Abstract: The invention provides a laser processing system having the function of optical diffraction tomography, comprising: an integrated imaging optical path and a processing optical path; the imaging optical path is used to perform optical diffraction tomography on the device to be processed; the processing optical path is used for processing the device to be processed. Moreover, the specific optical path structure is introduced. During the processing of the device to be processed, the laser processing system can also perform real-time imaging of the device to be processed without shifting the device to be processed. That is to say, the laser processing and imaging processing of the device to be processed can be realized at the same time in a laser processing system.

Abstract: An automatic surface tracing method, system, and storage medium are for laser processing. The method includes, at the initial moment, identifying the state of the laser beam on the surface of the workpiece to be processed. If the state is in an out-of-focus state, the relative distance between the microscope objective and the surface of the workpiece to be processed is adjusted, and the state is simultaneously identified until it is identified as an in-focus state. The method for identifying the state of the laser beam includes capturing a position image of the laser beam on the surface of the workpiece to be processed in real-time, and identifying the state of the laser beam accordingly. The method can effectively improve the processing success rate, processing quality and processing accuracy, and is economical and efficient.

Abstract: A method, including irradiating graphene oxide (GO) with a beam of light or radiation to form reduced graphene oxide (RGO) in a three-dimensional (3D) pattern, wherein the RGO is porous RGO with pores having sizes tuned by controlling the beam of light or radiation.

Abstract: A fiber core auto-tracing method, system, and storage medium for fabricating fiber gratings. The method includes: acquiring the image of the optical fiber to be processed on the three-dimensional translation stage in real-time; adjusting the relative position of the optical fiber and the microscope objective in the Z-axis direction, until it is recognized that two boundary lines are formed between the fiber core and the cladding in the currently collected image; calculate the position of the center point of the two boundary lines on the three-dimensional translation stage, and adjust the position of the fiber to be processed on the three-dimensional translation stage accordingly until the center point coincides with the XY coordinates of the laser focus.

Abstract: An automatic landing method, system, and storage medium for laser processing. The method includes: adjusting the relative position of the microscope objective and the workpiece to be processed along the direction of the optical axis within a preset travel range; during the adjustment process, collecting images of the workpiece to be processed in real-time and detecting the intensity of reflected light or fluorescence in real-time according to the image; determine the position of the strongest reflected light or the fluorescence initiation position according to the intensity detection data of reflected light or fluorescence. By scanning the intensity of reflected light or fluorescence, the invention achieves the purpose of quickly and accurately adjusting the laser focus to land on the surface to be processed, effectively improving the processing success rate, processing quality, and processing accuracy, and the solution is economical and efficient.

Abstract: A method, including irradiating graphene oxide (GO) with a beam of light or radiation to form reduced graphene oxide (RGO) in a three-dimensional (3D) pattern, wherein the RGO is porous RGO with pores having sizes tuned by controlling the beam of light or radiation.

Abstract: The invention relates in general to porous graphene-based films. In particular, the invention relates to a process for the preparation of a porous graphene-based films comprising reduced graphene oxide. The invention also relates to porous graphene-based films prepared by the process and to uses of such porous graphene-based films, in particular, in filtration applications. The invention further relates to porous multi-zone graphene-based films comprising different zones of different porosity.

Abstract: A photovoltaic (PV) structure for generating electrical power from light, the structure including an enhancing layer for increasing the absorption of the light into the structure, the enhancing layer including: a wrinkled graphene layer configured to trap the light in the PV structure; and aluminum nanoparticles configured to scatter the light into the PV structure.

Abstract: A photovoltaic (PV) structure for generating electrical power from light, the structure including an enhancing layer for increasing the absorption of the light into the structure, the enhancing layer including: a wrinkled graphene layer configured to trap the light in the PV structure; and aluminium nanoparticles configured to scatter the light into the PV structure.

Abstract: A non-linear optical device comprising a non-linear element made of a plasmonic material with a periodic structure having a period smaller than the wavelength of a non-linear process intrinsic to the plasmonic material. The plasmonic material is implemented as a gold film which is structured with a periodic array of asymmetric split ring slits. The metamaterial framework of the plasmonic material itself is used as the source of a strong and fast non-linearity. The cubic non-linear response is resonantly enhanced through the effect of the metamaterial structuring by more than two orders of magnitude and its sign and magnitude can be controlled by varying the metamaterial pattern.