Tuesday, 01 July 2025

Trees, soil crusts and soy: what influences the Earth's nitrogen balance

Soya cultivation

Soya cultivation is now responsible for 60 per cent of nitrogen fixation in the agricultural sector. Photo: Vesna - stock.adobe.com

You can't smell it, you can't see it, but it ensures our survival: nitrogen makes up 78 per cent of the Earth's atmosphere. Bettina Weber, a biologist at the University of Graz, emphasises its importance: “Nitrogen serves as an essential nutrient and is needed for the formation of biomass and the regulation of all living organisms.” In order to be used, the element must be fixed with the help of microorganisms. This biological binding occurs in natural habitats, but also on agricultural land. While the proportion of natural areas is declining, fixation caused by agriculture has increased by 75 percent over the past 20 years. A key cause is the cultivation of soy, according to an international study which was published in the renowned journal Nature.

An international team of researchers has now gained a comprehensive picture of global biological nitrogen fixation. Carla Reis Ely from Oregon State University (USA) led the study, which involved a total of 24 scientists: “Our new estimate of natural nitrogen fixation, based on improved scientific understanding, suggests that less new nitrogen enters natural ecosystems.” As a result, these ecosystems may store less carbon dioxide and mitigate climate change to a lesser extent.
“The amount of data has quadrupled over the past 25 years. In addition, significantly more habitats were taken into account and realistic average values were calculated, enabling us to describe global processes much more accurately,” explains Bettina Weber, co-author of the paper. “These data provide an essential basis for global calculations and modelling of Earth system processes. They are needed to understand how global biogeochemical cycles function and to take effective countermeasures in the event of undesirable developments.”

Importance of soil crusts

Worldwide, more than half (56 percent) of the nitrogen fixation by microorganisms takes place in natural landscapes, such as forests and soils without human use. However, this figure is up to two-thirds lower than was assumed 25 years ago. In this context, soils contribute 26 per cent, trees 19 per cent, herbs 17 per cent and shrubs nine per cent. Biological soil crusts have a previously unrecognised importance. They account for 18 per cent of the nitrogen fixation in natural environments. Biologist Bettina Weber: “This community of bacteria, fungi, mosses, lichens and algae, which occurs everywhere in arid areas, acts as a kind of local fertiliser, ensuring that other plants can settle and thus preventing desertification.” 

Balance of the Earth's atmosphere

In addition to natural areas, nitrogen fixation also plays a role in fields and pastures, where special plants, known as legumes, have fixing bacteria in nodules on their roots. Scientists attribute the 75 percent increase over the past two decades to intensification and the near doubling of the area under soybean cultivation. Soybeans are now responsible for 60 percent of nitrogen fixation in the agricultural sector, while 33 percent is accounted for by meadows and pastures, mainly clover, and seven percent by other agricultural products.
“If too much nitrogen is added to the soil, conversion processes can release more gaseous compounds into the atmosphere,” warns Bettina Weber, referring to the emission of degradation products such as nitrogen oxides and nitrous oxide. These may interfere with the balance of the Earth's atmosphere and alter or disrupt climate processes.

Related news

Human Rights, Security and National Adaptation Plans Nexus

A Holistic Approach to Women and Human Mobility on Monday, June 28th 16:00-17:30 online

Circular Bioengineering: FWF Cluster of Excellence aims to revolutionise the product cycle

Take a renewable raw material from nature – wood, for example – break it down into its building blocks and use them to create a functional material, such as a water-repellent surface coating, with the help of green chemistry. Once this has served its purpose, break it down again into its chemical components and use them to build something new. This idea is set to revolutionise the production and life cycle of materials and goods. The Cluster of Excellence "Circular Bioengineering", funded by the Austrian Science Fund FWF, is researching how to produce products from biomass, develop sustainable methods for the production process, and open options for returning products that have reached the end of their lifetime back into a cycle. The University of Graz is a partner in this Cluster of Excellence, for which the FWF is providing 18 million euros. Including its own funds, the total volume of the project is 27 million euros. The lead is with the BOKU University in Vienna.

Climate change update: ClimateTracer of the University of Graz provides reliable data

Yesterday, the Copernicus Climate Change Service of the European Union published its data on global warming up to end of November 2024. These confirm that this year will see the 1.5 °C threshold clearly exceeded for the first time. The Wegener Center at the University of Graz already computed an accurate full-year prediction: the global near-surface air temperature in 2024 will rise by 1.62 °C – plus/minus 0.05 °C standard deviation – compared to the pre-industrial level. Such latest predictions for 2024 and other essential data on climate change are provided by the scientists via the Graz Climate Change Indicators (GCCI) portal.

Novel Methods of Semiconductor Manufacturing: University of Graz is partner in EU project

How can technological innovations be aligned with principles of sustainability and circularity? This is a challenge being tackled by researchers at the Department of Environmental Systems Sciences at the University of Graz. As a partner in a new EU project, the team, led by Rupert Baumgartner, is contributing its expertise in sustainability assessment for the semiconductor manufacturing process. The focus of the research project “HaloFreeEtch” is on developing innovative, environmentally friendly etching methods for semiconductors.