The inside cover picture shows in situ construction of highly emissive Pt(II) metallacycles upon irradiation. The self‐assembled diarylethene‐containing metallacycles can realize supramolecular transform from the open‐ring isomers to their closed‐ring ones under UV irradiation. Moreover, the closed‐ring isomers featured a relatively high fluorescence quantum yield. This property of “turn‐on” fluorescence switching provides a new method to construct highly emissive supramolecular fluorescent materials by light stimulus. More details are discussed in the article by Yang et al. on page 323–329.
The cover picture shows a synergistically directed assembly route towards novel multi‐component coordination architectures driven by aromatic donor‐acceptor and coordination interactions. The huge structural discrepancies between coronene donor present and absent experiments clearly prove the significance of aromatic donor‐accepter pairs and their inherent cooperation mechanism in these assembly processes. More details are discussed by Bu et al. on page 871–877.
The inside cover picture shows the development of chiral pyridoxal and pyridoxamine catalysts by mimicking vitamin B6‐dependent enzymes. These chiral pyridoxals and pyridoxamines displayed extraordinary catalytic performances in asymmetric biomimetic transamination and Mannich reaction, to give various chiral α‐amino acids and α,β‐diamino acid esters in good yields with excellent diastero‐ and/or enantioselectivities. The research has provided some useful information for further applications of the catalytic power of vitamin B6 in the area of asymmetric cayalysis. More details are discussed in the article by Zhao et al. on page 103–112.
The back cover picture shows the first LA‐catalyzed [3+2]IMCC of GDA‐epoxides with carbon‐carbon double bonds. This provides an efficient and general strategy for construction of bridged oxa‐[n.2.1] skeletons. A novel SN‐like mechanism through a carbon‐carbon bond cleavage of epoxide ring has been proposed. The colorful fireworks in the picture imply the generation of skeletal diversity from the epoxide‐diene, and express a dedication to the 100th Anniversary of Nankai University as well. More details are discussed in the article by Wang et al. on page 695–699.
The cover picture shows a highly enantioselective organocatalytic protonation of monofluorinated silyl enol ethers to α‐secondary α‐fluoroketones using water as proton source. Notably, in the presence of D2O and MeOD, the facile access of chiral α‐deuterated α‐fluoroketones in excellent enantioselectivity is achieved. More details are discussed by Zhou et al. on page 799–806.
The love story of “Niu Lang and Zhi Nv” is one of the most famous tales in China. The couple separated by the Tianhe river were able to meet each other once a year with the help of numerous magpies who built a colorful bridge across the river. With this backdrop, Y.‐F. Han et al. present in their article a metal‐carbene‐templated photochemistry in solution. Assisted by the bridge of carbene‐metal‐carbene units, two olefin substrates can reach each other closely, leading to photodimerization and the formation of cyclobutane derivatives. More details are discussed in the article by Han et al. on page 1147–1152.
The cover picture shows an approach toward less‐trace SpyTag‐SpyCatcher ligation. A proteolytic recognition sequence has been engineered into the second loop of SpyCatcher to produce SpyCatcherDDDDK variant. The reaction between SpyTag and SpyCatcherDDDDK is highly efficient both in vivo and in vitro, producing a stable covalent complex. The complex can be further cleaved at the second loop by enterokinase, resulting in only a small scar after ligation. This protocol adds to the expanding toolbox of genetically‐encoded peptide‐protein chemistry for protein topology engineering. More details are discussed in the article by Zhang et al. on page 113–118.
The cover picture shows A new strategy for preparing antimicrobial peptides from the natural occurring peptide gramicidin A has been developed by simply removing its N‐terminal formyl group and decoration at the terminal NH2 group. The peptides are able to selectively insert into Gram‐positive bacterial membrane to form transmembrane channels but not that of erythrocyte membrane, which leads to their high antimicrobial activity and low hemolytic toxicity. More details are discussed in the article by Hou et al. on page 25–29.
The cover picture shows an efficient one‐pot condensation of maleimide derivatives in the presence of acetic acid and water to afford a series of benzene triimides (BTIs). The structure, physicochemical properties and electrochemistry behavior of BTIs were systematically investigated. Owing to the planar structure and unique electron‐deficient nature, BTIs can self‐assemble into different motifs. More details are discussed by Wang et al. on page 684–688.
The inside cover picture shows an electrochemical oxidative Csp3‐H/S‐H activation with hydrogen evolution for the synthesis of tetrasubstituted olefins. This method features very high atom economy, besides hydrogen gas, under the base‐free, transition met‐al‐free, and oxidants‐free conditions, no other by‐products were generated. More details are discussed in the article by Lei et al. on page 547–551.
The development of azobenzene‐containing polymers (azopolymers) opens up an avenue for controlling their properties and functions with light. These polymers show shape changes and mechanical responses under the stimulation of light via photoisomerization of azobenzene groups. Herein, this report focuses on the growing research on moving polymers via photoisomerization, including their moving mechanisms and various applications. More details are discussed in the article by Wu et al. on page 1019—1022.
The cover picture shows that sequential 1,1‐dihydrosilylation of terminal aliphatic alkynes with primary silanes enabled by one earth‐abundant cobalt catalyst has been developed. This protocol is operationally simple using readily available aliphatic alkynes, including simple acetylene and complex drug derivative, for efficient access to valuable gem‐bis(dihydrosilyl)alkanes in highly regioselective and atom‐economic manners. Corresponding asymmetric transformations are achieved with excellent enantioselectivities. More details are discussed in the article by Lu et al. on page 457–461.
The cover picture shows that a new class of axially chiral aryl‐alkene‐indole frameworks has been constructed by the strategy of designing 3‐alkynyl‐2‐indolylmethanols as versatile reactants for catalytic asymmetric cyclizations. This approach represents the first catalytic asymmetric construction of axially chiral alkene‐heteroaryl scaffolds, which will add a nascent member to the atropisomeric family. The authors devised the innovative strategy to construct the intriguing axially chiral frameworks, just like Nuwa used the 'five‐colored stone' to mend the sky in the mythology of ancient China. More details are discussed in the article by Shi and Jiao et al. on page 543—552.
Glycerol molecules can be selectively converted into 1,2‐propanediol in water by the way of Ni‐based Great‐Wall Catalysts with Beacon‐like macropores and Passage‐like mesoporous channels. Otherwise, an amount of by‐product lactic acid was produced via rearrangement from glycerol. More details are discussed in the article by Zhang & Ma et al. on page 439–444.
The inside cover picture shows the hydrogen transfer process of the production of acetic acid from ethanol and water mixture catalyzed by iridium catalyst owning bpyO ligand. A DFT mechanistic study indicates that the cooperation of the iridium center and bpyO ligand plays an important role in the catalytic activity, and that the hydrogen release process from the iridium center is the rate‐determining step. More details are discussed in the article by Lei et al. on page 883–886.
The development of chiral boron Lewis acids is highly essential for the chemistry of frustrated Lewis pairs. Three protocols including hydroboration, substitution and in situ hydroboration, have been successfully established to access the chiral boron Lewis acids. A rapid growth for the metal‐free asymmetric hydrogenation and hydrosilylation has therefore been achieved in the past decade. More details are discussed in the article by Du et al. on page 625—634.
The cover picture shows Schilancidilactones A, B and Schilancitrilactones A, B, C all belong to schinortriterpenoid. Preliminary bioassay shows some of them possess fascinating bioactivities, such as antitumor, antihepatitis, and anti‐HIV‐1 activities. The total synthesis of Schilancidilactones A, B and Schilancitrilactones A, B, C has been accomplished from the common intermediates for the first time by Tang group. An intramolecular radical cyclization, late‐stage halogenation and AIBN‐mediated or Ni‐catalyzed intermolecular radical cross coupling reaction were employed as the key steps. More details are discussed in the article by Tang et al. on page 255–268.
The cover picture shows the molecular modeling software package SPONGE (Simulation Package tOward Next GEneration molecular modeling). SPONGE is designed to be efficient and highly modulated. Especially, advanced machine learning algorithms can be easily merged into MD simulations by using SPONGE. All these features increase the power of SPONGE for modeling and simulation of complex chemical and biological systems. More details are given in the article by Gao et al. on page 160–168.
The cover picture shows a simple, inexpensive and robust method on defluorosilylation of diverse fluoroalkenes with silylboronates in the presence of alkoxy base to directly synthesize various silylated fluoroalkenes. Density functional theory calculations revealed that transient silyl anion complex undergoes SN2’ or SNV substitution, which is responsible for this base‐mediated defluorosilylation reaction, thus obviating the need for copper salts. More details are discussed in the article by Shi et al. on page 1009–1014.
Chiral structure is very common in nature. especially, the chiral materials could rotate the polarized light. Light‐matter interaction is very important for process of nature. Inorganic nanomaterials with unique chiral configuration and suitable size have shown exquisitely chiral recognition and selective catalysis function, similar to natural restriction endonuclease. There are no unbridgeable gulf between organic molecules and inorganic materials. The physical and chemical mechanisms involved in chiral phenomenon are very helpful to exploit novel application of chiral materials in biological sensing, imaging, gene editing and information communications. More details are discussed in the article by Kuang et al. on page 25—31.
