Substitutes for palm oil do not always exist. As we’ve discussed, substituting palm oil with alternatives can do more harm than good. But it’s also true that alternative oils are not always suitable for the products we need. Palm oil is unique in its versatility, meaning it is suitable for a range of foods, cosmetics, industrial applications, and biofuels. Substitution would be feasible for most food products. Substitution in industrial processes would be more difficult, especially if we want to replace it with oils grown in temperate countries: sunflower or rapeseed oil is not suited to products such as soaps, detergents, or cosmetics. One sector where alternatives do exist is bioenergy, which brings us to our next point.
European countries should stop using palm oil for biofuels. The EU – after China and India – is the third largest importer of palm oil. There are some products where using palm is our best option. This is not the case for biofuels, yet two-thirds of the EU’s imported palm oil goes to bioenergy production. Using palm oil as a biofuel is worse for the environment than petrol. A meta-analysis conducted by the Royal Academy of Engineering on EU biofuels found that when we factored in land-use change, the greenhouse gas emissions from palm oil were higher than those from using a petrol car.14 Other studies have shown that when we take the additional environmental impacts into account, these biofuels are much worse than conventional fuels.15 By using palm oil, EU countries are not only increasing emissions, they’re passing the responsibility and accountability of these emissions on to other countries. A ban on using palm oil for biofuels would reduce this impact while allowing global palm oil to be used for purposes where there are few better alternatives – food and cosmetic products.
Increase companies' sourcing from suppliers with sustainability certification. There are now a number of certification schemes that help to verify whether palm oil is being produced in a sustainable way. The most well-known is the Roundtable on Sustainable Palm Oil (RSPO). The RSPO was launched in 2004 and provides certification for suppliers who produce their crops in a more sustainable way by conducting impact assessments, managing high-value areas of biodiversity, not clearing primary forests, and avoiding land clearance through fires.16 For example, suppliers can only be certified if their plantations since 2005 have not replaced primary forests or areas rich in biodiversity. Consumer demand for sustainable palm oil puts pressure on food and cosmetic companies to source from certified suppliers and ultimately rewards the most sustainable growers.
Only 19% of palm oil production is covered by the RSPO.17 Research into the impact of the RSPO found that it was successful in reducing deforestation.18 However, it found that this most avoided deforestation from older plantations, which is not where most tropical forests remain. To have a real, permanent impact, certification needs to cover a much larger number of growers.
Increased crop yields. If we want to reduce agricultural expansion, we want to maximize crop yields through effective management practices, improved varieties, and choosing the most productive areas of land.
This combination of interventions involves actors across the full production line, from agricultural scientists improving crop varieties to palm oil growers, governments, food and cosmetic producers, retailers, and consumers. Pressure from consumers can filter through to growers. To do this effectively, understanding consumers has to be clearer. Many believe that boycotting palm oil is how we make a difference. But as we’ve seen, the alternatives are not necessarily better; more sustainable palm oil (used for food, not fuel) rather than no palm oil is what we should be pushing for.
Endnotes
Ostfeld, R., Howarth, D., Reiner, D., & Krasny, P. (2019). Peeling back the label—exploring sustainable palm oil ecolabelling and consumption in the United Kingdom. Environmental Research Letters, 14(1), 014001.
Ocado, an online UK retailer, is just one example.
This data is sourced from the UN Food and Agriculture Organization (FAO).
Wahid, M. B., Abdullah, S. N. A., & IE, H. (2005). Oil palm. Plant Production Science, 8(3), 288-297.
Meijaard, E., Garcia-Ulloa, J., Sheil, D., Wich, S.A., Carlson, K.M., Juffe-Bignoli, D., and Brooks, T.M. (eds.) (2018). Oil palm and biodiversity. A situation analysis by the IUCN Oil Palm Task Force. IUCN Oil Palm Task Force Gland, Switzerland: IUCN. xiii + 116pp.
Pendrill, F., Persson, U. M., Godar, J., & Kastner, T. (2019). Deforestation displaced: trade in forest-risk commodities and the prospects for a global forest transition. Environmental Research Letters, 14(5), 055003.
Potapov, P., Hansen, M. C., Laestadius, L., Turubanova, S., Yaroshenko, A., Thies, C., ... & Esipova, E. (2017). The last frontiers of wilderness: Tracking loss of intact forest landscapes from 2000 to 2013. Science advances, 3(1), e1600821.
Austin, K. G., Schwantes, A., Gu, Y., & Kasibhatla, P. S. (2019). What causes deforestation in Indonesia?. Environmental Research Letters, 14(2), 024007.
Seymour, F., & Harris, N. L. (2019). Reducing tropical deforestation. Science, 365(6455), 756-757.
Gaveau, D. L., Sheil, D., Salim, M. A., Arjasakusuma, S., Ancrenaz, M., Pacheco, P., & Meijaard, E. (2016). Rapid conversions and avoided deforestation: examining four decades of industrial plantation expansion in Borneo. Scientific reports, 6(1), 1-13.
Vijay, V., Pimm, S. L., Jenkins, C. N., & Smith, S. J. (2016). The impacts of oil palm on recent deforestation and biodiversity loss. PloS one, 11(7), e0159668.
Carter, C., Finley, W., Fry, J., Jackson, D., & Willis, L. (2007). Palm oil markets and future supply. European Journal of Lipid Science and Technology, 109(4), 307-314.
Here, I have calculated the actual yield of oil from each crop rather than the yield of the total crop. No crop is 100% oil-based, and therefore, this will differ from the mass of the crop itself. Ultimately, this is what matters if our question is how to meet global oil demand.
I have calculated the oil yield for each crop by dividing the actual oil production by the area harvested for each. Both of these metrics are sourced from the UN Food and Agriculture Organization (FAO).
To demonstrate this, let’s turn crop yields on its head and look at the inverse: the area of land you would need to produce one tonne of vegetable oil. We can simply calculate this as 1 / Yield (in tonnes per hectare).
This comparison by crop is shown here. To produce one tonne of oil, we need only 0.3 hectares of land from palm oil, 1.4 hectares from sunflower or rapeseed, 3.7 hectares from coconut, and 7 hectares from groundnut. To produce one tonne of oil, you would need four times the cropland devoted to sunflower or rapeseed or 10 to 15 times the amount of land devoted to coconut production.
Royal Academy of Engineering (2017). Sustainability of liquid biofuels.
R. Zah et al., Ökobilanz Von Energieprodukten: Ökologische Bewertung Von Biotreibstoffen (EMPA, Abteilung Technologie und Gesellschaft, St. Gallen, Switzerland, 2007).
Meijaard, E., Garcia-Ulloa, J., Sheil, D., Wich, S.A., Carlson, K.M., Juffe-Bignoli, D., and Brooks, T.M. (eds.) (2018). Oil palm and biodiversity. A situation analysis by the IUCN Oil Palm Task Force. IUCN Oil Palm Task Force Gland, Switzerland: IUCN. xiii + 116pp.
This is based on reported figures as of November 2020.
Carlson, K. M., Heilmayr, R., Gibbs, H. K., Noojipady, P., Burns, D. N., Morton, D. C., ... & Kremen, C. (2018). Effect of oil palm sustainability certification on deforestation and fire in Indonesia. Proceedings of the National Academy of Sciences, 115(1), 121-126.
Cite this work
Our articles and data visualizations rely on work from many different people and organizations. When citing this article, please also cite the underlying data sources. This article can be cited as:
Hannah Ritchie (2021) - “Palm Oil” Published online at OurWorldinData.org. Retrieved from: 'https://ourworldindata.org/palm-oil' [Online Resource]
BibTeX citation
@article{owid-palm-oil,
author = {Hannah Ritchie},
title = {Palm Oil},
journal = {Our World in Data},
year = {2021},
note = {https://ourworldindata.org/palm-oil}
}
Reuse this work freely
All visualizations, data, and code produced by Our World in Data are completely open access under the Creative Commons BY license. You have the permission to use, distribute, and reproduce these in any medium, provided the source and authors are credited.
The data produced by third parties and made available by Our World in Data is subject to the license terms from the original third-party authors. We will always indicate the original source of the data in our documentation, so you should always check the license of any such third-party data before use and redistribution.
All of our charts can be embedded in any site.