Performed a series of experiments presented at length in [4], where we tackled the direct application of pulsed laser deposition. The theoretical curves comply with the empirical information and are encouraging for future developments of the present model as a way of anticipating the behavior of diverse components made use of as targets in pulsed laser deposition. 6. Conclusions We reported here a new approach for understanding the fundamentals of laser ablation and transient plasma dynamics by means of a multifractal paradigm. The monofractal dynamics defined in Nottale’s scale relativity theory have been expanded for multifractal dynamics, establishing a multifractal theory of motion. The model was focused on understanding complex Alvelestat manufacturer phenomena such as multi-structuring and plasma heterogeneity during expansion, coupled with generating a link between the properties in the generated plasma with those of the ablated material. The angular distribution from the particles in multi-element plasmas was investigated, revealing that the fractality with the technique could be a element in preserving the stoichiometry of thin films throughout pulsed laser deposition. The simulations performed agreed effectively using the current data within the literature and were in line with recent reports of fundamental processes in laser-produced plasma dynamics. All through this manuscript, we aimed to present for the first time all of the numerous branches on the multifractal NSRT model relating to laser-produced plasma, inside a exclusive way. We aimed to supply the first complete description on the model as implemented for laser-produced plasmas. Additional developments with the model ought to be focused on the intricate dynamics of charged particles inside the framework with the pulsed laser deposition procedure. As PLD moves closer to becoming an industrial tool, it becomes imperative to possess comprehensive models which will describe the phenomena that exist and elucidate the connections among the properties from the target, laser, and plasma and those from the deposited film, as a complex puzzle that needs to be solved.Symmetry 2021, 13,16 ofAuthor Contributions: Conceptualization, M.A.; methodology, M.A. and S.A.I.; validation, S.A.I.; formal analysis, M.A. and S.A.I.; writing–original draft preparation, S.A.I. and M.A.; writing– overview and editing, S.A.I. and M.A.; visualization, S.A.I.; supervision, M.A.; funding acquisition, S.A.I. All authors have read and agreed to the published version in the manuscript. Funding: This study was funded by the SC-19220 Cancer Romanian Ministry of Education and Study under the Romanian National Nuclear System LAPLAS VI (contract no. 16N/2019, ELI-RO_2020_12) and Postdoctoral Project PD 145/2020. Institutional Evaluation Board Statement: Not applicable. Informed Consent Statement: Not applicable. Information Availability Statement: Information are obtainable on request from the corresponding author. Conflicts of Interest: The authors declare no conflict of interest.
applied sciencesArticleTechno-Economics Optimization of H2 and CO2 Compression for Renewable Power Storage and Power-to-Gas ApplicationsMario Esteban and Luis M. Romeo Escuela de Ingenier y Arquitectura, Universidad de Zaragoza, Mar de Luna 3, 50018 Zaragoza, Spain; [email protected] Correspondence: [email protected]: Esteban, M.; Romeo, L.M. Techno-Economics Optimization of H2 and CO2 Compression for Renewable Energy Storage and Power-to-Gas Applications. Appl. Sci. 2021, 11, 10741. https://doi.org/ ten.3390/app112210741 Academic Editor:.