Confined nanospace for enhanced photocatalysis

without tagging. Of note, the X-ray tag showed enhanced photostability (almost no photo-bleaching after 10 frames of scans) compared to endogenous fluorescent tags (up to 28% decrease), which allowed repetitive scanning at high density and thus enabled imaging with high spatial and energy resolution. Furthermore, the XRM cell imaging based on this tagging system had approximately an order ofmagnitude improved spatial resolution (about 30 nm) when compared to the resolution of classic optical microscopy (about 200 nm). The authors demonstrated two important applications of this genetic tagging and X-ray imaging system: it can be used to image subtle changes and refined structures of intercellular connections, which remains challenging for optical microscopy and electron microscopy because of their resolution limits; and it can achieve multi-color X-ray imaging by introducing different peroxidase tags and DAB substrates containing elements with distinguishable adsorption energies. The work by the Fan and Zhu group provides a highly versatile platform technique for imaging targetedmolecules and structures in cells with high specificity and resolution. Importantly, as part of the ‘Synchrotron for Neuroscience—an Asia Pacific Strategic Enterprise’ (SYNAPSE) project, aiming to comprehensively map the neuronal network of the entire human brain, this genetically encodedX-ray tagging system can be adapted readily to visualize the neuron network at a subcellular level resolution.

without tagging. Of note, the X-ray tag showed enhanced photostability (almost no photo-bleaching after 10 frames of scans) compared to endogenous fluorescent tags (up to 28% decrease), which allowed repetitive scanning at high density and thus enabled imaging with high spatial and energy resolution. Furthermore, the XRM cell imaging based on this tagging system had approximately an order of magnitude improved spatial resolution (about 30 nm) when compared to the resolution of classic optical microscopy (about 200 nm).
The authors demonstrated two important applications of this genetic tagging and X-ray imaging system: it can be used to image subtle changes and refined structures of intercellular connections, which remains challenging for optical microscopy and electron microscopy because of their resolution limits; and it can achieve multi-color X-ray imaging by introducing different peroxidase tags and DAB substrates containing elements with distinguishable adsorption energies.
The work by the Fan and Zhu group provides a highly versatile platform technique for imaging targeted molecules and structures in cells with high specificity and resolution. Importantly, as part of the 'Synchrotron for Neuroscience-an Asia Pacific Strategic Enterprise' (SYNAPSE) project, aiming to comprehensively map the neuronal network of the entire human brain, this genetically encoded X-ray tagging system can be adapted readily to visualize the neuron network at a subcellular level resolution.

Confined nanospace for enhanced photocatalysis
Bao-Lian Su 1,2 The world today is very different from how it was. The consumption rate of fossil fuels compared with the available resources and the calamity of global warming frighten people. The entire planet is at risk, but these are our crises. Mankind is the cause and so mankind should find sustainable and green energy solutions to satisfy the needs of society.
Chemical reactions driven by solar energy can not only diminish consumption of fossil fuels and pollution from such consumption, but also achieve high selectivity through exact energy exchange between photons and electrons. Since the pioneering work on electrochemical photolysis of water in 1972, semiconductors and other light-absorbing materials such as plasmonic metals have been widely explored [1][2][3]. For a long time, scientists have focused on enhancing photocatalytic performance through optimization of the three crucial processes in photocatalysis: light harvesting, electron-hole separation, and surface redox reactions. With the development of nanotechnology, hollow nanostructures have been found to efficiently promote light absorption and charge separation [4]. Not only that, the confined nanospace in the hierarchically hollow structures can provide a specific microenvironment for the reactions and affect the mass transfer of substrate to achieve a maximized efficiency [5][6][7].
To demonstrate the vital role of confined nanospace, a recent cooperative research group led by Prof. Jian Liu from the Dalian Institute of Chemical Physics, Chinese Academy of Sciences and Prof. Jun Huang from the University of Sydney investigated the effect of hierarchically hollow-structured nano-photoreactors loaded with bimetallic catalysts at different positions for photocatalytic oxidation of cinnamyl alcohol [8]. Hierarchically hollow nanostructures can be obtained through a nicely designed spontaneous phase transformation of core-shell structured zeolitic imidazolate frameworks (ZIF)-8@SiO 2 to hollow mesoporous zinc silica composites (HMZS) under mild hydrothermal conditions. The research traces the transformation process under different conditions via semi-in situ technique, and an 'adhesive-contraction' mechanism of hollow structure formation is proposed. Meanwhile, the synthesis strategy ensures controllability of the spatial location of active metals. The situation of AuPt bimetallic nanoparticles inside/on the surface (AuPt@HMZS and AuPt/HMZS) of the hollow structures depends on the order of metal loading and shell coating. AuPt bimetallic nanoparticles inside/ on the surface of the hollow structures exhibited a broader absorbance region under visible light than monometallic, through the influence of strong metal-metal interactions, as shown in Fig. 1a. Intriguingly, the adsorption edge of AuPt@HMZS displayed a red-shift compared with AuPt/HMZS. This phenomenon can be explained by multiple scattering of light inside, and the confined space of the hollow structure. It is clear that light absorption can be improved efficiently in a confined space, accompanied by heat management. The heat generated by light scattering and the photothermal effect of plasmonic AuPt nanoparticles is usually weakened via electron-photon scattering to reach the system equilibrium. However, heat loss can be slowed as the hollow nanoreactor serves as an insulating layer. As a result, the temperature in such a confined space where the reaction occurs will be higher than that of the external environment. The reaction rate of cinnamyl alcohol with AuPt nanoparticles confined inside the hollow structure (AuPt@HMZS) is 3.1 mmol/g after 5 h under visible light irradiation, which is superior to that of AuPt nanoparticles located at the surface of the hollow structure (AuPt/HMZS) with similar amounts of Au and Pt (Fig. 1b).
The contribution of hot electrons to the reaction process was also investigated. Hot electrons generated from plasmonic Au species were injected into the Pt species. The O 2 molecules adsorbed on the Pt surface could receive a hot electron to produce freestanding superoxide radicals (O 2 r − ), which are responsible for the catalytic oxidation of the reactant. For AuPt@HMZS catalysts, there is no doubt that O 2 molecules need to diffuse into the confined space through channels in the shell. Therefore, accumulation and collision of reactants in the confined space also accelerate the reaction (Fig. 1c).
This study provides a novel avenue for design of high-performance and sustainable photocatalysts for efficient chemical synthesis. The role of confined space will be certainly a good research direction, especially in light absorption, heat management, substrate accumulation, and protection of active components. Com-plex and hierarchical hollow structures, such as hollow multishelled structures (HoMSs), may provide more opportunities for rational design of efficient catalysts. The development of new technology to monitor the confined space parameters of nanoreactors renders visible the 'black boxes' of reactions occurring in confined space.