Advanced Materials Laser Processing is a peer-reviewed international journal dedicated to publishing cutting-edge research on advanced materials and laser processing. The journal aims to serve as a high impact platform bridging fundamental materials science, processing mechanism, engineering innovation and industrial application in the field of advanced materials and laser processing technology and equipment. The journal focuses on the development, characterization and application of materials and laser processes. It covers a broad spectrum of topics while maintaining a strong emphasis on originality, technical rigor, and industrial relevance.

The journal welcomes contributions in, but not limited to, the following areas:

• Composite materials and alloys: Ceramic matrix composite, metal matrix composite, carbon fiber reinforced composite, titanium alloys, aluminum alloys, magnesium alloys, nickel-based superalloys, cobalt-based superalloys, high-entropy alloys for structural, aerospace and automotive applications.
• Functional materials and metamaterial: Light, electricity, magnetic, separation, shape memory and other functional materials. Self-repairing materials, thermoelectric material, perovskite, aerogel, stanene, optical manipulation materials, artificial microstructure materials and other metamaterials.
• Laser processing and manufacturing: Development and applications of laser or laser-based multi-energy field processing and manufacturing such as laser welding, laser additive manufacturing, laser cleaning, laser cladding, laser cutting, laser forming and laser strengthening.
• Ultrafast laser micro/nano fabrication: Development and applications of femtosecond laser and picosecond laser micro-nano manufacturing for aviation engine blades, aerospace structural components, optical devices, optical windows, nuclear fusion ignition devices, photon chips and integrated circuit glass packaging and so on.
• Theoretical calculation and simulation: The theoretical calculation and simulation of laser processing based on first-principles, molecular dynamics and finite element methods.
• In-situ monitoring: In-situ high spatial-temporal resolution monitoring for laser processing to reveal the interaction mechanism between laser and materials, the energy transfer, the material joining and removal mechanism.