Pulsed laser deposition

Pulsed laser deposition (PLD) is a physical vapor deposition (PVD) technique where a high-power pulsed laser beam is focused inside a vacuum chamber to strike a target of the material that is to be deposited. This material is vaporized from the target (in a plasma plume) which deposits it as a thin film on a substrate (such as a silicon wafer facing the target). This process can occur in ultra high vacuum or in the presence of a background gas, such as oxygen which is commonly used when depositing oxides to fully oxygenate the deposited films. While the basic setup is simple relative to many other deposition techniques, the physical phenomena of laser-target interaction and film growth are quite complex (see Process below). When the laser pulse is absorbed by the target, energy is first converted to electronic excitation and then into thermal, chemical and mechanical energy resulting in evaporation, ablation, plasma formation and even exfoliation. The ejected species expand into the surrounding vacuum in the form of a plume containing many energetic species including atoms, molecules, electrons, ions, clusters, particulates and molten globules, before depositing on the typically hot substrate. The detailed mechanisms of PLD are very complex including the ablation process of the target material by the laser irradiation, the development of a plasma plume with high energetic ions, electrons as well as neutrals and the crystalline growth of the film itself on the heated substrate. The process of PLD can generally be divided into four stages: Laser absorption on the target surface and laser ablation of the target material and creation of a plasma Dynamic of the plasma Deposition of the ablation material on the substrate Nucleation and growth of the film on the substrate surface Each of these steps is crucial for the crystallinity, uniformity and stoichiometry of the resulting film. The most used methods for modelling the PLD process are the Monte Carlo techniques.

Optimizing Atomic Layer Deposition Processes with Nanowire-Assisted TEM Analysis

Piezoelectric and elastic properties of Al0.60Sc0.40N thin films deposited on patterned metal electrodes

Colloidal Atomic Layer Deposition on Nanocrystals Using Ligand-Modified Precursors

Optimizing Atomic Layer Deposition Processes with Nanowire-Assisted TEM Analysis

Piezoelectric and elastic properties of Al0.60Sc0.40N thin films deposited on patterned metal electrodes

Colloidal Atomic Layer Deposition on Nanocrystals Using Ligand-Modified Precursors