The natural world has been irreversibly changed by human actions and this has led to long-term trends towards increasing environmental degradation and scarcity of natural resources. Both of these trends are closely interlinked and will pose significant challenges over the next few decades, requiring large-scale, international action to avoid the worst-case scenario.
Human activities have resulted in air pollution, habitat destruction, soil erosion, desertification, ocean acidification and many other changes that are causing significant stress to ecosystems. With a growing global population, demand for fresh water and arable land for agriculture are expected to increase in the future. The development of new technologies (such as smart farming) will be essential to overcome some of these challenges. However, many such technologies, including clean energy technologies, require critical minerals that are also in short supply. Substantial efforts in terms of both mitigation (reduction of carbon emissions) and adaptation (changing behaviours, consumption patterns, resource management and more) will be required to maintain a level of ecosystem services needed for human wellbeing.
Environment trends
As the effects of climate change continue to impact the globe, precious, natural resources like fresh water, arable land and minerals are expected to become increasingly scarce, with significant implications for agriculture and food security, as well as the production of many new innovative technologies. According to the US National Intelligence Council, “nearly all of the Earth’s systems are undergoing natural and human-induced stresses outpacing national and international environmental protection efforts.”[1] The World Economic Forum identifies human over-exploitation and/or mismanagement as key drivers of the scarcity of natural resources.[2] Resource scarcity, whether of water, land or minerals, may also be a driver of conflict, particularly where economic and political issues create barriers to access to natural resources.[3,4]
Water, land, and consequences for food production
Water is already scarce and is likely to become even more scarce in future. Only 3% of the world’s water is freshwater, and much of this is is not readily accessible due to factors that include remote location, political boundaries, economics, and purity. The UN Food and Agricultural Organization (FAO) estimates that 1.8 billion people worldwide will face water scarcity by 2025 and 5.2 billion are expected to face water stress. By 2050, the FAO estimates that only 60% of the water needed will be available.[5] climate change may promote glacier melting that could lead to increased flows of water, higher temperatures are also expected to increase water loss due to evaporation.[4] An increasing demand for water will make the extraction and production (e.g. through desalination) of fresh water more energy intensive, and is likely to drive up costs for access to water.[3] Industrial water pollution, inadequate water management, and non-compliance with water sharing agreements and treaty provisions may lead to tensions over access to water sources.[1]
The same forces that are expected to impact water scarcity (climate change, population growth, ‘Urbanization’, economic development, and poor management) will also impact the availability of arable land for farming. This is a serious challenge when projections estimate that average levels of food production will have to increase by around 50% by 2050 (from a 2012 baseline) to meet the needs of the world’s population.[4] Indeed, it is impossible to separate out the issues of water and land scarcity as each affects the other in a significant way. For example, around 70% of global water consumption goes to agriculture, agriculture will be responsible for a large part of the increased demand for water in future[6], and current intensive farming techniques are linked to water pollution, along with air pollution, soil degradation and pest resistance.[4] Water scarcity and other consequences of climate change, such as volatile weather events and sea-level rise, will, on the one hand, reduce the amount of land available for developing new agricultural areas and, on the other hand, lead to reduced agricultural production. The resulting food insecurity is predicted to have a disproportionate effect on developing countries, with some predicting that “Africa could face a near double-digit reduction in crop yields and production volumes over the next decade, as well as rising food prices by similar margins.”[7]
Technology will need to play a major role in overcoming natural resource scarcity and improving agricultural productivity.[4] ‘Smart farming’ and techniques such as hydroponics and vertical farming will be key. Smart farming involves the use of digital technologies – e.g. unmanned machinery, robots, sensors, drones, big data, and advanced analytics – to be able to analyse the individual needs of specific fields, crops, or animals.[8] This kind of precision agriculture is more environmentally benign, minimizes water and electricity use, while maximizing the productivity of the land. Hydroponics (growing plants in mineral solutions instead of soil) and vertical farming (growing crops in vertically stacked layers) both reduce the need for land to grow certain crops and make it more practical to farm them in urban environments.[4]
Critical minerals and consequences for emerging technologies and the energy transition
Scarcity issues also apply to lesser-known natural resources like critical minerals – rare metals such as lithium, tellurium and rare earth metals that are used for batteries, solar panels, and various electronic devices. Demand for these product types will only increase in the coming decades as more people join the middle class and purchase consumer electronics such as smartphones. In addition, as the global community steps up efforts to cut greenhouse gas emissions, and transition to cleaner sources of energy such as electric vehicles (which require a lot of lithium) and solar power, this will increase the demand for these rare metals. As this demand grows, pressure on these limited resources will be significant. With the bulk of known critical mineral deposits in a small number of countries, political and supply chain issues could cause significant challenges in the future.[9]
Scarcity of water, land or minerals will provide both challenges and opportunities for businesses, who may have less readily available resources for production, but who may see potential market opportunities develop for sustainable and eco-friendly production.[10]
Related trends
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- ISO/DIS 24566-3 [Under development]Drinking water, wastewater and storm water systems and services — Adaptation of water services to climate change impactsPart 3: Drinking Water services
- ISO/DIS 24566-4 [Under development]Drinking water, wastewater and storm water systems and services — Adaptation of water services to climate change impactsPart 4: Wastewater services
- Water efficiency management systems — Requirements with guidance for use
- Published 38 Standards | Developing 12 Projects
- Water reuse — Vocabulary
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- ISO/AWI TR 4083 [Under development]Wood and wood-based products - Overview related to the concepts of renewability, reusability, recoverability, recyclability, compostability, biodegradability and circularity – Terminology and existing methodology
- ISO/DIS 8347 [Under development]Measurement procedures associated with the chain of custody in native tropical forest management areas
- ISO/FDIS 13391-1 [Under development]Wood and wood-based products — Greenhouse gas dynamicsPart 1: Framework for value chain calculations
- ISO/FDIS 13391-2 [Under development]Wood and wood-based products — Greenhouse gas dynamicsPart 2: Forest carbon balance
- ISO/FDIS 13391-3 [Under development]Wood and wood-based products — Greenhouse gas dynamicsPart 3: Displacement of greenhouse gas emissions
- Chain of custody of wood and wood-based products
- Published 12 Standards | Developing 7 Projects
- ISO/DIS 17887 [Under development]Traceability of rare earths in the supply chain from separated products to permanent magnets
- Recycling of rare earth elements — Requirements for providing information on industrial waste and end-of-life products
- Recycling of rare earth elements — Methods for the measurement of rare earth elements in industrial waste and end-of-life products
- Exchange of information on rare earth elements in industrial wastes and end-of-life cycled products
- Traceability of rare earths in the supply chain from mine to separated products
- Rare earth — Recyclable Neodymium iron boron (NdFeB) resources — Classification, general requirements and acceptance conditions
- ISO/AWI 24961 [Under development]Rare earths and lithium sustainability across the value chain : concentration, extraction, separation, conversion, recycling and reuse
- Published 4 Standards | Developing 2 Projects
- Circular economy — Vocabulary, principles and guidance for implementation
- Circular economy — Guidance on the transition of business models and value networks
- Circular economy — Measuring and assessing circularity performance
- ISO/CD TR 59031 [Under development]Circular economy – Performance-based approach – Analysis of cases studies
- Circular economy — Review of existing value networks
- ISO/FDIS 59040 [Under development]Circular economy — Product circularity data sheet
- Developing 15 Projects
- ISO/DIS 7819 [Under development]Lithium — Vocabulary
- Published 1 Standards
- Water efficiency labelling programmes – Requirements with guidance for implementation
- Published 68 Standards | Developing 10 Projects
ISO/TMBG/CMCC Coordination Committee on Critical Minerals
ISO/TMBG/SFCC Coordination Committee on Smart Farming
- Sustainable critical mineral supply chains
Ecosystems worldwide are at increasing risk of long-term changes and damage. Changes to plant life-cycles and animal behaviour are observed in both land and marine ecosystems.[11] Threats from pollution, habitat destruction, deforestation, over-exploitation, changes in biodiversity, seabed mining and ocean acidification are all interfering with the natural functioning of the earth’s ecosystems[3,11] alongside the ongoing threat of global warming.[4]
Reducing emissions of CO2 and other greenhouse gases is a critical response to these threats, and, if ambitious emission-reduction targets are achieved, offers some hope for the world’s ecosystems.[4]
Air pollution continues to increase, especially in rapidly growing cities, and will pose significant health risks into the future.[11] By 2035, air pollution may be the top cause of environmentally-related deaths worldwide.[1] Air quality is predicted to become ‘the most significant indicator with regards to quality of life, happiness and other indices.’[3] As growing numbers of people live in urban areas, air pollution can be expected to increase and will especially impact on urban populations.[3] Already, more than 80% of people living in cities are exposed to air pollution that exceeds safe limits.[1]
Signs of hope in relation to air pollution may appear in the form of increased public awareness, cleaner transport options, retrofitted buildings, and improved urban design.[3]
Soil erosion and desertification will increasingly threaten agricultural and habitable land[11], particularly where deforestation and unsustainable farming practices continue.
Related trends
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- ISO/AWI 14002-4 [Under development]Environmental management systems — Guidelines for using ISO 14001 to address environmental aspects and conditions within an environmental topic areaPart 4: Part 4: Resources and waste
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- ISO/WD 20305 [Under development]Mine closure and reclamation — Vocabulary
- Mine closure and reclamation planningPart 1: Requirements
- Mine closure and reclamation planningPart 2: Guidance
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- Mine closure and reclamation – Managing mining legaciesPart 2: Case studies and bibliography
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- Soil quality — Characterization of contaminated soil related to groundwater protection
- ISO/CD TS 18718 [Under development]Soil functions and related-ecosystem services: definitions and conceptual framework
- ISO/CD TS 18721 [Under development]Ecological soil functions: indicators and methods
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- Drinking water, wastewater and stormwater systems and services — Adaptation of water services to climate change impactsPart 2: Stormwater services
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- ISO/DIS 24566-4 [Under development]Drinking water, wastewater and storm water systems and services — Adaptation of water services to climate change impactsPart 4: Wastewater services
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- Waste management and reduction from aquaculture facilities in natural water bodies — Principles and guidelines
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References
- Global trends. Paradox of progress (US National Intelligence Council, 2017)
- The global risks report 2021 (World Economic Forum, 2021)
- Future outlook. 100 Global trends for 2050 (UAE Ministry of Cabinet Affairs and the Future, 2017)
- Global strategic trends. The future starts today (UK Ministry of Defence, 2018)
- Beyond the noise. The megatrends of tomorrow's world (Deloitte, 2017)
- Global trends and the future of Latin America. Why and how Latin America should think about the future (Inter-American Development Bank, Inter-American Dialogue, 2016)
- Foresight Africa. Top priorities for the continent 2020-2030 (Brookings Institution, 2020)
- Future technology for prosperity. Horizon scanning by Europe's technology leaders (EU Commission, 2019)
- Critical minerals scarcity could threaten renewable energy future (Stanford University, 2018)
- Global trends 2020. Understanding complexity (Ipsos, 2020)
- Asia pacific megatrends 2040 (Commonwealth Scientific and Industrial Research Organisation, 2019)