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Publications

NIBIOs employees contribute to several hundred scientific articles and research reports every year. You can browse or search in our collection which contains references and links to these publications as well as other research and dissemination activities. The collection is continously updated with new and historical material.

NIBIO's Scientific Publications →

2026

Authors

Kathrin Yvonne Weber Erlend Grenager Sørmo Gerard Cornelissen Alice Budai Daniel Rasse Harald Bier Troy Robichaud

Abstract

Biochar has emerged as a promising carbon dioxide removal (CDR) solution that combines long-term carbon storage with benefits for soil health, waste management, and industrial applications. This report provides a comprehensive assessment of the current state of biochar across feedstocks, production technologies, material properties, and end-use pathways, with a particular focus on its role in climate mitigation. Drawing on scientific literature and international case studies, the report evaluates the carbon sequestration potential, environmental performance, and technological maturity of biochar systems. It distinguishes between applications that deliver durable carbon removal and those that primarily contribute to emission reductions. The report further examines deployment barriers, including feedstock availability, regulatory frameworks, market development, and safety considerations, and reviews the status of biochar implementation across Mission Innovation countries. Based on these insights, it outlines key opportunities and recommendations to support the responsible scale-up of biochar as a climate solution.

Authors

Colin Sinclair Jemma Louise Wadham Laura Jaakola Sabina Strmic Palinkas

Abstract

No abstract has been registered

To document

Authors

Björn H. Franke Aafke M. Schipper Tal Avgar Luca Börger Nilanjan Chatterjee Thomas Müller Brian J. Smith Briana Abrahms Abdullahi H. Ali Nina Attias Hattie L. A. Bartlam‐Brooks Floris M. van Beest Jerrold L. Belant Dean E. Beyer Niels Blaum Michael B. Brown Bayarbaatar Buuveibaatar Francesca Cagnacci Simon Chamaillé‐Jammes Nandintsetseg Dejid Jasja Dekker Arnaud L. J. Desbiez Julian Fennessy Christina Fischer Ilya Fischhoff Adam T. Ford Benedikt Gehr Jacob R. Goheen Ronaldo Gonçalves Morato Mark Hebblewhite Robert Hering Marco Heurich A. J. Mark Hewison Lynne A. Isbell Matthew Kauffman Andrew Jakes René Janssen Paul F. Jones Bob Jonge Poerink Clayton Lamb John Durrus Linnell A. Catherine Markham Courtney J. Marneweck Jenny Mattisson John McEvoy Erling Meisingset Evelyn Merrill Guilherme de Miranda Mourão Bram Van Moorter Nicolas Morellet Atle Mysterud John Odden Kirk A. Olson Agustín Paviolo Tyler Petroelje Kelly M. Proffitt Kasim Rafiq Nathan Ranc Christer Moe Rolandsen Daniel I. Rubenstein Sonia Saïd Hall Sawyer Niels Martin Schmidt Nuria Selva Agnieszka Sergiel Erling Johan Solberg Melissa Songer Jonas Stiegler Olav Strand Siva Sundaresan Jeffrey J. Thompson Wiebke Ullmann Dorj Usukhjargal Ulrich Voigt Filip Zięba Tomasz Zwijacz‐Kozica Mark A. J. Huijbregts Marlee A. Tucker

Abstract

Aim Animal movements are a fundamental process affecting communities and ecosystems. Quantifying habitat selection across species and habitats is key for understanding how animals respond to environmental change. Currently, we lack comparative studies that examine how habitat selection varies across species traits and landscapes. We aim to quantify global patterns of habitat selection to help understand the fundamental drivers of movement behaviour. Location Global. Time Period Contemporary. Major Taxa Studied Terrestrial mammals. Methods We estimated selection coefficients for terrain ruggedness, vegetation productivity, human population density and distance to roads of individual terrestrial mammals through step‐selection analysis of 1344 GPS tracks across 48 species. We quantified intra‐ and interspecific variation and tested whether selection coefficients were associated with species traits and habitat availability. Results We observe an overall avoidance of roads and areas of high human population density as well as rugged terrain, with a large proportion of individuals selecting for areas of intermediate NDVI. However, we also found large intraspecific variation in habitat selection and show that this variation is predicted by local and landscape‐level environmental conditions rather than species traits. Individuals in more remote areas exhibited weaker functional responses to human presence than those in more disturbed areas. Avoidance of rugged terrain is also context‐dependent, with stronger avoidance when local ruggedness is high. The only exception to the observed intraspecific variability is consistent species‐level responses to road proximity. Main Conclusions Our findings contribute to the understanding of habitat selection by terrestrial mammals, showing that selection is largely shaped by environmental conditions and that animals exhibit high plasticity in their responses. Our results also provide further evidence for the significant impact of roads on animal movement. These insights can help us to understand the potential effects of environmental change on the behaviour of mammal species around the world.

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Authors

Kathrin Yvonne Weber Erlend Grenager Sørmo Gerard Cornelissen Alice Budai Daniel Rasse Harald Bier Troy Robichaud

Abstract

No abstract has been registered

To document

Authors

Adam Eindride Naas Trond Simensen Lasse Torben Keetz Ingrid Vesterdal Tjessem Anders Bryn Rune Halvorsen Peter Horvath Ida Marielle Mienna Olav Skarpaas Joachim Paul Töpper Vigdis Vandvik Liv Guri Velle Catharina Caspara Vloon

Abstract

No abstract has been registered

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Authors

Holger Lange Natalia Kowalska

Abstract

Vi undersøker trends i karbonopptak av skog basert på områder utstyrt med flukstårn

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Editors

Camilla Baumann

Abstract

In Green Knowledge 2025, NIBIO presents a small selection of our research and knowledge development within agriculture, forestry, environment, natural resources and the bioeconomy. The report shows how research, data and analysis contribute to sustainable solutions for society, public administration and business – in Norway and internationally.

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Authors

Michael Altgen Daniela Altgen Dag Pasquale Pasca Katrin Zimmer

Abstract

This study investigates the moisture-induced recovery of temporary property changes in thermo-mechanically densified (TMD) birch and aspen wood, compared to thermally modified (TM) wood. Both treatments were prepared under identical thermal conditions, differing only by compression in TMD. Dimensional stability, water vapour sorption, and Brinell hardness were assessed before and after repeated wetting and drying cycles to evaluate the effect of stress storage in the polymer matrix and its recovery during moisture exposure. The results indicate that both TMD and TM treatments induce a temporary reduction in moisture uptake, consistent with the formation of an annealed polymer structure. Water saturation and subsequent drying restored higher moisture content and reduced Brinell hardness in TMD wood, highlighting a moisture-driven recovery of the annealed polymer conformation. Notably, the decrease in hardness could not be attributed solely to the reduction in bulk density, indicating additional effects of polymer plasticisation. The presence of compression stresses during TMD appeared to enhance stress storage, thereby influencing the recovery of moisture-induced properties. Initial wood moisture content before TMD had little effect on the temporary reduction in moisture content, suggesting that annealing also occurs in dry states. These findings emphasise the need to account for moisture cycling in TMD wood’s service life. Future work should focus on the interplay between compression stresses and the annealing effect to reduce the temporary nature of the property improvements by TMD.

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Authors

Tiina Belt Andreas Treu Veikko Möttönen Michael Altgen

Abstract

Wood has many attractive material qualities, but it is susceptible to biological degradation by wood-decaying fungi. Moisture is one of the critical requirements for wood decay, but much remains unknown about moisture dynamics in decaying wood. To fill this knowledge gap, this study investigated moisture in Scots pine sapwood during decay caused by the brown rot fungus Coniophora puteana. Samples were exposed to decay in two time-series experiments; mass loss and moisture content were recorded over the course of decay, and the bound and free water populations in the samples were analysed using low-field nuclear magnetic resonance (LFNMR) relaxometry in both the decaying state and at full water saturation. Selected samples were also used for water vapour sorption measurements. The time-series decay tests showed that moisture content initially increased due to fungal activity but decreased over time when corrected for mass loss, contrary to the general belief that moisture content increases with decay. LFNMR revealed that bound water content increased on a decayed-mass basis in the decaying state and at saturation, but no increase was seen after correction for mass loss. Free water content followed gravimetric moisture content in the decaying state, but the saturated state measurements revealed an initial increase and subsequent decrease with mass loss. Degradation caused changes in hygroscopicity, but our data show that overall moisture content is regulated by fungal activity rather than by material properties. These findings highlight the complexity of water interactions during fungal degradation, offering valuable new insights into wood degradation mechanisms.

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Authors

Gaute Velle Anders Bryn Kyrre Kausrud Lawrence R. Kirkendall Martin Malmstrøm Brett Kevin Sandercock Paul Ragnar Berg Kjetil Hindar Johanna Järnegren Erlend Birkeland Nilsen Eva Bonsak Thorstad Anders Nielsen

Abstract

This report examines how co-occurring non-native species can interact to create cumulative impacts on ecosystems. Non-native species may interact in additive, antagonistic, or synergistic ways. Through literature review, we found theoretical foundations and empirical examples showing that such interactions often occur. Synergistic interactions are of particular concern. Certain ecosystems appear particularly susceptible, including agricultural landscapes, urban environments, riparian systems, shipping-influenced marine areas, and islands with naïve fauna. We conclude that cumulative effects are ecologically important, and that it would be beneficial to incorporate multispecies interactions into risk assessments of non-native species in Norway.