First-principle study of the influence of hydroxyapatite on magnesium surfaces
Journal article, 2026

Hydroxyapatite (HA) on a magnesium (Mg) surface is studied using density functional theory, to help understand the effect of HA coating and alloying in the surfaces of Mg-based biodegradable implants. We determine the adsorption energies and structural changes of a single layer of HA on pure Mg(0001) and on sparsely calcium (Ca) or zinc (Zn) doped Mg(0001) and find that both Zn and Ca doping improves the adsorption, except in a few positions of HA relative to the dopant position. All adsorption configurations, whether with pure or doped Mg surfaces, show deformation of the surface and HA layer. For Ca doping, we found that for a certain adsorption configuration, the dopant Ca atom moves out of the Mg surface and into the HA layer, leaving behind a Mg vacancy in the top layer of the Mg surface. Plots of electron density changes show that electrons accumulate around the Ca dopant and the neighboring Mg atoms, while in Zn doping this is less pronounced. Overall, our results demonstrate that the dopant choice and relative position of HA influence the interaction between HA and Mg-surfaces, and affect both adsorption energies and atomic and electronic structures.

Magnesium printing plates

Atoms

Semiconductor doping

Magnesium

Magnesium alloys

Calcium

Zinc

Density functional theory

Adsorption

Author

Anthony Veit Berg

Chalmers, Microtechnology and Nanoscience (MC2), Quantum Device Physics

Ablai Forster

Student at Chalmers

Tim Hansson

Student at Chalmers

Alexandra Jernstedt

Chalmers, Microtechnology and Nanoscience (MC2), Quantum Technology

Emmy Salminen

Student at Chalmers

Elsebeth Schröder

Chalmers, Microtechnology and Nanoscience (MC2), Quantum Device Physics

Physical Chemistry Chemical Physics

1463-9076 (ISSN) 1463-9084 (eISSN)

Vol. In Press

Subject Categories (SSIF 2025)

Materials Chemistry

Condensed Matter Physics

Areas of Advance

Materials Science

DOI

10.1039/d6cp01070a

PubMed

42312996

More information

Latest update

6/23/2026