Publications by authors named "Zhaolin Shi"

Elucidating the synergistic catalytic mechanism between multiple active centers is of great significance for heterogeneous catalysis; however, finding the corresponding experimental evidence remains challenging owing to the complexity of catalyst structures and interface environment. Here we construct an asymmetric TeN-CuN double-atomic site catalyst, which is analyzed via full-range synchrotron pair distribution function. In electrochemical CO reduction, the catalyst features a synergistic mechanism with the double-atomic site activating two key molecules: operando spectroscopy confirms that the Te center activates CO, and the Cu center helps to dissociate HO.

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  • The study explores enolimine-ketoenamine tautomerism to create 2D covalent organic frameworks (COFs) with enhanced chemical durability and photoelectronic performance.
  • It faces challenges in controlling tautomeric states and understanding how these structures affect photoelectronic properties due to the dynamic nature of proton transfer.
  • The researchers developed a 3D dynamic COF (dynaCOF-301) that stabilizes and switches its tautomeric forms via structural transformations and interactions with guest molecules, enabling effective chemosensing.
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  • - Molecular recognition is key for creating sensitive sensors for volatile organic compounds (VOCs), but designing porous solids for gas detection requires a careful balance of flexibility and durability.
  • - Researchers developed a dynamic 3D covalent organic framework (dynaCOF) that uses a special fluorescent material to change structure when exposed to different gases, enabling quick detection of various VOCs, even in humid conditions.
  • - This framework enhances interactions between the sensor and the gases, allowing for differentiation based on the polarity and shape of the organic vapours, contributing to advanced multiplex fluorescence sensing capabilities.
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  • Three-membered rings play a key role in zeolite chemistry, specifically in designing zeolitic imidazolate frameworks (ZIFs), but their formation has been largely accidental in the past.
  • This study introduces a method for creating four new ZIFs (ZIF-1001 to -1004) using tetrahedral zinc centers, a specific linker (benzotriazolate), and functionalized benzimidazolates, resulting in a unique NPO-type topology.
  • The new ZIFs can effectively capture carbon dioxide from high-humidity flue gas and isolate ethane during shale gas extraction processes.
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Metal-organic framework (MOF) glasses are a fascinating new class of materials, yet their prosperity has been impeded by the scarcity of known examples and limited vitrification methods. In the work described in this report, we applied synergistic stimuli of vapor hydration and thermal dehydration to introduce structural disorders in interpenetrated -net MOF, which facilitate the formation of stable super-cooled liquid and quenched glass. The material after stimulus has a glass transition temperature () of 560 K, far below the decomposition temperature of 695 K.

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For heterogeneous catalysts, the active sites exposed on the surface have been investigated intensively, yet the effect of the subsurface-underlying atoms is much less scrutinized. Here, a surface-engineering strategy to dope Ru into the subsurface/surface of Co matrix is reported, which alters the electronic structure and lattice strain of the catalyst surface. Using hydrogen evolution (HER) as a model reaction, it is found that the subsurface doping Ru can optimize the hydrogen adsorption energy and improve the catalytic performance, with overpotentials of 28 and 45 mV at 10 mA cm in alkaline and acidic media, respectively, and in particular, 28 mV in neutral electrolyte.

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  • Stimuli-responsive metal-organic frameworks (MOFs) can change their structure and gas adsorption properties when exposed to external factors like temperature.
  • A specific MOF, identified as ·[CuCl], can switch from a rigid to a flexible phase due to a temperature change, altering its gas adsorption behavior significantly.
  • This structural change is driven by a new mechanism that modifies the coordination and geometry of copper ions within the framework, allowing the MOF to express its inherent flexibility.
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  • A new metal docking method was developed using organic structures to precisely arrange metal chelating sites in a metal-organic framework (MOF).
  • The study focused on MOF-303, which utilized uncoordinated nitrogen atoms to bond with Cu and Ag, creating new metalated compounds.
  • The resulting Ag-MOF-303 showed excellent capability for capturing xenon from mixtures and ranked high in performance, with a significant uptake capacity and selectivity.
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The mutable structures of metal-organic frameworks (MOFs) allow their use as novel supports for transition metal catalysts. Herein we prepare an iridium bis(ethylene) catalyst bound to the neutral N-donors of a MOF structure and show that the compound is a stable gas phase ethylene hydrogenation catalyst. The data illustrate the need to carefully consider the inner sphere (support) and outer sphere (anion) chemistry.

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  • Researchers developed new metal-organic frameworks (MOFs) that are stable in harsh conditions for capturing CO from flue gas, which includes water vapor and acidic gases.
  • The MOFs are enhanced by adding amino groups to their structure, resulting in strong resistance to both acidic and basic environments.
  • One of the MOFs shows excellent performance with high selectivity for CO over other gases, low energy needs for regeneration, and effective CO capture even in humid conditions.
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The function of allosteric enzymes can be activated or inhibited through binding of specific effector molecules. Herein, we describe how the skeletal deformation, pore configuration, and ultimately adsorptive behavior of a dynamic metal-organic framework (MOF), (Me NH )[In(atp)] (in which atp=2-aminoterephthalate), are controlled by the allocation and orientation of its counter ions triggered by the inclusion/removal of different guest molecules. The power of such allosteric control in MOFs is highlighted through the optimization of the hydrocarbon separation performance by achieving multiple pore configurations but without altering the chemical composition.

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  • The separation of ethane from ethylene is crucial for purifying chemical feedstocks, but it’s challenging due to their similar properties.
  • High-performance porous adsorbents like MUF-15 can efficiently separate these gases by preferentially adsorbing ethane over ethylene in a single step.
  • MUF-15, made from inexpensive materials, can produce 14 liters of high-purity ethylene from 1 kg of adsorbent, is robust against interference from acetylene, and can be easily regenerated for repeated use.
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  • - The study focuses on creating a complex porous metal-organic framework (MOF) called FDM-8, which involves a systematic arrangement of various components to enhance their functional properties.
  • - FDM-8 is developed through self-assembly using two metals (Zn and Cu) and three different linkers, requiring careful design and precise control for successful crystallization.
  • - This MOF has a high surface area of 3643 m²/g, features hierarchical pores, and demonstrates impressive methane-storage capabilities, with organized functional groups strategically placed within its structure for improved performance.
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Guest-dependent dynamics having both crystal contraction and expansion upon inclusion of various guests is uncovered in a 3D covalent organic framework (COF) prepared with a facile and scalable method. A molecular-level understanding of how the framework adjusts the node geometry and molecular configuration to perform significant contraction and large amplitude expansion are resolved through synchrotron in-house powder X-ray diffraction (PXRD) and Rietveld refinements. We found that the COF adopts a contracted phase at ambient conditions upon capturing moisture and is also adaptive upon inclusion of organic solvents, which is highlighted by a large crystal expansion (as large as 50% crystallographic volume increment and a 3-fold channel size enlargement).

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Mesoporous ZnO(-COO)-based metal-organic frameworks (MOFs), including UMCM-1, MOF-205, MUF-7a, and the newly synthesized MOFs, termed ST-1, ST-2, ST-3, and ST-4 (ST = ShanghaiTech University), have been systematically investigated for ultrahigh capacity methane storage. Exceptionally, ST-2 was found to have the highest deliverable capacity of 289 cm/cm (567 mg/g) at 298 K and 5-200 bar, which surpasses all previously reported records held by porous materials. We illustrate that the fine-tuned mesoporosity is critical in further improving the deliverable capacities at ultrahigh pressure.

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