Beamline optics
NanoMAX is a Hard X-ray monochromatic nanoprobe experimental station at MAX IV, set for best performance between 8 and 15 keV. After the pink photon beam is generated at the…
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Beamline optics
FemtoMAX performance2024 Energy range 1.8 -15 keV (0.8 – 6.8 Å) Photon source 2 x in-vacuum undulators U15 Monochromator Double Crystal Monochromator with InSb(111) crystals. 3 x Multi-Layer Mirror Photons…
Merry Christmas and a happy New Year!
Dear Users and Friends of MAX IV MAX IV extends our warmest wishes to each of you. This year has been filled with challenges and significant achievements, and none of…
Accelerators
The MAX IV facility consists of a 3 GeV storage ring, a 1.5 GeV storage ring, and a linear accelerator (fed by two guns) that serves as a full-energy injector to the rings, but also…
Electrochemistry
The electrochemistry setup which is designed for performing photoemission measurements of the solid-liquid or liquid-gas interfaces in a dip-and-pull geometry. A three electrode setup can be dipped and then pulled…
Solid-state end station
The solid-state end station (SSES) is designed for studying solid-state material via advanced experimental techniques in an ultra-high vacuum (UHV) environment. The end station is composed of four UHV chambers…
Atomic Force Microscope
AFM at X-ray Optics Lab It is possible now for MAX IV users to characterize their samples with true Atomic Force Microscopy, using the Dimension 3100 machine from Veeco/Digital Instruments….
Sample holders
The Imaging Station is equipped with a robotic sample changer that is swapping the samples between the measurement position and an intermediate storage inside the vacuum chamber. For this reason,…
Access modes
Below are the access modes the FinEstBeAMS beamline participates in, and potentially useful notes regarding what is offered for each: Standard access chevron_right The standard peer reviewed access mode at…
Technical Notes
R3 beam dynamics High-Chromaticity_Optics_for_the_MAX_IV_3_GeV_Storage_Ring.pdf Internal_Note_20090902_Updated_Lattice_120614.pdf Internal_Note_20100318_Updated_Lattice_120614.pdf Internal_Note_20100512_Pulsed_Magnet_Injection_120612.pdf Internal_Note_20101101_Updated_Lattice_120614.pdf Internal_Note_20101203_Magnet_Synchronization_120612.pdf Internal_Note_20110117_Updated_Lattice_120612.pdf Internal_Note_20111124_Updated_Lattice_120611.pdf Internal_Note_20121107_Updated_Lattice_140129.pdf Internal_Note_20130724_OCO_Modeling_141009.pdf Internal_Note_20150129_MIK_Analysis_150130.pdf Internal_Note_20150930_MW_Threshold.pdf insertion devices Internal_Note_20090922_Insertion_Devices_for_the_MAX_IV_3_GeV_Storage_Ring.pdf Internal_Note_20100215_Insertion_Devices_for_the_MAX_IV_3_GeV_Ring.pdf Internal_Note_20101209_Elliptically_Polarising_Undulators_with_11_mm_Magnetic_Gap_at_the_MAX_IV_3_GeV_Ring.pdf Internal_Note_20111110_Comparison_Brilliance_MAX_IV_NSLS-II.pdf Internal_Note_20111220_Elliptically_polarizing_undulators_for_the_Arpes_beamline_at_the_Solaris_Light_Source.pdf RF cavities Internal_Note_20240410 Harmonic Cavity Parameters for Flat…