The hard X-ray nanoprobe of Max IV – NanoMAX – is designed to take full advantage of MAX IV’s exceptionally low emittance and the resulting coherence properties of the X-ray beam. Two endstations provide a high-flux diffraction-limited KB mirror focus, and an X-ray microscope based on zone plate optics.


MicroMAX will open up new possibilities in the area of structural biology making it possible to study proteins in 3D and to follow them in time. MicroMAX will allow studying the molecules that are most interesting but most difficult to study because they only provide microcrystals. MicroMAX will provide a very small but parallel and


BioMAX is the first X-ray macromolecular crystallography beamline of MAX IV Laboratory. It has been in user operation since 2017. The design goal for BioMAX was to create a stable and reliable beamline that is user friendly. The beamline experiment set-up is highly automated, in terms of both sample handling hardware and data analysis, while


Overview The Balder beamline is dedicated to X-ray absorption spectroscopy (XAS) and X-ray emission spectroscopy (XES) in medium and hard X-ray energy range, 2.4-40 keV (at present 4-40 keV). The high brilliance from the 3 GeV storage ring in combination with the beamline design will allow for time-resolved measurements down to sub-second time resolution to


DanMAX is a materials science beamline, dedicated to in situ and operando experiments on real materials. The beamline will operate in the 15–35 keV range and have three endstation instruments: one for full field imaging instrument, one versatile powder diffraction setup using an area detector and a high resolution powder X-ray diffraction instrument using a