Your search keyword '"H Xu"' showing total 173 results

1. Immunosuppressive polyketides from mantis-associated Daldinia eschscholzii

Author

Wei Wang, Jing Ma, Qiang Xu, Lu Wang, Yong C. Song, Ren-Xiang Tan, Gao F. Zhang, Ying L. Zhang, Jie Zhang, Su H. Xu, Nan Jiang, Hui M. Ge, and Yan H. Lu

Subjects

Models, Molecular, biology, Daldinia eschscholzii, Stereochemistry, Chemistry, Triketone, General Chemistry, Fungus, biology.organism_classification, Crystallography, X-Ray, Biochemistry, Catalysis, Mice, Colloid and Surface Chemistry, Ascomycota, Animals, Macrolides, Immunosuppressive Agents, Spleen, Cell Proliferation

Abstract

Polyketides with unknown architectures are highly desired for the discovery of new drugs and agrochemicals. Here, the mantis-associated Daldinia eschscholzii, a fungus known to produce immunosuppressants dalesconols A and B, was found to simultaneously generate four novel skeletons capable of shaping the unusual chemistry of the fungal polyketides, of which seven were structurally unique and substantially immunosuppressive. In particular, the scaled-up fermentation of the microbe enabled the structural characterization of minor or "transitional" intermediate polyketides that allowed the reasonable recognition of the four biosynthetic pathways initiated by condensations of four, five, six and eight acetate units, respectively. Furthermore, the decarbonylation reaction of triketone, as in the case of daeschol A, was described for the first time, in addition to the structural correction of sporothrin C and nodulone. The work provided a set of novel immunosuppressive molecules that are of significance to drug discovery.

Published

2011

2. Immunosuppressive Polyketides from Mantis-Associated Daldinia eschscholzii.

Author

Ying L. Zhang, Jie Zhang, Nan Jiang, Yan H. Lu, Lu Wang, Su H. Xu, Wei Wang, Gao F. Zhang, Qiang Xu, Hui M. Ge, Jing Ma, Yong C. Song, and Ren X. Tan

Published

2011

3. High-Entropy Magnet Enabling Distinctive Thermal Expansions in Intermetallic Compounds.

Author

Li J, Lin K, Xu H, Yang W, Zhang Q, Yu C, Zhang Q, Chen J, Wang CW, Kato K, Kawaguchi S, You L, Cao Y, Li Q, Chen X, Miao J, Deng J, and Xing X

Abstract

The high-entropy strategy has gained increasing popularity in the design of functional materials due to its four core effects. In this study, we introduce the concept of a "high-entropy magnet (HEM)", which integrates diverse magnetic compounds within a single phase and is anticipated to demonstrate unique magnetism-related properties beyond that of its individual components. This concept is exemplified in AB 2 -type layered Kagome intermetallic compounds (Ti,Zr,Hf,Nb,Fe)Fe 2 . It is revealed that the competition among individual magnetic states and the presence of magnetic Fe in originally nonmagnetic high-entropy sites lead to intricate magnetic transitions with temperature. Consequently, unusual transformations in thermal expansion property (from positive to zero, negative, and back to near zero) are observed. Specifically, a near-zero thermal expansion is achieved over a wide temperature range (10-360 K, α v = -0.62 × 10 -6 K -1 ) in the A-site equal-atomic ratio (Ti 1/5 Zr 1/5 Hf 1/5 Nb 1/5 Fe 1/5 )Fe 2 compound, which is associated with successive deflection of average Fe moments. The HEM strategy holds promise for discovering new functionalities in solid materials.

Published

2024

4. Rational Design and Stereodivergent Construction of Enantioenriched Tetrahydro-β-Carbolines Containing Multistereogenic Centers.

Author

Chen T, Xiong Q, Xu H, Xiao L, Wang ZF, Chang X, Dang Y, Dong XQ, and Wang CJ

Abstract

Chiral tetrahydro-β-carbolines, as one of the most intriguing subtypes of indole alkaloids, have emerged as the privileged units in plenty of natural products and biologically active molecules with an impressive range of bioactive properties. However, the stereodivergent construction of these valuable skeletons containing multistereogenic centers from readily available starting materials remains very challenging, especially, in view of the introduction of an axial chirality. Herein, we developed an efficient method toward enantioenriched tetrahydro-β-carbolines with readily available tryptophan-derived aldimine esters and allylic carbonates under mild reaction conditions. The reaction proceeds in a sequential fashion involving synergistic Cu/Ir-catalyzed stereodivergent allylation and the Brønsted acid-promoted stereospecific Pictet-Spengler reaction, affording a wide range of chiral tetrahydro-β-carbolines bearing up to four stereogenic centers in good yields with excellent stereoselectivity control. When N -aryl-substituted tryptophan-derived aldimine esters were utilized, notably, a unique C-N heterobiaryl axis could be simultaneously constructed with the formation of the third point stereogenic center in the last cyclization step through dynamic kinetic resolution (DKR). Computational mechanistic studies established a plausible synergistic mechanism for dual Cu/Ir-catalyzed asymmetric allylation and the succeeding protonation-assisted Pictet-Spengler cyclization to complete the annulation. Structure-activity relationship analyses unveil the origins of stereochemistry for the building of one axis and three point stereogenic centers.

Published

2024

5. P-Block Aluminum Single-Atom Catalyst for Electrocatalytic CO 2 Reduction with High Intrinsic Activity.

Author

Ma Z, Wang B, Yang X, Ma C, Wang W, Chen C, Liang F, Zhang N, Zhang H, Chu Y, Zhuang Z, Xu H, Wang Y, and Liu J

Abstract

Atomically dispersed transition metal sites on nitrogen-doped carbon catalysts hold great potential for the electrochemical CO 2 reduction reaction (CO 2 RR) to CO due to their encouraging selectivity. However, their intrinsic activity is restricted by the hurdle of the high energy barrier of either *COOH formation or *CO desorption due to the scaling relationship. Herein, we discover a p-block aluminum single-atom catalyst (Al-NC) featuring an Al-N 4 site that enables disentangling this hurdle, which endows a moderate reaction kinetic barrier for *COOH formation and *CO desorption, as validated by in situ attenuated total reflection infrared spectroscopy and theoretical simulations. As a result, the developed Al-NC shows a CO Faradaic efficiency (FE CO ) of up to 98.76% at -0.65 V vs RHE and an intrinsic catalytic turnover frequency of 3.60 s -1 at -0.99 V vs RHE, exceeding those of the state-of-the-art Ni-NC and Fe-NC counterparts. Moreover, it also delivers a partial CO current of 309 mA·cm -2 at 93.65% FE CO and 605 mA at >85% FE CO in a flow cell and membrane electrode assembly (MEA), respectively. Strikingly, when using low-concentration CO 2 (30%) as the feedstock, this catalyst can still deliver a partial CO current of 240 mA at >80% FE CO in the MEA. Considering the earth-abundant character of the Al element and the high intrinsic activity of the Al-NC catalyst, it is a promising alternative to today's transition metal-based single-atom catalysts.

Published

2024

6. Unusual Triple-State Switching of Thermally Induced Birefringence in a Two-Dimensional Perovskite Ferroelectric.

Author

Ma Y, Wang B, Li W, Liu Y, Guo W, Xu H, Tang L, Fan Q, Luo J, and Sun Z

Abstract

Birefringent crystals hold a significant position in optical and optoelectronic fields due to their capability to control polarized light. Despite various chemical strategies devoted to designing birefringent crystals, it remains a challenge to switch and manipulate birefringence under physical stimuli. Here we present an unusual triple-state switching of birefringence in a 2D perovskite ferroelectric, ( N -methylcyclohexylammonium) 2 PbCl 4 ( 1 ), which exhibits two reversible phase transitions at 361 and 373 K. The in-plane birefringence of 1 (Δ n bc ) shows three distinctive states inside the bc plane, namely, the low-, high-, and zero-Δ n bc states. Strikingly, a huge augmentation of Δ n bc is solidly confirmed up to ∼400% between its low and high states, far beyond other birefringent materials. The origin of this triple-state switching of birefringence involves the variation of the ferroelastic strain and domain in the vicinity of the phase transition. As an entirely new mode of switching birefringence, this work facilitates the further development of new intelligent nonlinear optics.

Published

2024

7. Photoexcited Copper-Catalyzed Enantioselective Allylic C(sp 3 )-H Acyloxylation of Acyclic Internal Alkenes.

Author

Tang S, Xu H, Dang Y, and Yu S

Abstract

The functionalization of C-H bonds streamlines the synthesis of complex molecules by eliminating the need for substrate preactivation. Traditionally, the Kharasch-Sosnovsky reaction, which directly oxidizes allylic C-H bonds into allylic esters under copper catalysis, has been hampered by long reaction times, limited substrate scope, and low enantioselectivity with acyclic olefins. Herein, we present a novel, visible light-driven, copper-catalyzed asymmetric Kharasch-Sosnovsky reaction that overcomes these challenges. This method expands the substrate scope to include acyclic internal alkenes and improves reaction conditions using eco-friendly visible light catalysis. It enhances radical reactivity and achieves superior enantioselectivity and regioselectivity in producing allylic C-H acyloxylation products. This breakthrough significantly advances direct C-H functionalization techniques, offering a more efficient and sustainable approach to synthesizing chiral molecules.

Published

2024

8. Strong NIR-II Magneto-Optical Activity of a Chiral Sm 15 Cu 54 Cage.

Author

Chen JN, Huang KX, Cheng PM, Qi MQ, Xu H, Chen J, Duan Y, Kong XJ, Zheng LS, and Long LS

Abstract

The magneto-optical response of chiral materials holds significant potential for applications in physics, chemistry, and biology. However, exploration of the near-infrared (NIR) magneto-optical response remains limited. Herein, we report the synthesis and strong NIR-II magneto-optical activity of three pairs of chiral 3 d- 4 f clusters of R/S -Ln 15 Cu 54 (Ln = Sm, Gd, and Dy). Structural analysis reveals that R/S -Ln 15 Cu 54 features a triangular prism cage with C 3 symmetry. Interestingly, magnetic circular dichroism (MCD) spectra exhibit remarkable magneto-optical response in the NIR-II region, driven by the f-f transition. The maximum g -factor of R/S -Sm 15 Cu 54 reaches 5.5 × 10 -3 T -1 around 1300-1450 nm, surpassing values associated with Dy III and Cu II ions. This remarkable NIR-II magneto-optical activity may be attributed to strong magnetic-dipole-allowed f-f transitions and helix chirality of the structure. This work not only presents the largest Ln-Cu clusters to date but also demonstrate the key role of magnetic-dipole-allowed transitions on magneto-optical activity.

Published

2024

9. Radiotherapy-Driven Nanoprobes Targeting for Visualizing Tumor Infiltration Dynamics and Inducing Ferroptosis in Myeloid-Derived Suppressor Cells.

Author

Zhu W, Cheng X, Xu P, Gu Y, Xu H, Xu J, Wang Y, Zhang LW, and Wang Y

Subjects

Animals, Humans, Mice, B7-H1 Antigen metabolism, Neoplasms diagnostic imaging, Neoplasms radiotherapy, Neoplasms pathology, Ferric Compounds chemistry, Cell Line, Tumor, Ferroptosis drug effects, Myeloid-Derived Suppressor Cells immunology

Abstract

Myeloid-derived suppressor cells (MDSCs) significantly hinder the immune response to tumor radiotherapy (RT) because of their massive accumulation in tumors after RT, resulting in immunosuppression and poor clinical prognosis. Herein, we developed an anti-PD-L1 antibody-conjugated iron oxide nanoprobe (Fe 3 O 4 -αPD-L1) to target and induce ferroptosis in MDSCs, thereby alleviating RT resistance. Overexpression of PD-L1 in MDSCs following RT enables noninvasive in vivo magnetic resonance and positron emission tomography imaging using 89 Zr-labeled nanoprobes to track the movement of MDSCs and their infiltration into the tumor. After uptake by MDSCs that infiltrated the tumor, Fe 3 O 4 -αPD-L1 nanoprobes were mainly found within the lysosome and triggered the Fenton reaction, resulting in the generation of abundant reactive oxygen species. This process leads to ferroptosis of MDSCs, characterized by lipid peroxidation and mitochondrial dysfunction, and effectively reprograms the immunosuppressive environment within the tumor following RT. This study highlights a strategy for monitoring and regulating the fate of MDSCs to alleviate RT resistance and ultimately achieve improved treatment outcomes.

Published

2024

10. Pure Water Splitting Driven by Overlapping Electric Double Layers.

Author

Xu H, Zhang J, Eikerling M, and Huang J

Abstract

In pursuit of a sustainable future powered by renewable energy, hydrogen production through water splitting should achieve high energy efficiency with economical materials. Here, we present a nanofluidic electrolyzer that leverages overlapping cathode and anode electric double layers (EDLs) to drive the splitting of pure water. Convective flow is introduced between the nanogap electrodes to suppress the crossover of generated gases. The strong electric field within the overlapping EDLs enhances ion migration and facilitates the dissociation of water molecules. Acidic and basic environments, which are created in situ at the cathode and anode, respectively, enable the use of nonprecious metal catalysts. All these merits allow the reactor to exhibit a current density of 2.8 A·cm -2 at 1.7 V with a nickel anode. This paves the way toward a new type of water electrolyzer that needs no membrane, no supporting electrolyte, and no precious metal catalysts.

Published

2024

11. "Hard" Emulsion-Induced Interface Super-Assembly: A General Strategy for Two-Dimensional Hierarchically Porous Metal-Organic Framework Nanoarchitectures.

Author

Han J, Xu H, Zhao B, Sun R, Chen G, Wu T, Zhong G, Gao Y, Zhang SL, Yamauchi Y, and Guan B

Abstract

Two-dimensional (2D) hierarchically porous metal-organic framework (MOF) nanoarchitectures with tailorable meso-/macropores hold great promise for enhancing mass transfer kinetics, augmenting accessible active sites, and thereby boosting performance in heterogeneous catalysis. However, achieving the general synthesis of 2D free-standing MOF nanosheets with controllable hierarchical porosity and thickness remains a challenging task. Herein, we present an ingenious "hard" emulsion-induced interface super-assembly strategy for preparing 2D hierarchically porous UiO-66-NH 2 nanosheets with highly accessible pore channels, tunable meso-/macropore sizes, and adjustable thicknesses. The methodology relies on transforming the geometric shape of oil droplet templates within appropriate oil-in-water emulsions from conventional zero-dimensional (0D) "soft" liquid spheres to 2D "hard" solid sheets below the oil's melting/freezing point. Subsequent surfactant exchange on the surface of 2D "hard" emulsions facilitates the heterogeneous nucleation and interfacial super-assembly of in situ formed mesostructured MOF nanocomposites, serving as structural units, in a loosely packed manner to produce 2D MOF nanosheets with multimodal micro/meso-/macroporous systems. Importantly, this strategy can be extended to prepare other 2D hierarchically porous MOF nanosheets by altering metal-oxo clusters and organic ligands. Benefiting from fast mass transfer and highly accessible Lewis acidic sites, the resultant 2D hierarchically porous UiO-66-NH 2 nanosheets deliver a fabulous catalytic yield of approximately 96% on the CO 2 cycloaddition of glycidyl-2-methylphenyl ether, far exceeding the yield of approximately 29% achieved using conventional UiO-66-NH 2 microporous crystals. This "hard" emulsion-induced interface super-assembly strategy paves a new path toward the rational construction of elaborate 2D nanoarchitecture of hierarchical MOFs with tailored physicochemical properties for diverse potential applications.

Published

2024

12. Double Unit-Cell Silicogermanate Nanosheets Developed by Salting-Out Mechanism for Biomass Conversion.

Author

Wang J, Ren X, Xiang Q, Jiang J, Wang F, Guan Y, Xu H, and Wu P

Abstract

Zeolite nanosheets with an extremely thin thickness featuring both unique pore systems and low diffusion resistance have the potential to achieve enhanced catalytic performance in the conversion of bulky molecular biomass. The preparation of unit-cell level nanosheets generally requires complex and costly multifunctional surfactants or an organic structure-directing agent (OSDA). Commercially available and environmentally friendly ionic liquids can also direct the structure of zeolite nanosheets by π-π stacking when these kinds of OSDA are used in large amount. Herein, we first report unit-cell-sized silicogermanate nanosheets of NS-IM-20 ( UWY topology), 5 nm in thickness, which were synthesized at a relatively low ionic liquid concentration with the assistance of halide ion (Cl - ). The Pd-loaded NS-IM-20 nanosheets with a hierarchical porosity and moderate acidity act as promising bifunctional catalysts for selective biomass conversion.

Published

2024

13. Carbene-Assisted Arene Ring-Opening.

Author

Cheng Z, Xu H, Hu Z, Zhu M, Houk KN, Xue XS, and Jiao N

Abstract

Despite the significant achievements in dearomatization and C-H functionalization of arenes, the arene ring-opening remains a largely unmet challenge and is underdeveloped due to the high bond dissociation energy and strong resonance stabilization energy inherent in aromatic compounds. Herein, we demonstrate a novel carbene assisted strategy for arene ring-opening. The understanding of the mechanism by our DFT calculations will stimulate wide application of bulk arene chemicals for the synthesis of value-added polyconjugated chain molecules. Various aryl azide derivatives now can be directly converted into valuable polyconjugated enynes, avoiding traditional synthesis including multistep unsaturated precursors, poor selectivity control, and subsequent transition-metal catalyzed cross-coupling reactions. The simple conditions required were demonstrated in the late-stage modification of complex molecules and fused ring compounds. This chemistry expands the horizons of carbene chemistry and provides a novel pathway for arene ring-opening.

Published

2024

14. Phosphine Oxide-Nd 3+ Coordination Chains with Cumulated Output Enable Efficient LED-Pumping Optical Amplification.

Author

Man Y, Shi X, He Y, Duan C, Han C, Zhang D, and Xu H

Abstract

Near-infrared luminescent rare-earth organic complexes have attracted intensive attention in the field of optical waveguide amplification. However, their optical gains were commonly less than 4 dB/cm due to limited doping concentrations. Herein, two one-dimensional (1D) Nd 3+ coordination chains, namely, [Nd(TTA) 3 (DBTDPO)] n ( Nd1 ) and [Nd(TTA) 3 (DPEPO)] n ( Nd2 ), bridged by phosphine oxide ligands were developed for the neodymium-doped waveguide amplifier. Despite its P-P distance being similar to DBTDPO, the different P═O orientation of DPEPO renders markedly shorter intra- and interchain Nd-Nd distances for Nd2 in comparison to Nd1 . Furthermore, the weaker intermolecular interactions alleviate the quenching effect for Nd2 . Therefore, Nd2 can provide more locally concentrated and radiative Nd 3+ ions, leading to a larger Nd 3+ -characteristic 1.06 μm emission intensity and duration than Nd1 . Based on embedded and evanescent-field waveguide structures, Nd2 achieves state-of-the-art gain maxima of 5.7 and 4.9 dB/cm as well as outstanding gain stability. These results indicate that controllable coordination assembly of lanthanide ions in multidimension provides a flexible approach to combine local high-density outputs and effective suppression of quenching.

Published

2024

15. Reticular Ratchets for Directing Electrochemiluminescence.

Author

Luo R, Luo X, Xu H, Wan S, Lv H, Zou B, Wang Y, Liu T, Wu C, Chen Q, Yu S, Dong P, Tian Y, Xi K, Yuan S, Wu X, Ju H, and Lei J

Abstract

Electrochemiluminescence (ECL) involves charge transfer between electrochemical redox intermediates to produce an excited state for light emission. Ensuring precise control of charge transfer is essential for decoding ECL fundamentals, yet guidelines on how to achieve this for conventional emitters remain unexplored. Molecular ratchets offer a potential solution, as they enable the directional transfer of energy or chemicals while impeding the reverse movement. Herein, we designed 10 pairs of imine-based covalent organic frameworks as reticular ratchets to delicately manipulate the intrareticular charge transfer for directing ECL transduction from electric and chemical energies. Aligning the donor and acceptor (D-A) directions with the imine dipole effectively facilitates charge migration, whereas reversing the D-A direction impedes it. Notably, the ratchet effect of charge transfer directionality intensified with increasing D-A contrast, resulting in a remarkable 680-fold improvement in the ECL efficiency. Furthermore, dipole-controlled exciton binding energy, electron/hole decay kinetics, and femtosecond transient absorption spectra identified the electron transfer tendency from the N-end toward the C-end of reticular ratchets during ECL transduction. An exponential correlation between the ECL efficiency and the dipole difference was discovered. Our work provides a general approach to manipulate charge transfer and design next-generation electrochemical devices.

Published

2024

16. Modulating CO 2 Electrocatalytic Conversion to the Organics Pathway by the Catalytic Site Dimension.

Author

Xu H, Wang J, He H, Hwang I, Liu Y, Sun C, Zhang H, Li T, Muntean JV, Xu T, and Liu DJ

Abstract

Electrochemical reduction of carbon dioxide to organic chemicals provides a value-added route for mitigating greenhouse gas emissions. We report a family of carbon-supported Sn electrocatalysts with the tin size varying from single atom, ultrasmall clusters to nanocrystallites. High single-product Faradaic efficiency (FE) and low onset potential of CO 2 conversion to acetate (FE = 90% @ -0.6 V), ethanol (FE = 92% @ -0.4 V), and formate (FE = 91% @ -0.6 V) were achieved over the catalysts of different active site dimensions. The CO 2 conversion mechanism behind these highly selective, size-modulated p -block element catalysts was elucidated by structural characterization and computational modeling, together with kinetic isotope effect investigation.

Published

2024

17. Highly Stable 72-Nuclearity Nanocages for Efficient Synthesis of Aryl Nitriles via Ni/Cu Synergistic Catalysis.

Author

Liang ZL, Zhang ZH, Jiao YE, Xu H, Hu HS, and Zhao B

Abstract

Seeking noble-metal-free catalysts for efficient synthesis of aryl nitriles under mild conditions poses a significant challenge due to the use of hypertoxic cyanides or high-pressure/temperature NH 3 /O 2 in conventional synthesis processes. Herein, we developed a novel framework 1 assembled by [Ni 72 ] nanocages with excellent solvents/pH stability. To investigate the structure-activity relationship of catalytic performance, several isostructural MOFs with different molar ratios of Ni/Cu by doping Cu 2+ into framework 1 (Ni 0.59 Cu 0.41 ( 2 ), Ni 0.81 Cu 0.19 ( 3 ), Ni 0.88 Cu 0.12 ( 4 ), and Ni 0.92 Cu 0.08 ( 5 )) were prepared. Catalytic studies revealed that catalyst 3 exhibited remarkable performance in the synthesis of aryl nitriles, utilizing a formamide alternative to hypertoxic NaCN/KCN. Notably, catalyst 3 achieved an excellent TOF value of 9.8 h -1 . Furthermore, catalyst 3 demonstrated its applicability in a gram-scale experiment and maintained its catalytic performance even after six recycling cycles, owing to its high stability resulting from significant electrostatic and orbital interactions between the Ni center and ligands as well as a large SOMO-LUMO energy gap supported by DFT calculations. Control experiments and DFT calculations further revealed that the excellent catalytic performance of catalyst 3 originated from the synergistic effect of Ni/Cu. Importantly, this work not only provides a highly feasible method to construct highly stable MOFs containing multinuclear nanocages with exceptional catalytic performance but also represents the first example of a heterogeneous catalyst for the synthesis of aryl nitriles using formamide as the cyanide source.

Published

2024

18. Discovery of a Fungal P450 with an Unusual Two-Step Mechanism for Constructing a Bicyclo[3.2.2]nonane Skeleton.

Author

Xu H, Yuan Z, Yang S, Su Z, Hou XD, Deng Z, Zhang Y, and Rao Y

Subjects

Oxidation-Reduction, Alkanes, Skeleton

Abstract

The successful biomimetic or chemoenzymatic synthesis of target natural products (NPs) and their derivatives relies on enzyme discovery. Herein, we discover a fungal P450 BTG5 that can catalyze the formation of a bicyclo[3.2.2]nonane structure through an unusual two-step mechanism of dimerization and cyclization in the biosynthesis of beticolin 1, whose bicyclo[3.2.2]nonane skeleton connects an anthraquinone moiety and a xanthone moiety. Further investigation reveals that BTG5-T318 not only determines the substrate selectivity but also alters the catalytic reactions, which allows the separation of the reaction to two individual steps, thereby understanding its catalytic mechanism. It reveals that the first heterodimerization undergoes the common oxidation process for P450s, while the second uncommon formal redox-neutral cyclization step is proved as a redox-mediated reaction, which has never been reported. Therefore, this work advances our understanding of P450-catalyzed reactions and paves the way for expansion of the diversity of this class of NPs through synthetic biology.

Published

2024

19. Field-Induced Antiferroelectric-Ferroelectric Transformation in Organometallic Perovskite Displaying Giant Negative Electrocaloric Effect.

Author

Han S, Bie J, Fa W, Chen S, Tang L, Guo W, Xu H, Ma Y, Liu Y, Liu X, Sun Z, and Luo J

Abstract

Antiferroelectric materials with an electrocaloric effect (ECE) have been developed as promising candidates for solid-state refrigeration. Despite the great advances in positive ECE, reports on negative ECE remain quite scarce because of its elusive physical mechanism. Here, a giant negative ECE (maximum Δ S ∼ -33.3 J kg -1 K -1 with Δ T ∼ -11.7 K) is demonstrated near room temperature in organometallic perovskite, i BA 2 EA 2 Pb 3 I 10 ( 1 , where i BA = isobutylammonium and EA = ethylammonium), which is comparable to the greatest ECE effects reported so far. Moreover, the ECE efficiency Δ S /Δ E (∼1.85 J cm kg -1 K -1 kV -1 ) and Δ T /Δ E (∼0.65 K cm kV -1 ) are almost 2 orders of magnitude higher than those of classical inorganic ceramic ferroelectrics and organic polymers, such as BaTiO 3 , SrBi 2 Ta 2 O 9 , Hf 1/2 Zr 1/2 O 2 , and P(VDF-TrFE). As far as we know, this is the first report on negative ECE in organometallic hybrid perovskite ferroelectric. Our experimental measurement combined with the first-principles calculations reveals that electric field-induced antipolar to polar structural transformation results in a large change in dipolar ordering (from 6.5 to 45 μC/cm 2 under the Δ E of 18 kV/cm) that is closely related to the entropy change, which plays a key role in generating such giant negative ECE. This discovery of field-induced negative ECE is unprecedented in organometallic perovskite, which sheds light on the exploration of next-generation refrigeration devices with high cooling efficiency.

Published

2024

20. Ternary Eutectic Electrolyte-Assisted Formation and Dynamic Breathing Effect of the Solid-Electrolyte Interphase for High-Stability Aqueous Magnesium-Ion Full Batteries.

Author

Song X, Ge Y, Xu H, Bao S, Wang L, Xue X, Yu Q, Xing Y, Wu Z, Xie K, Zhu T, Zhang P, Liu Y, Wang Z, Tie Z, Ma J, and Jin Z

Abstract

Aqueous rechargeable magnesium batteries hold immense potential for intrinsically safe, cost-effective, and sustainable energy storage. However, their viability is constrained by a narrow voltage range and suboptimal compatibility between the electrolyte and electrodes. Herein, we introduce an innovative ternary deep eutectic Mg-ion electrolyte composed of MgCl 2 ·6H 2 O, acetamide, and urea in a precisely balanced 1:1:7 molar ratio. This formulation was optimized by leveraging competitive solvation effects between Mg 2+ ions and two organic components. The full batteries based on this ternary eutectic electrolyte, Mn-doped sodium vanadate (Mn-NVO) anode, and copper hexacyanoferrate cathode exhibited an elevated voltage plateau and high rate capability and showcased stable cycling performance. Ex-situ characterizations unveiled the Mg 2+ storage mechanism of Mn-NVO involving initial extraction of Na + followed by subsequent Mg 2+ intercalation/deintercalation. Detailed spectroscopic analyses illuminated the formation of a pivotal solid-electrolyte interphase on the anode surface. Moreover, the solid-electrolyte interphase demonstrated a dynamic adsorption/desorption behavior, referred to as the "breathing effect", which substantially mitigated undesired dissolution and side reactions of electrode materials. These findings underscore the crucial role of rational electrolyte design in fostering the development of a favorable solid-electrolyte interphase that can significantly enhance compatibility between electrode materials and electrolytes, thus propelling advancements in aqueous multivalent-ion batteries.

Published

2024

21. In Situ Infrared Spectroscopic Evidence of Enhanced Electrochemical CO 2 Reduction and C-C Coupling on Oxide-Derived Copper.

Author

Delmo EP, Wang Y, Song Y, Zhu S, Zhang H, Xu H, Li T, Jang J, Kwon Y, Wang Y, and Shao M

Abstract

The reaction mechanism of CO 2 electroreduction on oxide-derived copper has not yet been unraveled even though high C 2+ Faradaic efficiencies are commonly observed on these surfaces. In this study, we aim to explore the effects of copper anodization on the adsorption of various CO 2 RR intermediates using in situ surface-enhanced infrared absorption spectroscopy (SEIRAS) on metallic and mildly anodized copper thin films. The in situ SEIRAS results show that the preoxidation process can significantly improve the overall CO 2 reduction activity by (1) enhancing CO 2 activation, (2) increasing CO uptake, and (3) promoting C-C coupling. First, the strong *COO - redshift indicates that the preoxidation process significantly enhances the first elementary step of CO 2 adsorption and activation. The rapid uptake of adsorbed *CO atop also illustrates how a high *CO coverage can be achieved in oxide-derived copper electrocatalysts. Finally, for the first time, we observed the formation of the *COCHO dimer on the anodized copper thin film. Using DFT calculations, we show how the presence of subsurface oxygen within the Cu lattice can improve the thermodynamics of C 2 product formation via the coupling of adsorbed *CO and *CHO intermediates. This study advances our understanding of the role of surface and subsurface conditions in improving the catalytic reaction kinetics and product selectivity of CO 2 reduction.

Published

2024

22. Silicon-Containing Thiol-Specific Bioconjugating Reagent.

Author

Zhang Z, Li L, Xu H, Lee CK, Jia Z, and Loh TP

Subjects

Sulfhydryl Compounds chemistry, Indicators and Reagents, Proteins chemistry, Silicon, Immunoconjugates

Abstract

A new bioconjugation reagent containing silicon has been developed for the selective reaction with thiols. The inclusion of silicon significantly improves chemoselectivity and suppresses retro processes, thereby exceeding the capabilities of traditional reagents. The method is versatile and compatible with a broad range of thiols and unsaturated carbonyl compounds and yields moderate to high results. These reactions can be conducted under biocompatible conditions, thereby making them suitable for protein bioconjugation. The resulting conjugates display good stability in the presence of various biomolecules, which suggests their potential application for the synthesis of antibody-drug conjugates. Furthermore, the presence of a silicon moiety within the conjugated products opens up new avenues for drug release and bridging inorganics with other disciplines. This new class of silicon-containing thiol-specific bioconjugation reagents has significant implications for researchers working in bioanalytical science and medicinal chemistry and leads to innovative opportunities for advancing the field of bioconjugation research and medicinal chemistry.

Published

2024

23. Topology-Selective Manipulation of Two-Dimensional Covalent Organic Frameworks.

Author

Wang X, Liu M, Liu Y, Shang S, Du C, Hong J, Gao W, Hua C, Xu H, You Z, Chen J, and Liu Y

Abstract

The manipulation of topological architectures in two-dimensional (2D) covalent organic framework (COF) materials for different applications is promising but remains a great challenge. Here, we first report the topology-selective synthesis of two distinct varieties of 2DCOFs, imine-based HT-COFs and benzimidazole-fused BI-HT-COFs, by simply altering acid catalysts. To HT-COFs, a superlattice of 1D channel with a persistent triangular shape is formed via Schiff base reaction, while to BI-HT-COFs, a hexagonal lattice structure with a highly conjugated structure and imidazole linkages is constructed due to an imine-based cyclization reaction. The two COFs exhibited marked differences in their bandgap, chemical stability, molecular adsorption, and catalytic activity, which make them have different fields of application. This work not only diversifies the hexaaminotriphenylene-based 2DCOF topologies but also provides vivid examples of structure-property relationships, which would facilitate fundamental research and potential applications of 2DCOFs.

Published

2023

24. Generalized Octet Rule with Fractional Occupancies for Boron.

Author

Xu S, He C, Zhao Y, Yang X, and Xu H

Abstract

The octet rule is a fundamental theory in the chemical bonding of main-group elements, which achieve stable configurations by gaining, losing, or sharing electrons. However, the conventional octet rule, as depicted through Lewis structures, is inadequate for describing the electron delocalization in boron allotropes and boron-rich compounds due to the electron deficiency of boron. To address this, we introduce the concept of fractional electron occupancies, which more accurately reflect the electron delocalization in boron systems. Based on this, we propose a generalized octet rule that provides a more comprehensive understanding of the complex bonding configurations in boron allotropes and boron-rich compounds. Importantly, our predictions for α-B 12 are validated by both first-principles calculations and existing experimental data. Beyond boron, this generalized octet rule is also applicable to systems with multiple resonance structures.

Published

2023

25. Sequence-Defined Conjugated Oligomers in Donor-Acceptor Dyads.

Author

Mills HA, Rahman S, Zigelstein R, Xu H, Varju BR, Bender TP, Wilson MWB, and Seferos DS

Abstract

Conjugated macromolecules have a rich history in chemistry, owing to their chemical arrangements that intertwine physical and electronic properties. The continuing study and application of these systems, however, necessitates the development of atomically precise models that bridge the gap between molecules, polymers, and/or their blends. One class of conjugated polymers that have facilitated the advancement of structure-property relationships is discrete, precision oligomers that have remained an outstanding synthetic challenge with only a handful of reported examples. Here we show the first synthesis of molecular dyads featuring sequence-defined oligothiophene donors covalently linked a to small-molecule acceptor. These dyads serve as a platform for probing complex photophysical interactions involving sequence-defined oligomers. This assessment is facilitated through the unprecedented control of oligothiophene length- and sequence-dependent arrangement relative to the acceptor unit, made possible by the incorporation of hydroxyl-containing side chains at precise positions along the backbone through sequence-defined oligomerizations. We show that both the oligothiophene sequence and length play complementary roles in determining the transfer efficiency of photoexcited states. Overall, the work highlights the importance of the spatial arrangement of donor-acceptor systems that are commonly studied for a range of uses, including light harvesting and photocatalysis.

Published

2023

26. Charge Shielding-Oriented Design of Zinc-Based Nanoparticle Liquids for Controlled Nanofabrication.

Author

Tao P, Wang Q, Vockenhuber M, Zhu D, Liu T, Wang X, Hu Z, Wang Y, Wang J, Tang Y, Ekinci Y, Xu H, and He X

Abstract

Metal-containing nanoparticles possess nanoscale sizes, but the exploitation of their nanofeatures in nanofabrication processes remains challenging. Herein, we report the realization of a class of zinc-based nanoparticle liquids and their potential for applications in controlled nanofabrication. Utilizing the metal-core charge shielding strategy, we prepared nanoparticles that display glass-to-liquid transition behavior with glass transition temperature far below room temperature (down to -50.9 °C). Theoretical calculations suggest the outer surface of these unusual nanoparticles is almost neutral, thus leading to interparticle interactions weak enough to give them liquefaction characteristics. Such features endow them with extraordinarily high dispersibility and excellent film-forming capabilities. Twenty-two types of nanoparticles synthesized by this strategy have all shown good lithographic properties in the mid-ultraviolet, electron beam, or extreme ultraviolet light, and these nanoparticle liquids have achieved controlled top-down nanofabrication with predesigned 18 or 16 nm patterns. This proposed strategy is synthetically scalable and structurally extensible and is expected to inspire the design of entirely new forms of nanomaterials.

Published

2023

27. Electrical Conductance and Thermopower of β-Substituted Porphyrin Molecular Junctions─Synthesis and Transport.

Author

Xu H, Fan H, Luan Y, Yan S, Martin L, Miao R, Pauly F, Meyhofer E, Reddy P, Linke H, and Wärnmark K

Abstract

Molecular junctions offer significant potential for enhancing thermoelectric power generation. Quantum interference effects and associated sharp features in electron transmission are expected to enable the tuning and enhancement of thermoelectric properties in molecular junctions. To systematically explore the effect of quantum interferences, we designed and synthesized two new classes of porphyrins, P1 and P2 , with two methylthio anchoring groups in the 2,13- and 2,12-positions, respectively, and their Zn complexes, Zn-P1 and Zn-P2 . Past theory suggests that P1 and Zn-P1 feature destructive quantum interference in single-molecule junctions with gold electrodes and may thus show high thermopower, while P2 and Zn-P2 do not. Our detailed experimental single-molecule break-junction studies of conductance and thermopower, the latter being the first ever performed on porphyrin molecular junctions, revealed that the electrical conductance of the P1 and Zn-P1 junctions is relatively close, and the same holds for P2 and Zn-P2 , while there is a 6 times reduction in the electrical conductance between P1 and P2 type junctions. Further, we observed that the thermopower of P1 junctions is slightly larger than for P2 junctions, while Zn-P1 junctions show the largest thermopower and Zn-P2 junctions show the lowest. We relate the experimental results to quantum transport theory using first-principles approaches. While the conductance of P1 and Zn-P1 junctions is robustly predicted to be larger than those of P2 and Zn-P2 , computed thermopowers depend sensitively on the level of theory and the single-molecule junction geometry. However, the predicted large difference in conductance and thermopower values between Zn-P1 and Zn-P2 derivatives, suggested in previous model calculations, is not supported by our experimental and theoretical findings.

Published

2023

28. Nickel(II) Phototheranostics: A Case Study in Photoactivated H 2 O 2 -Enhanced Immunotherapy.

Author

Zhang R, Xu H, Yao Y, Ran G, Zhang W, Zhang J, Sessler JL, Gao S, and Zhang JL

Subjects

Mice, Animals, Nickel, Hydrogen Peroxide, Theranostic Nanomedicine methods, Phototherapy methods, Oxygen, Immunotherapy, Cell Line, Tumor, Tumor Microenvironment, Neoplasms diagnostic imaging, Neoplasms therapy, Nanoparticles

Abstract

Phototheranostics have emerged as a promising subset of cancer theranostics owing to their potential to provide precise photoinduced diagnoses and therapeutic outcomes. However, the design of phototheranostics remains challenging due to the nature of tumors and their microenvironment, including limitations to the oxygen supply, high rates of recurrence and metastasis, and the immunosuppressive state of cancer cells. Here we report a dual-functional oxygen-independent phototheranostic agent, Ni-2 , rationally designed to provide a near-infrared (NIR) photoactivated thermal- and hydroxyl radical (•OH)-enhanced photoimmunotherapeutic anticancer response. Under 880 nm laser irradiation, Ni-2 exhibited high photostability and excellent photoacoustic and photothermal effects with a photothermal conversion efficacy of 58.0%, as well as novel photoredox features that allowed the catalytic conversion of H 2 O 2 to •OH upon photooxidation of Ni(II) to Ni(III). As a multifunctional photoagent, Ni-2 was found not only to inhibit tumor growth in a CT26 tumor-bearing mouse model but also to activate an immune response via a combination of photothermal- and H 2 O 2 -induced effects. When combined with an antiprogrammed death-ligand 1 (aPD-L1), Ni-2 treatment allowed for the suppression of distant tumor growth and cancer metastasis. Collectively, the present results provide support for the proposition that Ni-2 or its analogues could emerge as useful tools for photoimmunotherapy. They also highlight the potential of appropriately designed 3d transition metal complexes as "all- in-one" phototheranostics.

Published

2023

29. From Helices to Crystals: Multiscale Representation of Chirality in Double-Helix Structures.

Author

Li CY, Xu H, Cheng PM, Du MH, Long LS, Zheng LS, and Kong XJ

Abstract

Single crystals with chiral shapes aroused the interest of chemists due to their fascinating polarization rotation properties. Although the formation of large-scale spiral structures is considered to be a potential factor in chiral crystals, the precise mechanism behind their formation remains elusive. Herein, we present a rare phenomenon involving the multitransfer and expression of chirality at micro-, meso-, and macroscopic levels, starting from chiral carbon atoms and extending to the double-helical secondary structure, ultimately resulting in the chiral geometry of crystals. The assembly of the chiral double helices is facilitated by the dual characteristics of amide groups derived from amino acids, which serve as both hydrogen bond donors and receptors, similar to the assembly pattern observed in DNA. Crystal face analysis and theoretical morphology reveal two critical factors for the mechanism of the chiral crystal: inherent intrinsically symmetrical distribution of crystal faces and their acquired growth. Importantly, the magnetic circular dichroism (MCD) study reveals the strong magneto-optical response of the hypersensitive f - f transition in the UV-vis-NIR region, which is much stronger than previously observed signals. Remarkably, an external magnetic field can reverse the CD signal. This research highlights the potential of lanthanide-based chiral helical structures as promising magneto-optical materials.

Published

2023

30. Bioorthogonal PROTAC Prodrugs Enabled by On-Target Activation.

Author

Chang M, Gao F, Pontigon D, Gnawali G, Xu H, and Wang W

Subjects

Proteolysis, Ubiquitin-Protein Ligases metabolism, Integrins metabolism, Prodrugs pharmacology

Abstract

Although proteolysis targeting chimeras (PROTACs) have become promising therapeutic modalities, important concerns exist about the potential toxicity of the approach owing to uncontrolled degradation of proteins and undesirable ligase-mediated off-target effects. Precision manipulation of degradation activity of PROTACs could minimize potential toxicity and side effects. As a result, extensive efforts have been devoted to developing cancer biomarker activating prodrugs of PROTACs. In this investigation, we developed a bioorthogonal on-demand prodrug strategy (termed c lick- r elease " cr PROTACs") that enables on-target activation of PROTAC prodrugs and release of PROTACs in cancer cells selectively. Inactive PROTAC prodrugs TCO-ARV-771 and TCO-DT2216 are rationally designed by conjugating a bioorthogonal trans -cyclooctenes (TCO) group into the ligand of the VHL E3 ubiquitin ligase. The tetrazine (Tz)-modified RGD peptide, c (RGDyK)-Tz, which targets integrin α v β 3 biomarker in cancer cells, serves as the activation component for click-release of the PROTAC prodrugs to achieve targeted degradation of proteins of interest (POIs) in cancer cells versus noncancerous normal cells. The results of studies accessing the viability of this strategy show that the PROTAC prodrugs are selectively activated in an integrin α v β 3 -dependent manner to produce PROTACs, which degrade POIs in cancer cells. The cr PROTAC strategy might be a general, abiotic approach to induce selective cancer cell death through the ubiquitin-proteasome pathway.

Published

2023

31. Structural Insights into Three Sesquiterpene Synthases for the Biosynthesis of Tricyclic Sesquiterpenes and Chemical Space Expansion by Structure-Based Mutagenesis.

Author

Lou T, Li A, Xu H, Pan J, Xing B, Wu R, Dickschat JS, Yang D, and Ma M

Abstract

The cyclization of farnesyl diphosphate (FPP) into highly strained polycyclic sesquiterpenes is challenging. We here determined the crystal structures of three sesquiterpene synthases (STSs, namely, BcBOT2, DbPROS, and CLM1) catalyzing the biosynthesis of the tricyclic sesquiterpenes presilphiperfolan-8β-ol ( 1 ), Δ 6 -protoilludene ( 2 ), and longiborneol ( 3 ). All three STS structures contain a substrate mimic, the benzyltriethylammonium cation (BTAC), in their active sites, providing ideal templates for quantum mechanics/molecular mechanics (QM/MM) analyses toward their catalytic mechanisms. The QM/MM-based molecular dynamics (MD) simulations revealed the cascade reactions toward the enzyme products, and different key active site residues that play important roles in stabilizing reactive carbocation intermediates along the three pathways. Site-directed mutagenesis experiments confirmed the roles of these key residues and concomitantly resulted in 17 shunt products ( 4 - 20 ). Isotopic labeling experiments addressed the key hydride and methyl migrations toward the main and several shunt products. These combined methods provided deep insights into the catalytic mechanisms of the three STSs and demonstrated how the chemical space of STSs can rationally be expanded, which may facilitate applications in synthetic biology approaches toward pharmaceutical and perfumery agents.

Published

2023

32. Modular Oxidation of Cytosine Modifications and Their Application in Direct and Quantitative Sequencing of 5-Hydroxymethylcytosine.

Author

Xu H, Chen J, Cheng J, Kong L, Chen X, Inoue M, Liu Y, Kriaucionis S, Zhao M, and Song CX

Subjects

Humans, Animals, Mice, DNA Methylation, DNA genetics, Oxidation-Reduction, Cystine analysis

Abstract

Selective, efficient, and controllable oxidation of cytosine modifications is valuable for epigenetic analyses, yet only limited progress has been made. Here, we present two modular chemical oxidation reactions: conversion of 5-hydroxymethylcytosine (5hmC) into 5-formylcytosine (5fC) using 4-acetamido-2,2,6,6-tetramethylpiperidine-1-oxoammonium tetrafluoroborate (ACT + BF 4 - ) and further transformation of 5fC into 5-carboxycytosine (5caC) through Pinnick oxidation. Both reactions are mild and efficient on double-stranded DNA. We integrated these two oxidations with borane reduction to develop chemical-assisted pyridine borane sequencing plus (CAPS+), for direct and quantitative mapping of 5hmC. Compared with CAPS, CAPS+ improved the conversion rate and false-positive rate. We applied CAPS+ to mouse embryonic stem cells, human normal brain, and glioblastoma DNA samples and demonstrated its superior sensitivity in analyzing the hydroxymethylome.

Published

2023

33. ACR-Based Probe for the Quantitative Profiling of Histidine Reactivity in the Human Proteome.

Author

Li J, Zhou J, Xu H, Tian K, Zhu H, Chen Y, Huang Y, Wang G, Gong Z, Qin H, and Ye M

Subjects

Humans, Histidine, Phosphorylation, Proteomics, Proteome, Acrolein

Abstract

The quantitative profiling of residue reactivity in proteins promotes the discovery of covalent druggable targets for precise therapy. Histidine (His) residues, accounting for more than 20% of the active sites in enzymes, have not been systematically characterized for their reactivity, due to lack of labeling probes. Herein, we report a chemical proteomics platform for the site-specific quantitative analysis of His reactivity by combination of acrolein (ACR) labeling and reversible hydrazine chemistry enrichment. Based on this platform, in-depth characterization of His residues was conducted for the human proteome, in which the rich content of His residues (>8200) was quantified, including 317 His hyper-reactive residues. Intriguingly, it was observed that the hyper-reactive residues were less likely to be the sites for phosphorylation, and the possible mechanism of this antagonistic effect still needs to be evaluated in further research. Based on the first comprehensive map of His residue reactivity, many more residues could be adopted as the bindable sites to disrupt the activities of a diverse number of proteins; meanwhile, ACR derivatives could also be used as a novel reactive warhead in the development of covalent inhibitors.

Published

2023

34. Exceptional Light Sensitivity by Thiol-Ene Click Lithography.

Author

Wang Q, Cui H, Wang X, Hu Z, Tao P, Li M, Wang J, Tang Y, Xu H, and He X

Abstract

Lithographic patterning, which utilizes the solubility switch of photoresists to convert optical signals into nanostructures on the substrate, is the primary top-down approach for nanoscale fabrication. However, the low light/electron-energy conversion efficiency severely limits the throughput of lithography. Thiol-ene reaction, as a photoinitiated radical addition reaction, is widely known as click reaction in the field of chemistry due to its extremely high efficiency. Here, we introduce a click lithography strategy utilizing the rapid thiol-ene click reaction to realize ultraefficient nanofabrication. This novel approach facilitated by the implementation of ultrahigh-functionality material designs enables high-contrast patterning of metal-containing nanoclusters under an extremely low deep-ultraviolet exposure dose, e.g., 7.5 mJ cm -2 , which is 10-20 times lower than the dose used in the photoacid generator-based photoresist system. Meanwhile, 45 nm dense patterns were also achieved at a low dose using electron beam lithography, revealing the great potential of this approach in high-resolution patterning. Our results demonstrated the high-sensitivity and high-resolution features of click lithography, providing inspiration for future lithography design.

Published

2023

35. Diastereoselective Radical Aminoacylation of Olefins through N-Heterocyclic Carbene Catalysis.

Author

Liu WD, Lee W, Shu H, Xiao C, Xu H, Chen X, Houk KN, and Zhao J

Subjects

Aminoacylation, Catalysis, Alkenes

Abstract

There have been significant advancements in radical-mediated reactions through covalent-based organocatalysis. Here, we present the generation of iminyl and amidyl radicals via N-heterocyclic carbene (NHC) catalysis, enabling diastereoselective aminoacylation of trisubstituted alkenes. Different from photoredox catalysis, single electron transfer from the deprotonated Breslow intermediate to O -aryl hydroxylamine generates an NHC-bound ketyl radical, which undergoes diastereocontrolled cross-coupling with the prochiral C-centered radical. This operationally simple method provides a straightforward access to a variety of pyrroline and oxazolidinone heterocycles with vicinal stereocenters (77 examples, up to >19:1 d.r.). Electrochemical studies of the acyl thiazolium salts support our reaction design and highlight the reducing ability of Breslow-type derivatives. A detailed computational analysis of this organocatalytic system suggests that radical-radical coupling is the rate-determining step, in which π-π stacking interaction between the radical intermediates subtly controls the diastereoselectivity.

Published

2022

36. In Situ Investigations on Structural Evolutions during the Facile Synthesis of Cubic α-MoC 1- x Catalysts.

Author

Sun X, Yu J, Cao S, Zimina A, Sarma BB, Grunwaldt JD, Xu H, Li S, Liu Y, and Sun J

Abstract

Cubic α-phase molybdenum carbides (α-MoC 1- x ) exhibit great potential in hydrogen production at low temperatures due to their excellent activity in water dissociation. However, the design strategies of α-MoC 1- x are severely restricted by the harsh synthesis conditions, which involve multistep ammonification and carburization or the utilization of a significant amount of noble metals. Herein, high-purity α-MoC 1- x synthesis in a one-step carburization process was achieved with the assistance of a trace amount of Rh (0.02%). The structural evolution of Mo species during phase transition was monitored via qualitative and quantitative analysis by in situ X-ray diffraction (XRD) and in situ X-ray absorption spectroscopy (XAS), respectively. Environmental transmission electron microscopy (ETEM) was used to follow the visual changes. We reveal that the reduction of monoclinic MoO 3 to cubic oxygen-deficient Mo oxide (MoO x ) at low temperatures owing to the promoted H 2 activation on Rh sites is vital to the following carbon atom insertion and transformation to α-MoC 1- x , making the carburization follow the topological route. The systematic analysis of the relationship between the reduction behavior and the structural evolution supplies a feasible strategy for the α-MoC 1- x synthesis, and in situ characterizations shed light on controlling the phase transformation during carburization.

Published

2022

37. Peptide Self-Assemblies from Unusual α-Sheet Conformations Based on Alternation of d/l Amino Acids.

Author

Zhou P, Hu X, Li J, Wang Y, Yu H, Chen Z, Wang D, Zhao Y, King SM, Rogers SE, Wang J, Lu JR, and Xu H

Subjects

Protein Structure, Secondary, Circular Dichroism, Protein Conformation, beta-Strand, Amino Acids, Peptides chemistry

Abstract

Peptide self-assembly is a hierarchical process during which secondary structures formed in the initial stages play a critical role in determining the subsequent assembling processes and final structural ordering. Unusual secondary structures hold promise as a source to develop novel supramolecular architectures with unique properties. In this work, we report the design of a new peptide self-assembly strategy based on unusual α-sheet secondary structures. In light of the strong propensity of leucine toward forming helical conformations and its high hydrophobicity, we design two short amphiphilic peptides Ac-L D LL D LK-NH 2 and Ac- D LL D LL D K-NH 2 with alternating l- and d-form amino acids. Microscopic imaging, neutron scattering, and spectroscopic measurements indicate that the two heterochiral peptides form highly ordered wide nanotubes and helical ribbons with monolayer thickness, in sharp contrast to twisted nanofibrils formed by the homochiral peptide Ac-LLLLK-NH 2 . Molecular dynamics simulations from monomers to trimers reveal that the two heteropeptides fold into α-sheets instead of β-sheets, which readily pack into tubular architectures in oligomer simulations. Simulated circular dichroism spectra based on α-sheet oligomers validate the proposed α-sheet secondary structures. These results form an important basis for the rational design of higher-order peptide assemblies with novel properties based on unusual α-sheet secondary structures.

Published

2022

38. Remote Enantioselective [4 + 1] Annulation with Copper-Vinylvinylidene Intermediates.

Author

Kong HH, Zhu C, Deng S, Xu G, Zhao R, Yao C, Xiang HM, Zhao C, Qi X, and Xu H

Subjects

Stereoisomerism, Catalysis, Molecular Structure, Copper chemistry, Esters

Abstract

The first copper-catalyzed enantioselective [4 + 1] annulation of yne-allylic esters with 1,3-dicarbonyl compounds was realized through an elegant remote stereocontrol strategy. The very remote ε regioselective nucleophilic substitution was developed by employing a novel chiral copper-vinylvinylidene species from the new C4 synthon yne-allylic esters. Thus, greatly diverse spirocycles were obtained with ample scope and excellent levels of chemo-, regio-, and enantioselectivities. Moreover, detailed mechanistic studies suggest an yne-allylic substitution and Conia-ene cascade pathway on the remote stereochemical induction progress.

Published

2022

39. Multi-Component Synthesis of a Buta-1,3-diene-Linked Covalent Organic Framework.

Author

Su Y, Li B, Xu H, Lu C, Wang S, Chen B, Wang Z, Wang W, Otake KI, Kitagawa S, Huang L, and Gu C

Abstract

We report a multi-component synthetic strategy on a two-dimensional crystalline covalent organic framework (COF) by connecting acetonitrile with aromatic aldehyde and acetaldehyde moieties to form an unprecedented cyano-substituted buta-1,3-diene linkage. Different from most of the COFs that were crystallized from the condensations from two components, the presented COF is generated from two competitive and reversible reactions among three moieties. The buta-1,3-diene COF exhibits remarkable photoactivity with a low exciton binding energy of 44.4 ± 1.5 meV for promoted charge separation, which enables the buta-1,3-diene-linked COF as an efficient photocatalyst for various aerobic oxidation reactions under visible light. Our multi-component synthesis strategy may provide new sights for synthesizing COFs with structural diversity and functional variability that are hard to achieve by traditional COF synthesis.

Published

2022

40. Catalytic Asymmetric Vinylogous and Bisvinylogous Propargylic Substitution.

Author

Qian HD, Li ZH, Deng S, Yao C, Xiang HM, Xu G, Geng ZQ, Wang Z, Chen L, Liu C, Zhu C, Qi X, and Xu H

Subjects

Catalysis, Ligands, Molecular Structure, Stereoisomerism, Copper chemistry

Abstract

Distinct regio- and enantioselectivity control in copper-catalyzed vinylogous and bisvinylogous propargylic substitution has been accomplished by using a novel chiral N , N , P ligand. The developed method provides an efficient and selective approach to an array of highly enantioenriched alkynyl unsaturated carbonyl compounds. Salient features include excellent functional group tolerance and broad substrate scope. The synthetic utility of the developed method is further demonstrated by a gram-scale synthesis and by application to a range of transformations including enantioselective synthesis of unique challenging compounds.

Published

2022

41. Direct Location of Organic Molecules in Framework Materials by Three-Dimensional Electron Diffraction.

Author

Ge M, Yang T, Xu H, Zou X, and Huang Z

Abstract

In the study of framework materials, probing interactions between frameworks and organic molecules is one of the most important tasks, which offers us a fundamental understanding of host-guest interactions in gas sorption, separation, catalysis, and framework structure formation. Single-crystal X-ray diffraction (SCXRD) is a conventional method to locate organic species and study such interactions. However, SCXRD demands large crystals whose quality is often vulnerable to, e.g., cracking on the crystals by introducing organic molecules, and this is a major challenge to use SCXRD for structural analysis. With the development of three-dimensional electron diffraction (3D ED), single-crystal structural analysis can be performed on very tiny crystals with sizes on the nanometer scale. Here, we analyze two framework materials, SU-8 and SU-68, with organic molecules inside their inorganic crystal structures. By applying 3D ED, with fast data collection and an ultralow electron dose (0.8-2.6 e - Å -2 ), we demonstrate for the first time that each nonhydrogen atom from the organic molecules can be ab initio located from structure solution, and they are shown as distinct and well-separated peaks in the difference electrostatic potential maps showing high accuracy and reliability. As a result, two different spatial configurations are identified for the same guest molecule in SU-8. We find that the organic molecules interact with the framework through strong hydrogen bonding, which is the key to immobilizing them at well-defined positions. In addition, we demonstrate that host-guest systems can be studied at room temperature. Providing high accuracy and reliability, we believe that 3D ED can be used as a powerful tool to study host-guest interactions, especially for nanocrystals.

Published

2022

42. Step-Assisted On-Surface Synthesis of Graphene Nanoribbons Embedded with Periodic Divacancies.

Author

Yin R, Wang J, Qiu ZL, Meng J, Xu H, Wang Z, Liang Y, Zhao XJ, Ma C, Tan YZ, Li Q, and Wang B

Abstract

The bottom-up approach through on-surface synthesis of porous graphene nanoribbons (GNRs) presents a controllable manner for implanting periodic nanostructures to tune the electronic properties of GNRs in addition to bandgap engineering by width and edge configurations. However, owing to the existing steric hindrance in small pores like divacancies, it is still difficult to embed periodic divacancies with a nonplanar configuration into GNRs. Here, we demonstrate the on-surface synthesis of atomically precise eight-carbon-wide armchair GNRs embedded with periodic divacancies (DV8-aGNRs) by utilizing the monatomic step edges on the Au(111) surface. From a single molecular precursor correspondingly following a trans - and cis -coupling, the DV8-aGNR and another porous nanographene are respectively formed at step edges and on terraces at 720 and 570 K. Combining scanning tunneling microscopy/spectroscopy, atomic force microscopy, and first-principles calculations, we determine the out-of-plane conformation, wide bandgap (∼3.36 eV), and wiggly shaped frontier orbitals of the DV8-aGNR. Nudged elastic band calculations further quantitatively reveal that the additional steric hindrance effect in the cyclodehydrogenative reactions has a higher barrier of 1.3 eV than that in the planar porous nanographene, which also unveils the important role played by the monatomic Au step and adatoms in reducing the energy barriers and enhancing the thermodynamic preference of the oxidative cyclodehydrogenation. Our results provide the first case of GNRs containing periodic pores as small as divacancies with a nonplanar configuration and demonstrate the strategy by utilizing the chemical heterogeneity of a substrate to promote the formation of novel carbon nanomaterials.

Published

2022

43. Cooperative Catalysis of Vibrationally Excited CO 2 and Alloy Catalyst Breaks the Thermodynamic Equilibrium Limitation.

Author

Kim DY, Ham H, Chen X, Liu S, Xu H, Lu B, Furukawa S, Kim HH, Takakusagi S, Sasaki K, and Nozaki T

Abstract

Using nonthermal plasma (NTP) to promote CO 2 hydrogenation is one of the most promising approaches that overcome the limitations of conventional thermal catalysis. However, the catalytic surface reaction dynamics of NTP-activated species are still under debate. The NTP-activated CO 2 hydrogenation was investigated in Pd 2 Ga/SiO 2 alloy catalysts and compared to thermal conditions. Although both thermal and NTP conditions showed close to 100% CO selectivity, it is worth emphasizing that when activated by NTP, CO 2 conversion not only improves more than 2-fold under thermal conditions but also breaks the thermodynamic equilibrium limitation. Mechanistic insights into NTP-activated species and alloy catalyst surface were investigated by using in situ transmission infrared spectroscopy, where catalyst surface species were identified during NTP irradiation. Moreover, in in situ X-ray absorption fine-structure analysis under reaction conditions, the catalyst under NTP conditions not only did not undergo restructuring affecting CO 2 hydrogenation but also could clearly rule out catalyst activation by heating. In situ characterizations of the catalysts during CO 2 hydrogenation depict that vibrationally excited CO 2 significantly enhances the catalytic reaction. The agreement of approaches combining experimental studies and density functional theory (DFT) calculations substantiates that vibrationally excited CO 2 reacts directly with hydrogen adsorbed on Pd sites while accelerating formate formation due to neighboring Ga sites. Moreover, DFT analysis deduces the key reaction pathway that the decomposition of monodentate formate is promoted by plasma-activated hydrogen species. This work enables the high designability of CO 2 hydrogenation catalysts toward value-added chemicals based on the electrification of chemical processes via NTP.

Published

2022

44. Nitrogen-Embedded Quintuple [7]Helicene: A Helicene-Azacorannulene Hybrid with Strong Near-Infrared Fluorescence.

Author

Wu YF, Ying SW, Su LY, Du JJ, Zhang L, Chen BW, Tian HR, Xu H, Zhang ML, Yan X, Zhang Q, Xie SY, and Zheng LS

Abstract

Herein, a nitrogen-embedded quintuple [7]helicene ( N-Q7H ) with an azapentabenzocorannulene core, which can be considered to be a helicene/azacorannulene hybrid π-system, was synthesized from azapentabenzocorannulene in a three-step process. N-Q7H is the first example of a multiple helicene with an azabuckybowl core. Single-crystal X-ray diffractometry unambiguously confirmed the structure of the propeller-shaped hybrid π-system. Owing to nitrogen-atom doping in the multiple helicenes and effective hybridization between the helicene and azacorannulene, N-Q7H exhibits considerably redshifted absorption and emission (yellow-to-green color change and green-to-near-infrared fluorescence change) relative to the azapentabenzocorannulene core. The broad absorption from the ultraviolet-visible to the NIR region is ascribable to the allowed transition between the highest occupied molecular orbital and the lowest unoccupied molecular orbital after symmetry breaking, as revealed by density functional theory calculations. Compared to previous propeller-shaped multiple helicenes with corannulene or hexabenzocoronene (etc.) as cores, N-Q7H demonstrates a significantly higher NIR fluorescence quantum efficiency of 28%. Additionally, the chiral-resolution and redox properties of N-Q7H were investigated. The excellent photophysical and inherent chiral properties of N-Q7H suggest that azapentabenzocorannulene can be used as an outstanding nitrogen-embedded core to construct novel multiple helicenes with wide application potential, including as NIR fluorescent bio-probes.

Published

2022

45. Stereoselective 1,2- cis Furanosylations Catalyzed by Phenanthroline.

Author

Xu H, Schaugaard RN, Li J, Schlegel HB, and Nguyen HM

Subjects

Catalysis, Glycosylation, Stereoisomerism, Bromides, Phenanthrolines

Abstract

Stereoselective formation of the 1,2- cis furanosidic linkage, a motif of many biologically relevant oligosaccharides and polysaccharides, remains an important synthetic challenge. We herein report a new stereoselective 1,2- cis furanosylation method promoted by phenanthroline catalysts under mild and operationally simple conditions. NMR experiments and density functional theory calculations support an associative mechanism in which the rate-determining step occurs from an inverted displacement of the faster-reacting phenanthrolinium ion intermediate with an alcohol nucleophile. The phenanthroline catalysis system is applicable to a number of furanosyl bromide donors to provide the challenging 1,2- cis substitution products in good yield with high anomeric selectivities. While arabinofuranosyl bromide provides β-1,2- cis products, xylo- and ribofuranosyl bromides favor α-1,2- cis products.

Published

2022

46. Engineering Photomechanical Molecular Crystals to Achieve Extraordinary Expansion Based on Solid-State [2 + 2] Photocycloaddition.

Author

Xu TY, Tong F, Xu H, Wang MQ, Tian H, and Qu DH

Subjects

Crystallization methods, Molecular Structure, Photochemistry methods, Engineering, Light

Abstract

Photomechanical molecular crystals are promising candidates for photoactuators and can potentially be implemented as smart materials in various fields. Here, we synthesized a new molecular crystal, ( E )-3-(naphthalen-1-yl)acrylaldehyde malononitrile (( E )- NAAM ), that can undergo a solid-state [2 + 2] photocycloaddition reaction under visible light (≥400 nm) illumination. ( E )- NAAM microcrystals containing symmetric twinned sealed cavities were prepared using a surfactant-mediated crystal seeded growth method. When exposed to light, the hollow microcrystals exhibited robust photomechanical motions, including bending and dramatic directional expansion of up to 43.1% elongation of the original crystal length before fragmentation due to the photosalient effect. The sealed cavities inside the microcrystals could store different aqueous dye solutions for approximately one month and release the solutions instantly upon light irradiation. A unique slow-fast-slow crystal elongation kinematic process was observed, suggesting significant molecular rearrangements during the illumination period, leading to an average anisotropic crystal elongation of 37.0% (±3.8%). The significant molecular structure and geometry changes accompanying the photocycloaddition reaction, which propels photochemistry to nearly 100% completion, also facilitate photomechanical crystal expansion. Our results provide a possible way to rationally design molecular structures and engineer crystal morphologies to promote more interesting photomechanical behaviors.

Published

2022

47. Overcoming Efficiency Limitation of Cluster Light-Emitting Diodes with Asymmetrically Functionalized Biphosphine Cu 4 I 4 Cubes.

Author

Zhang N, Hu H, Qu L, Huo R, Zhang J, Duan C, Meng Y, Han C, and Xu H

Abstract

Electroluminescent (EL) nanoclusters holding promise for new-generation cluster light-emitting devices (CLEDs) rapidly emerge. However, slow radiation and serious quenching of cluster emitters largely limit the device performance. Herein, we report two monofunctionalized biphosphine chelated Cu 4 I 4 clusters [DMACDBFDP] 2 Cu 4 I 4 and [DPACDBFDP] 2 Cu 4 I 4 . The asymmetric modification and electron-donating effect of acridine groups lead to the iodine-to-ligand charge transfer predominant excited states of the clusters, which feature thermally activated delayed fluorescence with markedly improved singlet radiative rate constants and reduced triplet nonradiative rate constants. As consequence, compared to the nonfunctionalized parent cluster, [DPACDBFDP] 2 Cu 4 I 4 achieves 16-fold increased photoluminescence (81%) and 20-fold increased EL (19.5%) quantum efficiencies . Such new-record efficiencies make CLEDs achieve the state-of-the-art performance of all kinds of EL technologies.

Published

2022

48. Degradation Chemistry and Kinetic Stabilization of Magnetic CrI 3 .

Author

Zhang T, Grzeszczyk M, Li J, Yu W, Xu H, He P, Yang L, Qiu Z, Lin H, Yang H, Zeng J, Sun T, Li Z, Wu J, Lin M, Loh KP, Su C, Novoselov KS, Carvalho A, Koperski M, and Lu J

Abstract

The discovery of the intrinsic magnetic order in single-layer chromium trihalides (CrX 3 , X = I, Br, and Cl) has drawn intensive interest due to their potential application in spintronic devices. However, the notorious environmental instability of this class of materials under ambient conditions renders their device fabrication and practical application extremely challenging. Here, we performed a systematic investigation of the degradation chemistry of chromium iodide (CrI 3 ), the most studied among CrX 3 families, via a joint spectroscopic and microscopic analysis of the structural and composition evolution of bulk and exfoliated nanoflakes in different environments. Unlike other air-sensitive 2D materials, CrI 3 undergoes a pseudo-first-order hydrolysis in the presence of pure water toward the formation of amorphous Cr(OH) 3 and hydrogen iodide (HI) with a rate constant of k I = 0.63 day -1 without light. In contrast, a faster pseudo-first-order surface oxidation of CrI 3 occurs in a pure O 2 environment, generating CrO 3 and I 2 with a large rate constant of k Cr = 4.2 day -1 . Both hydrolysis and surface oxidation of CrI 3 can be accelerated via light irradiation, resulting in its ultrafast degradation in air. The new chemical insights obtained allow for the design of an effective stabilization strategy for CrI 3 with preserved optical and magnetic properties. The use of organic acid solvents ( e.g. , formic acid) as reversible capping agents ensures that CrI 3 nanoflakes remain stable beyond 1 month due to the effective suppression of both hydrolysis and oxidation of CrI 3 .

Published

2022

49. Dispersion and Steric Effects on Enantio-/Diastereoselectivities in Synergistic Dual Transition-Metal Catalysis.

Author

Li B, Xu H, Dang Y, and Houk KN

Abstract

Comprehensive computational studies were carried out to explore the mechanisms of enantioselective Cu/Pd and stereodivergent Cu/Ir dual-catalytic syntheses of α,α-disubstituted α-amino acids (α-AAs). A chiral copper azomethine ylide undergoes facile α-allylation with racemic π-allylpalladium species or stereopure π-allyliridium complex to stereoconvergently or stereodivergently furnish single/double stereocenters, respectively. Stereoselectivity at the α-center is controlled by the facial selectivity of α-allylation with respect to the prochiral nucleophile. Despite apparently similar transition-state assemblies, computational models and distortion/interaction analyses disclose versatile modes of stereoinduction wherein the copper azomethine ylide species can face-selectively intercept metal-π-allyl intermediates utilizing attractive dispersion interactions and/or sterically caused distortions. Generation of the β-stereocenter in the Cu/Ir system relies on a stereospecifically generated allyliridium complex and electronically controlled branched-to-linear selectivity, while the dual Cu/Pd system yields a linear monochiral product due to steric factors and π-π stacking interactions. The studies demonstrate on a molecular level how ligand-encoded chiral information is transferred to the α-/β-sites of the resulting α-AAs and how the mode of regio-/stereoselection is altered by differences in transition-metal-stabilized coupling partners. To facilitate studies of stereoselective catalysis, a suite of analytical tools to extract controlling factors for asymmetric induction is demonstrated.

Published

2022

50. "Open" Nonporous Nonasil Zeolite Structure for Selective Catalysis.

Author

Lu K, Fan Y, Huang J, Wang J, Xu H, Jiang J, Ma Y, and Wu P

Abstract

Nonasil (NON-type framework) zeolite, having inner large cages but only 6-ring (R) apertures, is recognized as a nonporous material without practical application values as catalysts or adsorbents. A novel bottom-up structural construction strategy assisted with well-designed Gemini-type surfactant is proposed to "open" the non cages, constructing two novel NON-related structures with accessible and stable acid sites. The obtained derivant (named as ECNU-27) possessed hierarchical porosity with short-range ordered 8-R micropores and abundant intercrystal mesopores, serving as a promising catalyst for the 1-butene cracking to lower alkenes.

Published

2021