A) The professional tasks consist, on the one hand, of the establishment of an Integrated 3D fine-structure testing laboratory, the procurement of the instruments and the establishment of harmonised operating conditions for them. During the physical design of the laboratory, we wish to provide the technical conditions of operation of the equipment to be placed, on the other hand, the coordinated operation, the possibility of complex problem solving, the demanding service for co-researchers or industrial operators and the possibilities of visiting researchers. During the design of the laboratory we want to take into account the requirements arising from the use of the instrument assembly, the conditions of modern work and the cost-effectiveness of the implementation. We intend to carry out the procurement of infrastructure equipment with the help of a public procurement consultant and in compliance with the relevant legislation. The development of a complex laboratory is justified by the fact that the 3D study in the field of material science is also one of the new research guidelines of the 21st century according to the relevant databases (Scopus, WoS), which allows not only morphological information, but also high-resolution phase identification and phase orientation determination. The international uniqueness of the planned infrastructure is that the planned microCT allows comprehensive testing and provides input data to the other three instruments. By combining them, uni-resolution and testable size can be achieved, providing 3D information obtained from the samples (composition, macro-, microstructure, crystal structure, morphology, orientation). The planned XRD Robot equipment offers the possibility of moving along pre-programmed tracks and automated measurements, which greatly increases the measuring capacity of the equipment. In addition, the rotation around the six axes provided by the planned equipment makes it possible to extend the innovative sampleless texture measurement method developed at the University of Miskolc to a new measurement arrangement, which increases the measurement range and reduces the measurement time. The nano/micro-scale machining that can be achieved by LA-FIB-SEM is essential for modern material engineering research, but also provides significant benefits in other research directions. By allowing us to produce directional samples with micrometer precision from almost any material, we can ensure that we provide the most suitable sample for a given scientific problem. Often time-consuming and costly tests can be carried out more efficiently, thereby optimising the time and resources spent on it while maximising effectiveness. The new laser ablation and focused ion beam provides a nationwide unique in situ sample preparation for SEM and even TEM tests. Thus, LA-FIB-SEM allows for 3D exploration with high-resolution, precise slicing technology, which can also be used for samples where minimal destruction is possible, e.g. archaeology, car electronics, or the sample volume to be tested justifies precision destruction e.g. nanotechnological developments, thin layer technology. The novelty of the device is the laser ablation preparing for FIB machining. Thus increasing the fine-working speed, the pre-prepared volume and reducing the cost of the use of gallium. This allows for individual sample processing which is not possible by using other traditional techniques. Using laser and ion beam machining, 3D tomographic tests can be carried out, which have not been possible so far. With the help of XRD(SAXS), the device will be suitable for phase identification, crystallisation and particle size testing of nanometre layers according to modern trends. B) The suitability of the research organisation is guaranteed by its professional achievements in metrology, the available research capacity, the degree of educational and research qualification, the interdisciplinary themes provided by the academic environment and the related broad professional relationship base. As mentioned above, the two centres of excellence of the University of Miskolc have decades of experience in fine structure testing, currently operating nationally uninitial infrastructures serving several disciplines (SEM/WDS, voltage meter XRD G3R, parallel beam XRD). There is a well-established technical history for each test method provided by the four instrument infrastructure. We have CT history, e.g. hydrogeology, soil and rock mechanics, oil exploration, silicate-based material development, fault analysis of soldering in research areas, despite the fact that no such equipment can be found at the University of Miskolc. The 3D tomography is well complemented by the XRD Robot capable of detecting deformation and orientation problems of non-destructive microstructures. We have tens of years of experience with the testing technique, we have had a diffractometer without a working center for several years. We have a strong ...