Structure, principle, and application of magnetic field-assisted pulsed laser deposition: An overview

One of the most significant developments in pulsed laser deposition (PLD) technology is the introduction of external magnetic fields to affect the generation, expansion, diffusion, and nucleation of particles during deposition, which is completely different from its counterpart in magnetron sputtering (MS) and filtered vacuum cathode arc (FVCA). This overview summarizes the various structures and principles of the magnetic field introduced in PLDs. The effects of the magnetic field on the various properties of the PLD-grown nanomaterials were reviewed, and the reasons or probable causes were analyzed. These grown materials were applied in the different fields due to their novel optical, magnetic, and mechanical properties, which was overviewed emphatically in this manuscript. This overview intends to assist researchers working on PLD-grown materials.

Automated summary

One of the most significant developments in pulsed laser deposition (PLD) technology is the introduction of external magnetic fields to affect the generation, expansion, diffusion, and nucleation of particles during deposition, which is completely different from its counterpart in magnetron sputtering (MS) and filtered vacuum cathode arc (FVCA). This overview summarizes the various structures and principles of the magnetic field introduced in PLDs, reviews the effects of the magnetic field on the various properties of the PLD-grown nanomaterials, and analyzes the reasons or probable causes. These grown materials were applied in the different fields due to their novel optical, magnetic, and mechanical properties, which was overviewed emphatically in this manuscript. This overview intends to assist researchers working on PLD-grown materials.