Our world faces many challenges, and the UN sustainable development goals are a call for action. Research has a crucial role to play in reaching these goals. The high-quality light and experiment methods available at MAX IV Laboratory enable researchers to see further into materials than ever before. Some experiments directly lead to an improved product, and others are beginning to explore the materials we will use many years from now. MAX IV works together with universities and industry to explore materials and solutions for a sustainable future.

Here you are able to read about sustainability research conducted by MAX IV users as well as sign up for webinars.

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News articles

 

 

Making wood – aligning nanocellulose fibres

Freeze drying suspensions of nanocellulose in water under the right conditions result in well-ordered networks of aligned fibres. This study shows that the ice-templating method is a promising way for sustainable composites and new human-made wood materials.

A hand placing component made of nanocellulose fibres

Riverine iron survives salty exit to sea

Iron organic complexes in Sweden’s boreal rivers significantly contribute to increased iron concentration in open marine waters, X-ray spectroscopy data shows. A Lund University study in Biogeosciences characterizes the role of salinity for iron-loading in estuarine zones, a factor which underpins intensifying seasonal algal blooms in the Baltic Sea.

A gushing river in the midst of trees

Designing a Model Catalyst for Large-Scale Biofuel Production

The future of efficient biofuel production is within reach. With measurements from MAX IV’s SPECIES beamline, a group from Lund University and RISE, Research Institutes of Sweden, has successfully developed a model catalyst that, once tuned, holds potential to significantly improve the treatment process for the large-scale manufacture of viable biofuels from lignin. Lignin is a plant polymer only secondary in abundance to cellulose in nature.

A piece of silicon (SiOx) wafer next to NiMo nanoparticles

Imaging temperature-dependent structural transition in a perovskite nanomaterial

An international team of researchers have used nano focused X-rays at the NanoMAX beamline to image the complex structure of metal halide perovskite nanowires. The high-resolution imaging made it possible to see domains inside the nanowire, as the temperature was increased across a structural phase transition. The structure of perovskite materials plays an important role in their properties for solar cells and light-emitting device applications.

A piece of sample perovskite nanomaterial

COOL sustainability more than a pipe dream in Lund

Sustainability measures, when applied intelligently, bolster societal productivity and deliver tangible improvements to the natural environment. Some argue that world economies cannot survive the impacts of business as usual in terms of pollution and high energy demands. In Lund, sustainability in work and life is a consistent aim, and in the most constructive way with COOL DH—the build project for the world’s largest low temperature district heating grid—nearing completion.

Inside MAX IV’s Energy Central building in Lund

 

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