For millions of years, nature has basically been getting by with just a few elements from the periodic table. Carbon, calcium, oxygen, hydrogen, nitrogen, phosphorus, silicon, sulfur, magnesium and potassium are the building blocks of almost all life on our planet (tree trunks, leaves, hairs, teeth, etc). However, to build the world of humans—including cities, health care products, railways, airplanes and their engines, computers, smartphones, and more—many more chemical elements are needed.
A recent article, published in Trends in Ecology and Evolution and written by researchers from CREAF, the Universitat Autònoma de Barcelona (UAB) and the Spanish National Research Council (CSIC), warns that the range of chemical elements humans need (something scientifically known as the human elementome) is increasingly diverging from that which nature requires (the biological elementome).
In 1900, approximately 80% of the elements humans used came from biomass (wood, plants, food, etc.). That figure had fallen to 32% by 2005, and is expected to stand at approximately 22% in 2050. We are heading for a situation in which 80% of the elements we use are from non-biological sources.
Non-biological elements are scarce or practically absent in living organisms, and rare in general; in many cases, their main reserves are located in just a handful of countries. They must be obtained from geological sources, which entails extraction, trade between countries, and the development of efficient recycling technologies, while their scarcity and location create potential for social, economic, geopolitical and environmental conflicts.
Thus, what might initially appear to be a purely scientific issue actually has much more far-reaching repercussions. “Sustaining the human elementome will be more and more complicated and risky; it will need to be done in terms of environmental justice, and of course, with a more rational use of the Earth’s limited resources,” sums up Jaume Terradas, founder of CREAF, honorary professor at the UAB and one of the article’s three authors.
Humanity, firmly bound to its expansive use of the periodic table
The study looks back at the history of humankind in relation to its use of the periodic table’s elements. “Humans have gone from using common materials, such as clay, stone and lime, the elements of which are constantly recycled in the ground, in nature and in the atmosphere, to using lots of other elements, notably including those known as rare earth elements,” says Jordi Sardans, CREAF researcher and co-author of the study. According to the article, the human and biological elementomes started to diverge in the decade of the 1900s, a result of continuous growth of the use of non-biomass materials (fossil fuels, metallic/industrial materials, and building materials).
In 1900, 79% of all the materials humans used annually were biomass materials, compared to 32% in 2005, and the figure of 22% currently predicted for 2050. Elements used in construction, transport, industry, and more recently, new technologies, such as computation and photovoltaic devices and mobile phones, were added to the human elementome over the course of the 20th century.
They include silicon, nickel, copper, chromium and gold, as well as others that are less common, such as samarium, ytterbium, yttrium and neodymium. In the past two decades, there has been an increase in the use of such scarce elements, owing to the implementation and expansion of new technologies and clean energy sources.
“Mineral element consumption/extraction is rising at a rate of around 3% a year, and that will continue up to 2050,” states Josep Peñuelas, CREAF and CSIC researcher and the other co-author of the study. “In that scenario, it is possible that we will have used up all our reserves of some of those elements (gold and antimony) by 2050, and of others (molybdenum and zinc) within a hundred years.”
Environmental, economic, social and geopolitical risks
The article leaves no room for doubt: The extraction of Earth’s chemical elements could be a limiting factor and lead to crises at every level. Using more of the periodic table’s elements involves the extraction of more minerals, rising energy consumption and the associated CO2 emissions. Furthermore, the growing scarcity of the elements in question is a threat to their availability, especially where poorer countries are concerned, and makes maintaining production difficult even for wealthy countries, thus affecting economic development.
Against that backdrop, there are also important and problematic geopolitical considerations. The natural reserves of some elements, including the rare earth elements, are located in a limited number of countries (China, Vietnam, Brazil, the U.S., Russia and the Democratic Republic of the Congo); China actually controls over 90% of the global supply and close to 40% of reserves. Their availability is therefore subject to fluctuations in supply and prices caused by opposing geopolitical interests, with the consequent danger of conflicts.
Out with programmed obsolescence, in with recycling and recovery
The authors stress the need to put an end to programmed obsolescence (the policy of planning or designing a product to have an artificially limited useful life), as well as to develop new technologies that contribute to a more profitable use of scarce elements and allow for their widespread, efficient recycling and reuse.
At present, there are few—if any—alternatives to many such elements, and their recycling rates are low because they are used in small amounts in combination with other materials in a broad range of products. Current recovery techniques have poor efficiency levels and entail a high risk of pollution owing to the toxicity of rare earth elements.
The article mentions different technologies that could be used for the recovery of scarce elements. One is bioleaching, the extraction of metals from their ores by using living organisms, such as bacteria, which can accumulate rare earth elements if they come into contact with industrial waste.
To avoid pollution, meanwhile, scientists are studying biosorption, a physiochemical process that occurs naturally in certain organisms and enables them to filter pollutants, such as heavy metals, in wastewater.
Other possibilities include cryomilling, in which recovery takes place through electrochemical deposition; the use of different carbon-based nanomaterials as means of sorption to preconcentrate rare earth elements from dissolved solids in wastewater; hydrometallurgy for the substantial recovery of rare earth elements and heavy metals from apatite and different scraps; and pyrometallurgy, or the extraction of supercritical fluids with CO2.
In any case, developing new ways of producing and recycling such elements on a large scale is essential.
Josep Penuelas et al, Increasing divergence between human and biological elementomes, Trends in Ecology & Evolution (2022). DOI: 10.1016/j.tree.2022.08.007
University of Barcelona
Humans plunder the periodic table while turning blind eye to the risks of doing so, say researchers (2023, January 17)
retrieved 18 January 2023
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no
part may be reproduced without the written permission. The content is provided for information purposes only.