Fluorescence imaging can be employed in fields of medical treatment, astronomical exploration, and national defense security. Traditional fluorescence imaging often takes the single-photon techniques, which is vulnerable to background interference and photobleaching. Remedially, two-photon fluorescence imaging can achieve much higher-resolution fluorescence imaging for reducing scattering and deeper depth. Hence, by assembling the tetraphenylethylene backbones with nontoxic and non-noble K+ ions, compound 1 ([(Hdma)K(H2ettc)]n, H4ettc = 4',4''',4''''',4'''''''-(ethene-1,1,2,2-tetrayl)tetrakis(([1,1'-biphenyl]-4-carboxylic acid))) with the crystallization-induced emissions exhibited charming fluorescence imaging under two-photon excitation microscopy (TPEM). Besides, luminescent powders based on compound 1 can achieve high-resolution fingerprint recognition, providing secure access control and identification for a novel authentication method. Compared with the commercial fluorescent dyes coumarin-6, the as-synthesized compound 1 showed great solvent stability, indicating its durability against harsh environment. Moreover, compound 1 shows mechanoluminescent properties for the perturbation of weak supramolecular interactions within ordered arrangements of the H2ettc2− ligands. This novel compound has provided an important insight to the development of two-photon fluorescence imaging and advanced external-stimuli responsive materials.
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Bismuth-based materials have attracted broad research interest as catalysts for electrocatalytic CO2 reduction (ECR) to formate in recent years. Most studies have been focused on exploring materials with high activity, selectivity, and durability, while little attention has been paid to the catalysts structure stability especially under working conditions of CO2 electrolysis. Here, starting from the precursor of bismuth oxide formate nanowires (BiOCOOH NWs), it was found that BiOCOOH NWs were easy to electrochemically evolve into two-dimensional sheet structure in CO2-saturated KHCO3 solution and would further reconstitute into larger ultrathin bismuth nanosheets covered with amorphous oxide thin layer (Bi/BiOx NSs). However, in Ar-saturated HCOONa solution, the one-dimensional structure could be maintained and reconstructed into rough porous bismuth nanowires (Bi NWs). Bi NWs showed less stability during ECR, which also generated surface amorphous oxide layer and further fragmentated into nanoparticles or nanosheets. Bi/BiOx NSs showed better activity, selectivity, and stability than Bi NWs, thanks to the high exposing active sites, enhancing CO2 adsorption and charge transfer. The demonstrated electrolyte dependence of structure evolution for bismuth-based catalysts and their performance for CO2 electroreduction could provide guidance for the design and synthesis of efficient catalysts.