RESUMEN
Electrocatalytic carbon dioxide/carbon monoxide reduction reaction (CO(2)RR) has emerged as a prospective and appealing strategy to realize carbon neutrality for manufacturing sustainable chemical products. Developing highly active electrocatalysts and stable devices has been demonstrated as effective approach to enhance the conversion efficiency of CO(2)RR. In order to rationally design electrocatalysts and devices, a comprehensive understanding of the intrinsic structure evolution within catalysts and micro-environment change around electrode interface, particularly under operation conditions, is indispensable. Synchrotron radiation has been recognized as a versatile characterization platform, garnering widespread attention owing to its high brightness, elevated flux, excellent directivity, strong polarization and exceptional stability. This review systematically introduces the applications of synchrotron radiation technologies classified by radiation sources with varying wavelengths in CO(2)RR. By virtue of in situ/operando synchrotron radiationanalytical techniques, we also summarize relevant dynamic evolution processes from electronic structure, atomic configuration, molecular adsorption, crystal lattice and devices, spanning scales from the angstrom to the micrometer. The merits and limitations of diverse synchrotron characterization techniques are summarized, and their applicable scenarios in CO(2)RR are further presented. On the basis of the state-of-the-art fourth-generation synchrotron facilities, a perspective for further deeper understanding of the CO(2)RR process using synchrotron radiation analytical techniques is proposed.
RESUMEN
Objective To investigate the dependency of thermal expansion coefficient of DNA adsorption film on environmental conditions. Methods By treating DNA adsorption film as a macroscopic continuum film with prestrain, an equivalent composite beam model of DNA film-substrate was established to calculate the deflection of DNA-microcantilever beam under temperature loading. By adopting Parsegian’s empirical potential which described the mesoscopic free energy of DNA adsorption film, the DNA liquid crystal-substrate multi-scale deflection model, the thought experiment method and the equivalent deformation method were combined to establish the trans-scale relationship between the microstructure of DNA adsorption film and its macro-scale mechanical properties. The thermal expansion coefficient of DNA adsorption film was predicted. ResultsGiven the ionic strength, the thermal expansion coefficient of double-stranded DNA adsorption film ranged from 0.3×10-4/K to 8.05×10-4/K, and that of single-stranded DNA adsorption film ranged from 1.28×10-4/K to 9.33×10-4/K. Conclusions As a leading role in the competition of micro-interactions, the change of configurational entropy determines the dependency of thermal expansion coefficient of DNA adsorption film on environmental conditions; the thermal expansion coefficient of DNA adsorption film decreases with the increase of temperature or ion concentration or DNA packing density. These results are useful for gene detection and its regulation, and provide reference for the evaluation of tissue organ performance in tissue engineering.