The material consequences of choosing sustainable fashion
The material consequences of choosing sustainable fashion
The textile industry - primarily the business of cloth and clothing - produces close to 100 million tonnes of fibres every year. This number is only set to grow as purchasing power in emerging markets rises.
The industry - and its growth - has huge consequences for the environment and climate change, producing some 1.2 billion tonnes of CO2 equivalent per year. However, an increasing number of consumers, aware of the impact that clothing choices can have on the environment, are changing their buying habits.
For an industry that makes $3 trillion per year in revenues and employs nearly 60 million workers globally, this has material consequences for investors too.
In facts and figures
- 66% of global consumers say they are willing to pay more for sustainable goods – up from 55% in 2014 and 50% in 2013, according to Nielsen data.
- Millennials continue to be most willing to pay extra for sustainable offerings – almost three-out-of-four respondents in the latest findings, up from approximately half in 2014.
- In emerging markets, more than 65% of emerging consumers have been found to actively seek out sustainable fashion1.
What’s wrong with textiles?
Even if we focus just on carbon emissions and water consumption, textile production is one of the most polluting industries globally.
The textile industry produces more carbon than international flights and maritime shipping. The production of 1 tonne of textiles generates 17 tonnes of CO2 equivalent, compared to 3.5 tonnes for plastic and less than 1 tonne for paper2.
Over 60% of textiles are used in the clothing industry, and a large proportion of clothing manufacturing occurs in China and India, countries that rely on coal-fuelled power plants. This increases the carbon footprint of each garment.
The materials produced also has a noticeable effect on emissions from manufacturing. It is estimated that a single polyester t-shirt has emissions of 5.5 kg CO2, compared with 2.1 kg CO2 for one made from cotton3.
If the industry continues on its current path, by 2050, it could use more than 26% of the carbon budget “allowed” by the Paris Accord 4to keep global temperature rises to the 2°C target.
Textiles production (including cotton farming) uses around 93 billion cubic metres of water annually, representing 4% of global freshwater withdrawal5. Cotton, while less carbon intensive than polyester, is the most water intensive fibre to produce.
Beyond production, washing clothing using washing machines is estimated to require an additional 20 billion cubic metres of water per year globally6.
The greatest challenge is accessing the water required in water-scarce regions. At present, many of the key cotton-producing countries are under high water stress, including China, India, the US, Pakistan, and Turkey7. In China, 80% to 90% of fabric, yarn, and plastic-based fibres are made in water-scarce or water-stressed regions8.
Furthermore, while there is little data on ” substances of concern” used across the industry, it is recognised that textile production discharges high volumes of water containing hazardous chemicals into the environment. As an example, the World Bank estimates that 20% of industrial water pollution globally is attributable to the dyeing and treatment of textiles9.
What are the solutions?
There are several ways the textiles industry can tackle these problems. Fibre producers that have sustainable sourcing (ie. that have certified & controlled sources), have “closed loop” systems avoiding waste, and have sustainable processing of biomass - ideally powered by renewable energy sources - have the best carbon footprints. These “bio refineries” generate pulp, bio based chemicals and energy.
There are also emerging innovations that change the way textiles are dyed in order to save water, chemical and energy use. Digital printing is one example.
One of the most effective changes could be promoting wood-based “cellulosic” fibre use. Synthetic fibres are used more than natural fibres, and of the latter, cotton still leads. Cotton and polyester dominate the fibre market, accounting for 85% of all fibre used in clothing. Cotton production is very water and pesticide intensive, whereas polyester and nylon have very poor carbon footprints. Synthetics are also not biodegradable.
Wood based cellulosic fibres are only 6% of fibres in use today, but their use is outgrowing other fibres. “Modal fibres” are a type of cellulosic fibre developed in Japan in 1951. They are made from regenerated cellulose fibre.
Modal is 50% more water absorbent per unit volume than cotton, and consumes less water in production. Modal is also resistant to shrinkage, stays colour fast when washed in warm water, and is breathable and silky smooth to the touch. Modal fibre is a generic name for viscose/rayon, which comprise 90% of all cellulosic fibres. Modal fibre is produced according to a modified viscose process and has better textile properties, therefore it is a separate generic fibre.
Lyocell is a fibre made from the natural polymer cellulose found in wood. It is 100% biodegradable, and a sub-category of rayon. It is made in a closed loop process, which means the water and non-toxic solvents are virtually all reused.
Cellulosic fibres like lyocell and modal consume far less energy than synthetic fibres, and consequently are lower carbon emitters than the main alternatives on the market. They also don’t have the water withdrawal issues that cotton possesses.
Using these types of fibres could further limit the climate damage from textiles or clothes through their life cycle. Most life cycle emissions of clothes arise from the “use” phase. If we model a scenario of 50 uses of a cotton t-shirt, more emissions come from the use phase of clothing than from other activities.
Source: Carbon trust
Washing and drying clothing alone is estimated to account for 120 million tonnes of CO2 equivalent10. Fast drying products – able to improve appliance efficiency through lower temperature washing – could offer a major improvement upon the emissions associated with existing fibres.
Some fibres can enable faster drying, mainly cellulose and wool blends. Home appliances are also getting more efficient, which will help reduce carbon emissions. More recycling of fibres/extension of garment life – ie. “slower” fashion and better quality items – will also help.
The climate change impact of recycling worn out polyester or cotton waste into new polyester or cotton fibre is much lower than making the fibre from scratch. In addition, the dominance of the “use” phase emissions means that if garment lives can be extended, we can achieve strong carbon emission savings.
What is being done?
Textiles is an industry that contributes close to 10% to global carbon emissions. We see considerable potential to reduce this by focusing on cellulosic fibres, using digital printing, and improving resource preservation, as well as focusing more on recycling and in-use emissions.
Change, encouragingly, is looking more likely now than ever. The UK Parliament's Environmental Audit Committee published its proposals for improving the sustainability of the fashion industry in February. Recommendations include strengthening the Modern Slavery Act, using taxation as a way to penalise companies selling products with higher environmental impacts, and introducing an Extended Producer Responsibility scheme to reduce waste.
There is growing momentum in China too, which has focused on building a greener supply chain within the fashion and textile industries for some time, via its five-year plan. In January, the China National Textile and Apparel Council revealed national ambitions to forge a new image under three new labels “Technology, Fashion and Green” and it specified intentions to tighten its grip on environmental issues.
1. Source: Cotton Lifestyle Monitor (n.d.) as cited in Business of Fashion (2016), The State of Fashion 2017↩
2. Source: Eunomia, The potential contribution of waste management to a low carbon economy (2015)↩
3. This is because the former is produced from fossil fuels such as crude oil. In 2015, production of polyester for textiles use results in more than 706 billion kg of CO2e↩
4. Compared to the IEA 2°C pathway 2050 which allows for 15.3 giga tonnes of CO2 equivalent↩
5. Source: World Bank, AQUASTAT, and FAO, Dataset: Annual freshwater withdrawals, total (2014) ↩
6. Calculation based on Circular Fibres Initiative analysis and following sources: Pakula, C., Stamminger, R., Electricity and water consumption for laundry washing by washing machine worldwide (2009)↩
7. Source: Gassert, F., et al., Water stress by country, WRI Aqueduct (2013)↩
8. Source: Maxwell, D., et al., State of the apparel sector report: Water, GLASA (2015), p.43↩
. Source: Kant, R., Textile dyeing industry: An environmental hazard, Natural Science, Vol. 4, 1 (2012), p.23↩
10. Source: Calculation based on Circular Fibres Initiative analysis and following sources: Pakula, C., Stamminger, R., Electricity and water consumption for laundry washing by washing machine worldwide (2009); Dupont, Consumer Laundry Study (2013)↩
- How data science helps sustainable investors
- Webinar: what comes after the volatility of 2020?
- Taper Tantrum 2: is there a sequel in the making?
- The multi-generational family's approach to sustainable investment
- Are any stock markets cheap going into 2021?
- What next for Biden’s climate and social agenda?
This article is issued by Cazenove Capital which is part of the Schroders Group and a trading name of Schroder & Co. Limited, 1 London Wall Place, London EC2Y 5AU. Authorised by the Prudential Regulation Authority and regulated by the Financial Conduct Authority and the Prudential Regulation Authority.
Nothing in this document should be deemed to constitute the provision of financial, investment or other professional advice in any way. Past performance is not a guide to future performance. The value of an investment and the income from it may go down as well as up and investors may not get back the amount originally invested.
This document may include forward-looking statements that are based upon our current opinions, expectations and projections. We undertake no obligation to update or revise any forward-looking statements. Actual results could differ materially from those anticipated in the forward-looking statements.
All data contained within this document is sourced from Cazenove Capital unless otherwise stated.