Supervisors

The main supervisor – dR Calum Williams

Secondary supervisors – Dr. Masij Dabrovsky and Professor Simon Horsley

This doctoral layer will develop 3D printed optical materials to control the ultra -speed laser pulses on the time domains. By combining nano manufacturing, electromagnetic simulation, and pump laser measurements, the project will explore how 3D engineering, different material platforms, and enable light manipulation of the superior applications of the next generation in spectral analysis, sensing, and communications.

High -speed lasers still lead innovations from quantum technology to medical imaging, however the control of the pulses of the Vatmani is a major challenge. Metamaterials are artificial structures with sub -length features that allow visual responses designed in nature – such as a negative refractive index. This doctoral printing will develop 3D printed optical materials to sculpt the ultra -sculpture laser sculpting for the spectral analysis of the next generation, sensing, and control of light.

The student will use different materials platforms with 3D dual -photon (2PP) to manufacture multi -domain anti -drug materials below 200 nm. Research is basic visual physics to applications, and the student will develop skills in electromagnetic simulation, nanoparticles in a modern cleaning room, experimental visual systems and data analysis.

This research is perfectly suitable for candidates with interests in lights, photographic materials, high -speed optics, nanoparticles and arithmetic electromagnetism. Python /Matlab and experimental efficiency are desirable.

Skills Development: Basic visual physics research extends to applications, and the student will develop a variety of skills required during a doctoral project, including: electromagnetic simulation, nanoparticles in a clean condition in the latest style, high -speed pump measurements with laser pulses, data analysis and effective communication.

Exter University: The Exter Physics Department has extensive experience through visual physics and the development of optical devices and similar materials. The student will obtain a global level research facilities and will be based in the Research and Innovation Center at the Research and Innovation Center (CMRI): a society of academic, industrial and government partnerships that harness the global leading research distinction from theory to application, enabling simulation, measurement, manufacturing water tools and weapons -based devices.

Entry requirements

The successful candidate must be completed / complete a bachelor’s degree in physics, engineering, or discipline in relevant physical sciences (2: 1 / above). It should be self -motivated, creative problem solving, strong attention to angle, electromagnetic and mathematical optics. Strong analytical and experimental skills are necessary. Efficiency in Python / Matlab programming is desirable, preferably the motivation for research that focuses experimentally.

Supervisors

The main supervisor – dR Calum Williams

Secondary supervisors – Dr. Masij Dabrovsky and Professor Simon Horsley

This doctoral layer will develop 3D printed optical materials to control the ultra -speed laser pulses on the time domains. By combining nano manufacturing, electromagnetic simulation, and pump laser measurements, the project will explore how 3D engineering, different material platforms, and enable light manipulation of the superior applications of the next generation in spectral analysis, sensing, and communications.

High -speed lasers still lead innovations from quantum technology to medical imaging, however the control of the pulses of the Vatmani is a major challenge. Metamaterials are artificial structures with sub -length features that allow visual responses designed in nature – such as a negative refractive index. This doctoral printing will develop 3D printed optical materials to sculpt the ultra -sculpture laser sculpting for the spectral analysis of the next generation, sensing, and control of light.

The student will use different materials platforms with 3D dual -photon (2PP) to manufacture multi -domain anti -drug materials below 200 nm. Research is basic visual physics to applications, and the student will develop skills in electromagnetic simulation, nanoparticles in a modern cleaning room, experimental visual systems and data analysis.

This research is perfectly suitable for candidates with interests in lights, photographic materials, high -speed optics, nanoparticles and arithmetic electromagnetism. Python /Matlab and experimental efficiency are desirable.

Skills Development: Basic visual physics research extends to applications, and the student will develop a variety of skills required during a doctoral project, including: electromagnetic simulation, nanoparticles in a clean condition in the latest style, high -speed pump measurements with laser pulses, data analysis and effective communication.

Exter University: The Exter Physics Department has extensive experience through visual physics and the development of optical devices and similar materials. The student will obtain a global level research facilities and will be based in the Research and Innovation Center at the Research and Innovation Center (CMRI): a society of academic, industrial and government partnerships that harness the global leading research distinction from theory to application, enabling simulation, measurement, manufacturing water tools and weapons -based devices.

Entry requirements

The successful candidate must be completed / complete a bachelor’s degree in physics, engineering, or discipline in relevant physical sciences (2: 1 / above). It should be self -motivated, creative problem solving, strong attention to angle, electromagnetic and mathematical optics. Strong analytical and experimental skills are necessary. Efficiency in Python / Matlab programming is desirable, preferably the motivation for research that focuses experimentally.