Your search keyword '"Gan, W."' showing total 49 results

1. Role of chlorine dioxide in NDMA formation from oxidation of model amines

Author

Gan, W, Bond, T, Yang, X, and Westerhoff, P

Published

2015

2. Identification of Active Molecules against Thrombocytopenia through Machine Learning.

Author

Yang Y, Gan W, Lin L, Wang L, Wu J, and Luo J

Subjects

Humans, Drug Discovery methods, Megakaryocytes metabolism, Megakaryocytes drug effects, Megakaryocytes cytology, Blood Platelets drug effects, Blood Platelets metabolism, Computer Simulation, Algorithms, Machine Learning, Thrombocytopenia drug therapy

Abstract

Thrombocytopenia, which is associated with thrombopoietin (TPO) deficiency, presents very limited treatment options and can lead to life-threatening complications. Discovering new therapeutic agents against thrombocytopenia has proven to be a challenging task using traditional screening approaches. Fortunately, machine learning (ML) techniques offer a rapid avenue for exploring chemical space, thereby increasing the likelihood of uncovering new drug candidates. In this study, we focused on computational modeling for drug-induced megakaryocyte differentiation and platelet production using ML methods, aiming to gain insights into the structural characteristics of hematopoietic activity. We developed 112 different classifiers by combining eight ML algorithms with 14 molecule features. The top-performing model achieved good results on both 5-fold cross-validation (with an accuracy of 81.6% and MCC value of 0.589) and external validation (with an accuracy of 83.1% and MCC value of 0.642). Additionally, by leveraging the Shapley additive explanations method, the best model provided quantitative assessments of molecular properties and structures that significantly contributed to the predictions. Furthermore, we employed an ensemble strategy to integrate predictions from multiple models and performed in silico predictions for new molecules with potential activity against thrombocytopenia, sourced from traditional Chinese medicine and the Drug Repurposing Hub. The findings of this study could offer valuable insights into the structural characteristics and computational prediction of thrombopoiesis inducers.

Published

2024

3. Wood Ion Pumps Enabled by Light-Responsive MoS 2 -Decorated Nanocellulosic Channels.

Author

Liu S, Yao Y, Li X, Tang J, Dong X, Wang Y, Yin R, Li J, Xie Y, and Gan W

Abstract

Light-driven active ion transport discovered in nanomaterials (e.g., graphene, metal-organic framework, and MXene) implicates crucial applications in membrane-based technology and energy conversion systems. However, it remains a challenge to achieve bulk assembly. Herein, we employ the scalable wood as a framework for in situ growth of MoS 2 nanosheets to facilitate light-responsive ion transport. Owing to the aligned and negatively charged wood nanochannels, the MoS 2 -decorated wood exhibits an excellent nanofluidic conductivity of 8.3 × 10 -5 S cm -1 in 1 × 10 -6 M KCl. Asymmetric light illumination creates the separation of electrons and holes in MoS 2 nanosheets, enabling ions to move uphill against a wide range of concentration gradients. As a result, the MoS 2 -decorated wood can pump ions uphill against a 20-fold concentration gradient at a light intensity of 300 mW cm -2 . When the illumination is applied to the opposite side, the osmotic current along the 20-fold concentration gradient can be enhanced to 75.1 nA, and the corresponding osmotic energy conversion power density increases to more than 12.6 times that of the nonilluminated state. Based on the light-responsive behaviors, we are extending the use of MoS 2 -decorated wood as the ionic elements for nanofluidic circuits, such as ion switches, ion diodes, and ion transistors. This work provides a facile and scalable strategy for fabricating light-controlled nanofluidic devices from biomass materials.

Published

2024

4. Temperature-Modulated Evolution of Surface Structures Induces Significant Enhancement of Two-Photon Fluorescent Emission from a Dye Molecule.

Author

Li J, Chen S, Xu B, He Z, Yuan Q, and Gan W

Abstract

Fluorescence is an essential property of molecules and materials that plays a pivotal role across various areas such as lighting, sensing, imaging, and other applications. For instance, temperature-sensitive fluorescence emission is widely utilized for chemo-/biosensing but usually decreases the intensity upon the increase in temperature. In this study, we observed a temperature-induced enhancement of up to ∼150 times in two-photon fluorescence (TPF) emission from a dye molecule, 4-(4-diethylaminostyry)-1-methylpyridinium iodide (D289), as it interacted with binary complex vesicles composed of two commonly applied surfactants: sodium dodecyl sulfate (SDS) and cetyltrimethylammonium bromide (CTAB). By employing second harmonic generation (SHG) and TPF techniques, we clearly revealed the temperature-dependent kinetic behavior of D289 on the surface of the vesicles and utilized it to interpret the origin of the significant TPF enhancement. Additionally, we also demonstrated a similar heating-induced enhancement of the TPF emission from D289 on the membrane of phospholipid vesicles, indicating the potential application of TPF in temperature sensing in the biology systems. The embedding of D289 in the tightly packed alkane chains was identified as the key factor in enhancing the TPF emission from D289. This finding may provide valuable information for synthesizing fluorescence materials with a high optical yield.

Published

2024

5. Symmetry-Reduction Enhanced Polarization-Sensitive Photoresponse Based on One-Dimensional van der Waals Materials.

Author

Gan W, Liu Y, Liu X, Xiao R, Ni K, Jiang M, Han H, Zhou X, Li S, Wu C, Li Y, and Li H

Abstract

Designing high-performance polarization-sensitive photodetectors is essential for photonic device applications. Anisotropic one-dimensional (1D) van der Waals (vdW) materials have provided a promising platform to that end. Despite significant advances in 1D vdW photonic devices, their performance is still far from delivering practical potential. Herein, we propose the design of high-performance polarization-sensitive photodetectors using unique 1D vdW materials. By leveraging the chemical vapor transport technique, we successfully fabricate high-quality 1D vdW Nb 2 Pd 1- x Se 5 ( x = 0.29) nanowires. The 1D vdW Nb 2 Pd 1- x Se 5 photodetector exhibits a high mobility of ∼56 cm 2 /(V s) and superior photoresponse performance, including a high responsivity of 1A/W and an ultrafast response time of ∼8 μs under 638 nm illumination. Moreover, the 1D vdW Nb 2 Pd 1- x Se 5 photodetector demonstrates excellent polarization-sensitive photoresponse with a degree of linear polarization (DOLP) up to 0.85 and can be modulated by adjusting the gate voltage, laser power density, and wavelength. Those exceptional performance are believed to be relevant to the symmetry-reduction induced by the partial occupation of Pd sites. This study offers feasible approaches to enhance the anisotropy of 1D vdW materials and the modulation of their polarization-sensitive photoresponse, which may provide deep insights into the physical origin of anisotropic properties of 1D vdW materials.

Published

2024

6. Amide and Multihydroxyl Complementary Tailored Metal-Organic Framework with Enhanced Glycan Affinity for Efficient Glycoproteomic Analysis.

Author

Yang Z, Gan W, Dai L, Zhang H, Zhang Y, Yang Q, Feng Y, Yang J, Fu C, and Li D

Subjects

Humans, Amides, Glycoproteins, Polysaccharides, Glycopeptides chemistry, Hydrophobic and Hydrophilic Interactions, Metal-Organic Frameworks chemistry, Diabetes Mellitus, Type 2

Abstract

Protein glycosylation is ubiquitous and crucial for regulating biological processes in organisms. Given the heterogeneity and low abundance of glycoproteins, efficient and specific enrichment procedures are required for the mass spectrometry analysis of glycopeptides. Hydrophilic interaction liquid chromatography (HILIC) has emerged as an effective strategy for glycopeptide enrichment. However, the relatively weak hydrophilic affinity restricts the achievement of a satisfactory enrichment performance. Here, we presented a rational design of an amide and multihydroxyl complementary tailored metal-organic framework, denoted as U6N/Pv@Glc, which exhibited ultrahydrophilicity and enhanced glycan affinity. Our results demonstrated a significant increase in glycopeptide coverage after enrichment, accompanied by extremely low detection limits (0.05 fmol μL -1 ) and high selectivity (IgG/BSA, 1:4000) as evaluated using trypsin-digested standard glycoproteins. A total of 379 glycopeptides and 247 intact glycopeptides (containing a total of 1577 site-specific N -glycans) were identified and characterized within human serum samples from individuals with type 2 diabetes in-depth. Additionally, we extended the application of this material to capture undigested glycoproteins, demonstrating potential compatibility with top-down MS analysis. These results highlight the promising potential of this novel material for comprehensive glycoproteomic analysis of every potential aspect.

Published

2024

7. MXene Clay (Ti2C)-Containing In Situ Polymerized Hollow Core-Shell Binder for Silicon-Based Anodes in Lithium-Ion Batteries.

Author

Tian M, Gan W, and Oh ES

Abstract

Silicon, an attractive anode material, suffers fast capacity fading due to the electrical isolation from massive volumetric expansion upon cycling. However, it holds a high theoretical capacity and low operation voltage in its practical application. In this study, a new water-based binder, MXene clay/hollow core-shell acrylate composite, was synthesized through an in situ emulsion polymerization technique to alleviate the fast capacity fading of the silicon anode efficiently. The efficient introduction of conductive MXene clay and the hollow core-shell structure, favorable to electron and ion transport in silicon-based electrodes, gives a novel conceptual design of the binder material. Such a strategy could alleviate electrical isolation after cycling and promises better electrochemical performance of the high-capacity anodes. The effect of the MXene introduction and hollow core-shell on the binder performance is thoroughly investigated using various characterization tools by comparison with no MXene-containing, core-shell acrylate, and commercial styrene-butadiene latex binders. Consequently, the silicon-based electrode containing the MXene clay/hollow core-shell acrylate binder exhibits a high capacity retention of 1351 mAh g -1 at 0.5C after 100 cycles and good rate capability of over 1100 mAh g -1 at 5C., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published

2023

8. What Determines If a Ligand Undergoes Coordination or Catalytic Activation on a Metal Cluster?

Author

Gan W, Huang B, Hansen K, and Luo Z

Abstract

We report a joint experimental and theoretical study on the reactivity of Ag n + clusters with H 2 S, D 2 O, and NH 3 . Complete dehydrogenation products are observed for Ag n + reacting with H 2 S, but no dehydrogenation products are found for D 2 O or NH 3 under the same reaction condition. Theoretical calculations elucidate why Ag n + clusters show different reactivities with these inorganic hydrides. NH 3 shows strong coordination with Ag n + , but the dehydrogenation reactions are unfavorable; in contrast, the fragile H-S bonds and stable Ag n S + products facilitate the hydrogen evolution of H 2 S on Ag n + . We fully analyzed the metal-ligand interactions of Ag n + clusters with three molecules and illustrated the reaction dynamics and charge-transfer interactions and altered the superatomic states during the formation of cluster sulfides. We expect this study to benefit the design of stable environmentally friendly desulfurization catalysts and also the understanding of the mechanism on ligand-protected metal clusters in wet chemistry.

Published

2023

9. Programmable, Changeable, Origami Cellulose Films for Magnetically Controllable Soft Robots.

Author

Li X, Shang Z, Wang Y, Liu J, Xie Y, Li J, Liu Y, and Gan W

Abstract

Magnetic soft robots composed of stimuli-responsive materials are promising for biomedical engineering applications; however, typical responsive materials are fabricated with nondegradable polymeric substrates. In this study, we report a flexible, biodegradable, and magnetically sensitive cellulose film (M-film) that can be utilized for magnetically controllable soft robots (M-robots) with programmable locomotion, cargo delivery, and remote wireless operation functions. The M-film with good foldability, origami, and magnetic properties is synthesized by a simple paper-making process using cellulose nanofibers, additive sodium alginate, and BaFe 12 O 19 particles. Through the following origami-magnetization process, the M-robot with multimodal movements is designed: climbing over the obstacles in the walking environment; additionally, this process can complete various cargo transport tasks by clawing, rolling, and flipping. This approach expands the precise controllability and manipulability of environmentally friendly cellulose nanomaterials beyond the known applications and opens the prospects of their implementation in stimuli-responsive robots, wireless control electronics, and intelligent devices.

Published

2023

10. Multifunctional AIE Nanosphere-Based "Nanobomb" for Trimodal Imaging-Guided Photothermal/Photodynamic/Pharmacological Therapy of Drug-Resistant Bacterial Infections.

Author

Li B, Wang W, Zhao L, Yan D, Li X, Gao Q, Zheng J, Zhou S, Lai S, Feng Y, Zhang J, Jiang H, Long C, Gan W, Chen X, Wang D, Tang BZ, and Liao Y

Subjects

Humans, Light, Diagnostic Imaging, Theranostic Nanomedicine methods, Nanospheres, Photochemotherapy, Bacterial Infections diagnostic imaging, Bacterial Infections drug therapy, Nanoparticles therapeutic use

Abstract

Injudicious or inappropriate use of antibiotics has led to the prevalence of drug-resistant bacteria, posing a huge menace to global health. Here, a self-assembled aggregation-induced emission (AIE) nanosphere (AIE-PEG 1000 NPs) that simultaneously possesses near-infrared region II (NIR-II) fluorescence emissive, photothermal, and photodynamic properties is prepared using a multifunctional AIE luminogen (AIE-4COOH). The AIE-PEG 1000 NPs were encapsulated with teicoplanin (Tei) and ammonium bicarbonate (AB) into lipid nanovesicles to form a laser-activated "nanobomb" (AIE-Tei@AB NVs) for the multimodal theranostics of drug-resistant bacterial infections. In vivo experiments validate that the "nanobomb" enables high-performance NIR-II fluorescence, infrared thermal, and ultrasound (AB decomposition during the photothermal process to produce numerous CO 2 /NH 3 bubbles, which is an efficient ultrasound contrast agent) imaging of multidrug-resistant bacteria-infected foci after intravenous administration of AIE-Tei@AB NVs followed by 660 nm laser stimulation. The highly efficient photothermal and photodynamic features of AIE-Tei@AB NVs, combined with the excellent pharmacological property of rapidly released Tei during bubble generation and NV disintegration, collectively promote broad-spectrum eradication of three clinically isolated multidrug-resistant bacteria strains and rapid healing of infected wounds. This multimodal imaging-guided synergistic therapeutic strategy can be extended for the theranostics of superbugs.

Published

2023

11. A Novel Hierarchical Structure of SnCu 2 Se 4 /d-Ti 3 C 2 T x /NPC for a Lithium/Sodium Ion Battery and Hybrid Capacitor with Long-Term Cycling Stabilities.

Author

Wang H, Wang Y, Liu Y, Dou S, Gan W, and Yuan Q

Abstract

To alleviate kinetics imbalance and capacity insufficiency simultaneously, a novel hierarchical structure (SnCu 2 Se 4 /d-Ti 3 C 2 T x /NPC) composed of delaminated Ti 3 C 2 T x , SnCu 2 Se 4 nanoparticles, and N-doped porous carbon layers is designed as a battery-type anode for lithium/sodium ion hybrid capacitor (LIC/SIC). The combination of SnCu 2 Se 4 nanoparticles with high specific capacity, d-Ti 3 C 2 T x with accelerated ion diffusion path, and NPC with enhanced electronic conductivity makes the SnCu 2 Se 4 /d-Ti 3 C 2 T x /NPC composite possess excellent cycling stabilities in half-cell lithium-ion and sodium-ion batteries (LIB and SIB), with capacities of 114 mAh g -1 after 6000 cycles at 10 A g -1 for LIB and 296 mAh g -1 after 900 cycles at 1.0 A g -1 for SIB. The rate performance is also outstanding, with recovered capacity of 738 mAh g -1 at 0.1 A g -1 after cycles at current densities up to 50 A g -1 for LIB. Subsequently, LIC and SIC based on the SnCu 2 Se 4 /d-Ti 3 C 2 T x /NPC anode and activated carbon cathode exhibit high energy densities of 147.9 and 158.6 Wh kg -1 at a power density of 100 W kg -1 , respectively. They also possess distinctive long lifespans with capacity retentions of 78 and 81% after 10,000 cycles at 1.0 A g -1 , respectively, demonstrating the feasibility of SnCu 2 Se 4 /d-Ti 3 C 2 T x /NPC toward energy devices requiring high energy density, power density, and long-term stability.

Published

2022

12. What Determines the Drastic Reactivity of Nb n + Clusters with Nitric Oxide under Thermalized Conditions?

Author

Huang B, Gan W, Hansen K, and Luo Z

Abstract

We report an in-depth study of the adsorption and reaction of NO with cationic Nb n + ( n = 1-20) clusters under thermalized conditions in a laminar flow tube reactor in tandem with a customized triple quadrupole mass spectrometer (FT-TQMS). It is found that the small-sized Nb n + clusters (2 ≤ n ≤ 7) readily react with NO giving rise to dominant fragmentation products pertaining to the loss of a stable diatomic molecule NbO or NbN. In contrast, the reaction products of larger-sized clusters ( n ≥ 10) proceed through diverse channels, including NO adsorption, N 2 /N 2 O release, and even NO 2 formation. These experimental observations provided the incentive for us to dig deep into the reaction mechanism with the help of DFT calculations. In contrast to the NO-donation coordination in transition metal complexes, here the cationic Nb n + clusters exhibit dominant electronic donation in initiating the reactions with NO molecules. We fully demonstrated the reaction rate constants, compared the reaction energy diagram of typical Nb n + clusters, and unveiled the distinct interaction mechanism of niobium clusters available for NO activation and conversion.

Published

2022

13. Gas-Phase Synthesis of Metal Olefins: Plasma-Assisted Methane Dehydrogenation and C═C Bond Formation.

Author

Guo M, Yi Q, Cui C, Gan W, and Luo Z

Abstract

Methane dehydrogenation and C-C coupling under mild conditions are very important but challenging in chemistry. Utilizing a customized time of flight mass spectrometer combined with a magnetron sputtering (MagS) cluster source, here, we have conducted a study on the reactions of methane with small silver and copper clusters simply by introducing methane in argon as the working gas for sputtering. Interestingly, a series of [ M (C n H 2 n )] + ( M = Cu and Ag; n = 2-12) clusters were observed, indicating high-efficiency methane dehydrogenation in such a plasma-assisted chamber system. Density functional theory calculations find the lowest energy structures of the [ M (C n H 2 n )] + series pertaining to olefins indicative of both C-H bond activation of methane and C-C bond coupling. We analyzed the interactions involved in the [Cu(C n H 2 n )] + and [Ag(C n H 2 n )] + ( n = 1-6) clusters and demonstrated the reaction coordinates for the "Cu + + CH 4 " and "Ag + + CH 4 ." It is illustrated that the presence of a second methane molecule enables us to reduce the necessary energy of dehydrogenation, which concurs with the experimental observation of an absence of the metal carbine products Cu + CH 2 and Ag + CH 2 , which are short-lived. Also, it is elucidated that the higher-lying excitation states of Cu + and Ag + ions enable more favorable dehydrogenation process and C═C bond formation, shedding light on the plasma assistance of the essence.

Published

2022

14. Cyclotrimerization of Acetylene on Clusters Co n + /Fe n + /Ni n + ( n = 1-16).

Author

Gan W, Geng L, Yin B, Zhang H, Luo Z, and Hansen K

Abstract

Cyclotrimerization of acetylene to benzene has attracted significant interest, but the role of geometric and electronic effects on catalytic chemistry remains unclear. To fully elucidate the mechanism of catalytic acetylene-to-benzene conversion, we have performed a gas-phase reaction study of the Fe n + , Co n + , and Ni n + ( n = 1-16) clusters with acetylene utilizing a customized mass spectrometer. It is found that their reactions with acetylene are initiated by C 2 H 2 molecular adsorption and allow for dominant dehydrogenation with the relatively low partial pressure of the acetylene gas. However, at high acetylene concentrations, the cyclotrimerization in M n + + 3C 2 H 2 (M = Fe, Co, Ni) becomes the dominant reaction channel. We demonstrate theoretically the favorable thermodynamics and reaction dynamics leading to the formation of the M + (C 6 H 6 ) products. The results are discussed in terms of a cluster-catalyzed multimolecule synergistic effect and the cation-π interactions.

Published

2021

15. Unveiling the Molecular Dynamics in a Living Cell to the Subcellular Organelle Level Using Second-Harmonic Generation Spectroscopy and Microscopy.

Author

Li B, Li J, Gan W, Tan Y, and Yuan Q

Subjects

Humans, Microscopy, Molecular Dynamics Simulation, Organelles, Spectrum Analysis, Second Harmonic Generation Microscopy

Abstract

Second-harmonic generation (SHG) microscopy has been proved to be a powerful method for investigating the structures of biomaterials. SHG spectra were also generally used to probe the adsorption and cross-membrane transport of molecules on lipid bilayers in situ and in real time. In this work, we applied SHG and two-photon fluorescence (TPF) spectra to investigate the dynamics of an amphiphilic ion with an SHG and TPF chromophore, D289 (4-(4-diethylaminostyry)-1-methyl-pyridinium iodide), on the surface of human chronic myelogenous leukemia (K562) cells and the subcellular structures inside the cells. The adsorption and cross-membrane transport of D289 into the cells and then into the organelles such as mitochondria were revealed. SHG images were also recorded and used to demonstrate their capability of probing molecular dynamics in organelles in K562 cells. This work demonstrated the first SHG investigation of the cross-membrane transport dynamics on the surface of subcellular organelles. It may also shed light on the differentiation of different types of subcellular structures in cells.

Published

2021

16. Strain-Mediated Spin-Orbit Torque Enhancement in Pt/Co on Flexible Substrate.

Author

Hwee Wong GD, Xu Z, Gan W, Ang CCI, Law WC, Tang J, Zhang W, Wong PKJ, Yu X, Xu F, Wee ATS, Seet CS, and Lew WS

Abstract

Current-induced magnetization switching by spin-orbit torque generated in heavy metals offers an enticing realm for energy-efficient memory and logic devices. The spin Hall efficiency is a key parameter in describing the generation of spin current. Recent findings have reported enhancement of spin Hall efficiency by mechanical strain, but its origin remains elusive. Here, we demonstrate a 45% increase in spin Hall efficiency in the platinum/cobalt (Pt/Co) bilayer, of which 78% of the enhancement was preserved even after the strain was removed. Spin transparency and X-ray magnetic circular dichroism revealed that the enhancement was attributed to a bulk effect in the Pt layer. This was further confirmed by the linear relationship between the spin Hall efficiency and resistivity, which indicates an increase in skew-scattering. These findings shed light on the origin of enhancement and are promising in shaping future utilization of mechanical strain for energy-efficient devices.

Published

2021

17. Mechanical Properties of Atomically Thin Tungsten Dichalcogenides: WS 2 , WSe 2 , and WTe 2 .

Author

Falin A, Holwill M, Lv H, Gan W, Cheng J, Zhang R, Qian D, Barnett MR, Santos EJG, Novoselov KS, Tao T, Wu X, and Li LH

Abstract

Two-dimensional (2D) tungsten disulfide (WS 2 ), tungsten diselenide (WSe 2 ), and tungsten ditelluride (WTe 2 ) draw increasing attention due to their attractive properties deriving from the heavy tungsten and chalcogenide atoms, but their mechanical properties are still mostly unknown. Here, we determine the intrinsic and air-aged mechanical properties of mono-, bi-, and trilayer (1-3L) WS 2 , WSe 2 , and WTe 2 using a complementary suite of experiments and theoretical calculations. High-quality 1L WS 2 has the highest Young's modulus (302.4 ± 24.1 GPa) and strength (47.0 ± 8.6 GPa) of the entire family, overpassing those of 1L WSe 2 (258.6 ± 38.3 and 38.0 ± 6.0 GPa, respectively) and WTe 2 (149.1 ± 9.4 and 6.4 ± 3.3 GPa, respectively). However, the elasticity and strength of WS 2 decrease most dramatically with increased thickness among the three materials. We interpret the phenomenon by the different tendencies for interlayer sliding in an equilibrium state and under in-plane strain and out-of-plane compression conditions in the indentation process, revealed by the finite element method and density functional theory calculations including van der Waals interactions. We also demonstrate that the mechanical properties of the high-quality 1-3L WS 2 and WSe 2 are largely stable in air for up to 20 weeks. Intriguingly, the 1-3L WSe 2 shows increased modulus and strength values with aging in the air. This is ascribed to oxygen doping, which reinforces the structure. The present study will facilitate the design and use of 2D tungsten dichalcogenides in applications such as strain engineering and flexible field-effect transistors.

Published

2021

18. Magnetically Driven 3D Cellulose Film for Improved Energy Efficiency in Solar Evaporation.

Author

Gan W, Wang Y, Xiao S, Gao R, Shang Y, Xie Y, Liu J, and Li J

Abstract

The architecture of cellulose nanomaterials is definitized by random deposition and cannot change in response to shifting application requirements. Herein, we present a magnetic field-controlled cellulose film derived from wood that exhibits great magnetic properties and reliable tunability enabled by incorporated Fe 3 O 4 nanoparticles and cellulose nanofibers (CNF) with a large length-diameter ratio. Fe 3 O 4 nanoparticles are dispersed in suspensions of CNF so as to enhance the magnetic response. The plane magnetic CNF can be processed to form a three-dimensional (3D) flower-like structure along the magnetic induction line after applying an external magnet. Inspired by the fluidic transport in natural flowers, a bilayer structure was created using the 3D flower-like film as the solar energy receiver and natural wood as the water pathway in a solar-derived evaporation system. Compared with a planar cellulose film decorated with Fe 3 O 4 , the 3D structure design can greatly improve the evaporation rate from 1.19 to 1.39 kg m -2 h -1 and the efficiency from 76.9 to 90.6% under 1 sun. Finite element molding further reveals that the 3D structural top layer is beneficial for the formation of a gradient temperature profile and the improvement of the energy efficiency through the reduction of thermal radiation. The magnetically controlled fabrication represents a promising strategy for designing cellulose nanomaterials with a complicated structure and controllable topography, which has a wide spectrum of applications in energy storage devices and water treatment.

Published

2021

19. Bioinspired Cavity Regulation on Superhydrophobic Spheres for Drag Reduction in an Aqueous Medium.

Author

Yao C, Zhang J, Xue Z, Yu K, Yu X, Yang X, Qu Q, Gan W, Wang J, and Jiang L

Abstract

Hydrodynamic drag not only results in high-energy consumption for water vehicles but also impedes the increase of vehicle speed. The introduction of a low-viscosity gas lubricating film is assumed to be an effective and promising method to reduce hydrodynamic drag. However, the poor stability of the gas film and massive extra energy consumption restricts the practical application of the gas lubricating method. Herein, inspired by the microhairs with low surface energy wax covering the abdomen of water spiders, superhydrophobic sphere surfaces were designed. Attributed to numerous neighboring nanoneedle branches with low surface energy chemicals, an air-entrained cavity with a large surface area was captured and stabilized by the superhydrophobic sphere, changing its shape from a sphere to a streamlined body. The cavity continued attaching to the superhydrophobic sphere without bursting at a depth of 70.0-90.0 cm underwater and reduced the hydrodynamic drag by more than 90%. This work provides a simple, cost-effective, and energy-efficient way to stabilize the underwater gas-liquid interface to achieve a reduction in the hydrodynamic drag.

Published

2021

20. High-Performance Flexible Transparent Conductive Films Enabled by a Commonly Used Antireflection Layer.

Author

Zhang L, Liu Y, Li L, Zhong L, Wang K, Gan W, and Qiu Y

Abstract

Recently, silver nanowire-based transparent conductive films (AgNW-based TCFs) with excellent comprehensive performance have aroused wide and great interest. However, it is always difficult to simultaneously improve the performances of TCFs in all aspects. In this work, by introducing silica nanoparticles (SiO 2 -NPs) with a smaller particle size, several properties of AgNW-based TCFs were optimized successfully. The transmittance and conductivity were improved simultaneously, and smaller particle size was proven to be more suitable to achieve TCFs with excellent optoelectrical properties. Typically, an AgNW/SiO 2 -based TCF with a sheet resistance of 250 Ω/sq and transmittance of 93.6% (including the poly (ethylene terephthalate) substrate, abbreviated as PET) could be obtained by using SiO 2 -NPs with a size of ∼21 nm, and this transmittance is even higher than that of the bare PET (91.8%) substrate. We demonstrated that the layer formed through self-assembly of SiO 2 -NPs can cut down the light scattering on the AgNW surface through total reflection, thus leading to a low haze of AgNW/SiO 2 -based TCFs. Very interestingly, the SiO 2 -NPs conducted away most of the heat generated during laser ablation, protecting the AgNWs from excessive melt and PET from empyrosis, and thus ensuring the TCFs with high transmittance and patterning accuracy. Besides, AgNW/SiO 2 -based TCFs have smaller surface roughness, better flexibility, and adhesive force. To the best of our knowledge, the comprehensive performance of the AgNW/SiO 2 -based TCFs reaches the highest level among recently reported novel TCFs.

Published

2021

21. Highly Elastic Hydrated Cellulosic Materials with Durable Compressibility and Tunable Conductivity.

Author

Chen C, Song J, Cheng J, Pang Z, Gan W, Chen G, Kuang Y, Huang H, Ray U, Li T, and Hu L

Abstract

Anisotropic cellular materials with direction-dependent structure and durable mechanical properties enable various applications ( e . g ., nanofluidics, biomedical devices, tissue engineering, and water purification), but their widespread use is often hindered by complex and scale-limited fabrication and unsatisfactory mechanical performance. Here, inspired by the anisotropic and hierarchical material structure of tendons, we demonstrate a facile, scalable top-down approach for fabricating a highly elastic, ionically conductive, anisotropic cellulosic material (named elastic wood) directly from natural wood via chemical treatment. The resulting elastic wood demonstrates good elasticity and durable compressibility, showing no sign of fatigue after 10 000 compression cycles. The chemical treatment not only softens the wood cell walls by partially removing lignin and hemicellulose but introduces an interconnected cellulose fibril network into the wood channels. Atomistic and continuum modeling further reveals that the absorbed water can freely and reversibly move inside the elastic wood and therefore helps the elastic wood accommodate large compressive deformation and recover to its original shape upon compression release. In addition, the elastic wood showed a high ionic conductivity of up to 0.5 mS cm -1 at a low KCl concentration of 10 -4 M, which can be tuned by changing the compression ratio of the material. The demonstrated elastic, mechanically robust, and ionically conductive cellulosic material combining inherited anisotropic cellular structure from natural wood and a self-formed internal gel may find a variety of potential applications in ionic nanofluidics, sensors, soft robots, artificial muscle, environmental remediation, and energy storage.

Published

2020

22. MOF-Derived 2D/3D Hierarchical N-Doped Graphene as Support for Advanced Pt Utilization in Ethanol Fuel Cell.

Author

Gao J, Zhang F, Gan W, Gui Y, Qiu H, Li H, and Yuan Q

Abstract

Development of bifunctional catalysts with low platinum (Pt) content for the ethanol oxidation reaction (EOR) and the oxygen reduction reaction (ORR) is highly desirable, yet challenging. Herein, we present structural engineering of a series of two-dimensional/three-dimensional (2D/3D) hierarchical N-doped graphene-supported nanosized Pt 3 Co alloys and Co clusters (PtCo@N-GNSs) via a hydrolysis-pyrolysis route. For the ORR, the optimal PtCo@N-GNS exhibits a high mass activity of 3.01 A mg Pt -1 , which is comparable to the best Pt-based catalyst obtained through sophisticated synthesis. It also possesses excellent stability with minor decay after 50 000 cyclic voltammograms (CV) cycles in acidic medium. For the EOR, PtCo@N-GNS achieves the highest mass-specific and area-specific activities of 1.96 A mg Pt -1 and 5.75 mA cm -2 , respectively, among all of the reported EOR catalysts to date. The unique 2D/3D hierarchy, high Pt utilization, and valid encapsulation of nanosized Pt 3 Co/Co synergistically contribute to the robust ORR and EOR activities of the present PtCo@N-GNS. A direct ethanol fuel cell based on PtCo@N-GNS delivers a high open-circuit potential of 0.9 V, a stable power density of 10.5 mW cm -2 , and an excellent rate performance, implying the feasibility of the bifunctional PtCo@N-GNS. This work offers a new strategy for designing an ultralow Pt loading yet highly active and durable catalyst for ethanol fuel cell application.

Published

2020

23. Giant Spin Hall Effect in Cu-Tb Alloy Thin Films.

Author

Xu Z, Hwee Wong GD, Tang J, Liu E, Gan W, Xu F, and Lew WS

Abstract

We report the giant spin current generation in CuTb alloys arising from the spin Hall effect. The maximum spin Hall angle from our CuTb-based magnetic heterostructures was found to be -0.35 ± 0.02 for Cu 0.39 Tb 0.61 . We find that the contribution of skew scattering is larger than the side jump for lower Tb concentrations (<14.9%), while the converse is true for higher Tb concentrations. Additionally, we also studied the Gilbert damping parameter, spin diffusion length, and spin-mixing conductance. Interfacial spin transparency was found to be 0.55 ± 0.03 for the CoFeB/Cu 0.53 Tb 0.47 interface. The spin diffusion length and spin-mixing conductance of the Cu 0.53 Tb 0.47 alloy are λ sd = 2.5 ± 0.3 nm and G ↓↑ = (24.2 ± 1.0) × 10 15 cm -2 , respectively. Our results pave a way for rare-earth metals to be used as a spin Hall material in highly efficient SOT devices.

Published

2020

24. Discovery of Triazolo-pyridazine/-pyrimidine Derivatives Bearing Aromatic (Heterocycle)-Coupled Azole Units as Class II c-Met Inhibitors.

Author

Zhang Q, Liu X, Gan W, Wu J, Zhou H, Yang Z, Zhang Y, Liao M, Yuan P, Xu S, Zheng P, and Zhu W

Abstract

Two series of novel triazolo-pyridazine/-pyrimidine derivatives were designed, synthesized, and evaluated for their inhibitory activity against c-Met kinase, as well as three c-Met overexpressed cancer cell lines (A549, MCF-7, and HeLa) and one normal human hepatocytes cell line LO2 in vitro . The pharmacological data indicated that most of the tested compounds showed moderate cytotoxicity, and the most promising compound 12e exhibited significant cytotoxicity against A549, MCF-7, and HeLa cell lines with IC 50 values of 1.06 ± 0.16, 1.23 ± 0.18, and 2.73 ± 0.33 μM, respectively. Moreover, the inhibitory activity of compound 12e against c-Met kinase (IC 50 = 0.090 μM) was equal to that of Foretinib (IC 50 = 0.019 μM). The result of the acridine orange (AO) single staining test demonstrated that compound 12e could remarkably induce apoptosis of A549 cells. The results of apoptosis and cycle distribution of cells showed that compound 12e could induce late apoptosis of A549 cells and stimulate A549 cells arresting in the G0/G1 phase. Structure-activity relationships (SARs), pharmacological results, and docking studies indicated that the introduction of 5-methylthiazole fragment to the five-atom moiety was beneficial for the activity. So far, the existing data indicated that compound 12e may become a potential class II c-Met inhibitor., Competing Interests: The authors declare no competing financial interest., (Copyright © 2020 American Chemical Society.)

Published

2020

25. Two-Dimensional Van der Waals Heterostructures for Synergistically Improved Surface-Enhanced Raman Spectroscopy.

Author

Cai Q, Gan W, Falin A, Watanabe K, Taniguchi T, Zhuang J, Hao W, Huang S, Tao T, Chen Y, and Li LH

Abstract

Surface-enhanced Raman spectroscopy (SERS) is a precise and noninvasive analytical technique that is widely used in chemical analysis, environmental protection, food processing, pharmaceutics, and diagnostic biology. However, it is still a challenge to produce highly sensitive and reusable SERS substrates with a minimum fluorescence background. In this work, we propose the use of van der Waals heterostructures of two-dimensional materials to cover plasmonic metal nanoparticles to solve this challenge. The heterostructures of atomically thin boron nitride (BN) and graphene provide synergistic effects: (1) electrons could tunnel through the atomically thin BN, allowing the charge transfer between graphene and probe molecules to suppress the fluorescence background; (2) the SERS sensitivity is enhanced by graphene via a chemical enhancement mechanism in addition to an electromagnetic field mechanism; and (3) the atomically thin BN protects the underlying graphene and Ag nanoparticles from oxidation during heating for regeneration at 360 °C in the air so that the SERS substrates could be reused. These advances will facilitate wider applications of SERS especially on the detection of fluorescent molecules with higher sensitivity.

Published

2020

26. Atomically Thin Boron Nitride as an Ideal Spacer for Metal-Enhanced Fluorescence.

Author

Gan W, Tserkezis C, Cai Q, Falin A, Mateti S, Nguyen M, Aharonovich I, Watanabe K, Taniguchi T, Huang F, Song L, Kong L, Chen Y, and Li LH

Abstract

Metal-enhanced fluorescence (MEF) considerably enhances the luminescence for various applications, but its performance largely depends on the dielectric spacer between the fluorophore and plasmonic system. It is still challenging to produce a defect-free spacer having an optimized thickness with a sub-nanometer accuracy that enables reusability without affecting the enhancement. In this study, we demonstrate the use of atomically thin hexagonal boron nitride (BN) as an ideal MEF spacer owing to its multifold advantages over the traditional dielectric thin films. With rhodamine 6G as a representative fluorophore, it largely improves the enhancement factor (up to ∼95 ± 5), sensitivity (10 -8 M), reproducibility, and reusability (∼90% of the plasmonic activity is retained after 30 cycles of heating at 350 °C in air) of MEF. This can be attributed to its two-dimensional structure, thickness control at the atomic level, defect-free quality, high affinities to aromatic fluorophores, good thermal stability, and excellent impermeability. The atomically thin BN spacers could increase the use of MEF in different fields and industries.

Published

2019

27. Understanding the Dynamic Behavior of an Anticancer Drug, Doxorubicin, on a Lipid Membrane Using Multiple Spectroscopic Techniques.

Author

Hou Y, Chen SL, Gan W, Ma X, and Yuan Q

Subjects

Adsorption, Particle Size, Surface Properties, Antineoplastic Agents chemistry, Doxorubicin chemistry, Membrane Lipids chemistry, Microscopy, Fluorescence, Multiphoton, Molecular Dynamics Simulation

Abstract

The interaction, including the adsorption and embedding, of a widely applied anticancer drug, doxorubicin, with a lipid membrane was investigated. Second harmonic generation and two photon fluorescence were used as a powerful combination capable in revealing this dynamic process at the interface. The adsorption, association, deassociation and embedding of doxorubicin on the lipid membrane were clearly identified based on the consistency in the dynamic parameters revealed by the time dependent second harmonic generation and two-photon fluorescence measurements. This work also presents a new approach for in situ measurement of the adsorption density of doxorubicin on lipid membrane, benefiting from the two-photon fluorescence signal of doxorubicin being significantly altered by its chemical environment. The analysis of the location and molecular density based on the fluorescent efficiency of the chromophores makes the fluorescence measurement a "surface sensitive" technique as well. The analytical procedures used in this work are expected to aid in understanding the interaction between fluorescent molecules and lipid membranes in general.

Published

2019

28. Super Bright Luminescent Metallic Nanoparticles.

Author

Gan W, Xu B, and Dai HL

Abstract

It is found that, by curing the surface defects that quench photoexcited carriers, luminescence efficiency of metallic nanoparticles can be dramatically increased. For Ag nanoparticles, as much as 300 times increase in photoexcitation induced luminescence is observed upon surface adsorption of ethanethiol. The same treatment increases Au nanoparticle luminescence efficiency by a factor of 3. A model based on the elimination of surface defects by the sulfur-metal bond formed upon thiol adsorption can quantitatively account for the observations, which also indicate that nanoparticles without proper surface treatment typically have low luminescence quantum yields.

Published

2018

29. Energy-Efficient Elastocaloric Cooling by Flexibly and Reversibly Transferring Interface in Magnetic Shape-Memory Alloys.

Author

Li Y, Zhao D, Liu J, Qian S, Li Z, Gan W, and Chen X

Abstract

Elastocaloric cooling is currently under extensive study owing to its great potential to replace the conventional vapor-compression technique. In this work, by employing multiscale characterization approaches, including in situ neutron diffraction in a loading frame, in situ transmission electron microscopy observation at different temperatures, in situ synchrotron X-ray Laue microdiffraction, and high-resolution infrared thermal imaging, we have investigated the thermal and stress-induced martensitic transformation, the stability of superelastic behavior and the associated elastocaloric effect for a Heusler-type Ni 50.0 Fe 19.0 Ga 27.1 Co 3.9 single crystal. On the basis of transformation from cubic austenite into monoclinic martensite with a flexibly and reversibly transferring interface, this unique single crystal exhibits a giant elastocaloric effect of 11 K and ultralow fatigue behavior during above 12 000 mechanical cycles. The numerical simulation shows that the Ni 50.0 Fe 19.0 Ga 27.1 Co 3.9 alloy offers 18% energy saving potential and 70% cooling capacity enhancement potential compared to the conventional shape-memory nitinol alloy in a single-stage elastocaloric cooling system, making it a great candidate for energy-efficient air conditioner applications.

Published

2018

30. Improved Multiprotein Microcontact Printing on Plasma Immersion Ion Implanted Polystyrene.

Author

Kosobrodova E, Gan WJ, Kondyurin A, Thorn P, and Bilek MMM

Subjects

Animals, Cell Survival, Ions, Mice, Surface Properties, Polystyrenes chemistry

Abstract

Multiprotein micropatterning allows the creation of complex, controlled microenvironments for single cells that can be used for the study of the localized effects of various proteins and signals on cell survival, development, and functions. To enable analysis of cell interactions with microprinted proteins, the multiprotein micropattern must have low cross-contamination and high long-term stability in a cell culture medium. To achieve this, we employed an optimized plasma ion immersion implantation (PIII) treatment to provide polystyrene (PS) with the ability to covalently immobilize proteins on contact while retaining sufficient transparency and suitable surface properties for contact printing and retention of protein activity. The quality and long-term stability of the micropatterns on untreated and PIII treated PS were compared with those on glass using confocal microscopy. The protein micropattern on the PIII treated PS was more uniform and had a significantly higher contrast that was not affected by long-term incubation in cell culture media because the proteins were covalently bonded to PIII treated PS. The immunostaining of mouse pancreatic β cells interacting with E-cadherin and fibronectin striped surfaces showed phosphorylated paxillin concentrated on cell edges over the fibronectin stripes. This indicates that multiprotein micropatterns printed on PIII treated PS can be used for high-resolution studies of local influence on cell morphology and protein production.

Published

2018

31. Facile Design and Fabrication of Superwetting Surfaces with Excellent Wear-Resistance.

Author

Zhang W, Xiang T, Liu F, Zhang M, Gan W, Zhai X, Di X, Wang Y, Liu G, and Wang C

Abstract

Preparation of mechanically durable superwetting surfaces is imperative, yet challenging for the wide range of real applications where high durability is required. Mechanical wear on superwetting surfaces usually degrades weak roughness, leading to loss of functions. In this study, wear-resistant superhydrophilic/underwater superoleophobic and superhydrophobic surfaces are prepared by anchoring reinforced coatings via adhesive-swelling and adhesive-bonding processes, respectively. The results of the sandpaper abrasion (grit no. 600, 24 kPa) show that superhydrophilic nylon/SiO 2 coatings and superhydrophobic polyurethane/TiO 2 coatings retain their functions after suffering the abrasion distances of 70 cm and more than 1000 cm, respectively. Reinforced coatings formed by consecutive roughness and improved adhesion between coatings and substrates are responsible for repeatedly generated superwettability after exposure to mechanical stresses and demonstrated to be feasible for designing wear-resistant superwetting surfaces. Furthermore, this novel architecture of "reinforced coating with consecutive roughness + high adhesion" may demand desired coating materials and reliable coating-fixing techniques for sustaining sufficient roughness and is superior to currently existing technologies in advancing wear-resistance of superwetting surfaces.

Published

2017

32. Chitosan-Modified Filter Paper for Nucleic Acid Extraction and "in Situ PCR" on a Thermoplastic Microchip.

Author

Gan W, Gu Y, Han J, Li CX, Sun J, and Liu P

Subjects

DNA blood, Filtration, Healthy Volunteers, Humans, Polymerase Chain Reaction, Chitosan chemistry, DNA genetics, DNA isolation & purification, Microfluidic Analytical Techniques, Paper, Temperature

Abstract

Plastic microfluidic devices with embedded chitosan-modified Fusion 5 filter paper (unmodified one purchased from GE Healthcare) have been successfully developed for DNA extraction and concentration, utilizing two different mechanisms for DNA capture: the physical entanglement of long-chain DNA molecules with the fiber matrix of the filter paper and the electrostatic adsorption of DNA to the chitosan-modified filter fibers. This new method not only provided a high DNA extraction efficiency at a pH of 5 by synergistically combining these two capture mechanisms together, but also resisted the elution of DNA from filters at a pH > 8 due to the entanglement of DNA with fibers. As a result, PCR buffers can be directly loaded into the extraction chamber for "in situ PCR", in which the captured DNA were used for downstream analysis without any loss. We demonstrated that the capture efficiencies of a 3-mm-diameter filter disc in a microchip were 98% and 95% for K562 human genomic DNA and bacteriophage λ-DNA, respectively. The washes with DI water, PCR mixture, and TE buffer cannot elute the captured DNA. In addition, the filter disc can enrich 62% of λ-DNA from a diluted sample (0.05 ng/μL), providing a concentration factor more than 30-fold. Finally, a microdevice with a simple two-chamber structure was developed for on-chip cell lysis, DNA extraction, and 15-plex short tandem repeat amplification from blood. This DNA extraction coupled with "in situ PCR" has great potential to be utilized in fully integrated microsystems for rapid, near-patient nucleic acid testing.

Published

2017

33. Label-Free Method Using a Weighted-Phase Algorithm To Quantitate Nanoscale Interactions between Molecules on DNA Microarrays.

Author

Li Q, Fu R, Zhang J, Wang R, Ye J, Xue N, Lin X, Su Y, Gan W, Lu Y, and Huang G

Subjects

DNA chemical synthesis, Fluorescence Resonance Energy Transfer, Interferometry, Light, Nucleic Acid Hybridization, Algorithms, DNA chemistry, Nanoparticles chemistry, Oligonucleotide Array Sequence Analysis

Abstract

White light interference is used as a label-free method to detect nanoscale changes on surfaces. However, the signal-to-noise ratio of the white light interference method is very low, thus resulting in inaccurate results. In this paper, we report a corrected label-free method based on hyperspectral interferometry to overcome the shortcoming of the white light interference method. A platform based on hyperspectral interferometry was established, and a DNA hybridization microarray was constructed to quantitate thickness variation of molecules on a solid surface. We used fluorescence resonance energy transfer (FRET) to validate the results of our method. Compared to conventional fluorescence-labeled method like FRET, our method has advantages because it does not require a fluorescent label and has a detection limit of 1.78 nm, a high accuracy, and wide detection range (5-64 bp).

Published

2017

34. A Ternary Alloy Substrate to Synthesize Monolayer Graphene with Liquid Carbon Precursor.

Author

Gan W, Han N, Yang C, Wu P, Liu Q, Zhu W, Chen S, Wu C, Habib M, Sang Y, Muhammad Z, Zhao J, and Song L

Abstract

Here we demonstrate a ternary Cu 2 NiZn alloy substrate for controllably synthesizing monolayer graphene using a liquid carbon precursor cyclohexane via a facile CVD route. In contrast with elemental metal or bimetal substrates, the alloy-induced synergistic effects that provide an ideal metallic platform for much easier dehydrogenation of hydrocarbon molecules, more reasonable strength of adsorption energy of carbon monomer on surface and lower formation energies of carbon chains, largely renders the success growth of monolayer graphene with higher electrical mobility and lower defects. The growth mechanism is systemically investigated by our DFT calculations. This study provides a selective route for realizing high-quality graphene monolayer via a scalable synthetic method by using economic liquid carbon supplies and multialloy metal substrates.

Published

2017

35. Intermolecular Aminocarbonylation of Alkenes using Concerted Cycloadditions of Iminoisocyanates.

Author

Bongers A, Clavette C, Gan W, Gorelsky SI, Betit L, Lavergne K, Markiewicz T, Moon PJ, Das Neves N, Obhi NK, Toderian AB, and Beauchemin AM

Abstract

The aminocarbonylation of alkenes is a powerful method for accessing the β-amino carbonyl motif that remains underdeveloped. Herein, the development of intermolecular aminocarbonylation reactivity of iminoisocyanates with alkenes is presented. This includes the discovery of a fluorenone-derived reagent, which was effective for many alkene classes and facilitated derivatization. Electron-rich substrates were most reactive, and this indicated that the LUMO of the iminoisocyanate is reacting with the HOMO of the alkene. Computational and experimental results support a concerted asynchronous [3 + 2] cycloaddition involving an iminoisocyanate, which was observed for the first time by FTIR under the reaction conditions. The products of this reaction are complex azomethine imines, which are precursors to valuable β-amino carbonyl compounds such as β-amino amides and esters, pyrazolones, and bicyclic pyrazolidinones. A kinetic resolution of the azomethine imines by enantioselective reduction (s = 13-43) allows access to enantioenriched products. Overall, this work provides a new tool to convert alkenes into β-amino carbonyl compounds.

Published

2017

36. N-Doped Ordered Mesoporous Carbon Originated from a Green Biological Dye for Electrochemical Sensing and High-Pressure CO2 Storage.

Author

Zhou S, Xu H, Yuan Q, Shen H, Zhu X, Liu Y, and Gan W

Subjects

Adsorption, Catechols analysis, Hydroquinones analysis, Isomerism, Nitrogen chemistry, Oxidation-Reduction, Photoelectron Spectroscopy, Porosity, Silicon Dioxide chemical synthesis, Temperature, Water chemistry, X-Ray Diffraction, Carbon chemistry, Carbon Dioxide chemistry, Coloring Agents chemistry, Electrochemistry methods, Pressure

Abstract

Herein, a series of nitrogen-doped ordered mesoporous carbons (NOMCs) with tunable porous structure were synthesized via a hard-template method with a green biological dye as precursor, under various carbonization temperatures (700-1100 °C). Compared with the ordered mesoporous silica-modified and unmodified electrodes, the use of electrodes coated by NOMCs (NOMC-700-NOMC-1100) resulted in enhanced signals and well-resolved oxidation peaks in electrocatalytic sensing of catechol and hydroquinone isomers, attributable to NOMCs' open porous structures and increased edge-plane defect sites on the N-doped carbon skeleton. Electrochemical sensors using NOMC-1000-modified electrode were fabricated and proved feasible in tap water sample analyses. The NOMCs were also used as sorbents for high-pressure CO2 storage. The NOMC with the highest N content exhibits the best CO2 absorption capacities of 800.8 and 387.6 mg/g at 273 and 298 K (30 bar), respectively, which is better than those of other NOMC materials and some recently reported CO2 sorbents with well-ordered 3D porous structures. Moreover, this NOMC shows higher affinity for CO2 than for N2, a benefit of its higher nitrogen content in the porous carbon framework.

Published

2016

37. Role of Chlorine Dioxide in N-Nitrosodimethylamine Formation from Oxidation of Model Amines.

Author

Gan W, Bond T, Yang X, and Westerhoff P

Subjects

Amines chemistry, Chloramines chemistry, Dimethylamines analysis, Dimethylamines chemistry, Dimethylhydrazines analysis, Dimethylhydrazines chemistry, Disinfection methods, Drinking Water chemistry, Gas Chromatography-Mass Spectrometry, Oxidation-Reduction, Chlorine Compounds chemistry, Dimethylnitrosamine chemistry, Oxides chemistry, Water Purification methods

Abstract

N-Nitrosodimethylamine (NDMA) is an emerging disinfection byproduct, and we show that use of chlorine dioxide (ClO2) has the potential to increase NDMA formation in waters containing precursors with hydrazine moieties. NDMA formation was measured after oxidation of 13 amines by monochloramine and ClO2 and pretreatment with ClO2 followed by postmonochloramination. Daminozide, a plant growth regulator, was found to yield 5.01 ± 0.96% NDMA upon reaction with ClO2, although no NDMA was recorded during chloramination. The reaction rate was estimated to be ∼0.0085 s(-1), and on the basis of our identification by mass spectrometry of the intermediates, the reaction likely proceeds via the hydrolytic release of unsymmetrical dimethylhydrazine (UDMH), with the hydrazine structure a key intermediate in NDMA formation. The presence of UDMH was confirmed by gas chromatography-mass spectrometry analysis. For 10 of the 13 compounds, ClO2 preoxidation reduced NDMA yields compared with monochloramination alone, which is explained by our measured release of dimethylamine. This work shows potential preoxidation strategies to control NDMA formation may not impact all organic precursors uniformly, so differences might be source specific depending upon the occurrence of different precursors in source waters. For example, daminozide is a plant regulator, so drinking water that is heavily influenced by upstream agricultural runoff could be at risk.

Published

2015

38. Fully automated sample preparation microsystem for genetic testing of hereditary hearing loss using two-color multiplex allele-specific PCR.

Author

Zhuang B, Gan W, Wang S, Han J, Xiang G, Li CX, Sun J, and Liu P

Subjects

Alleles, Connexin 26, Connexins, Equipment Design, Genetic Testing instrumentation, Humans, DNA blood, DNA genetics, DNA Mutational Analysis instrumentation, Hearing Loss blood, Hearing Loss genetics, Lab-On-A-Chip Devices, Multiplex Polymerase Chain Reaction instrumentation

Abstract

A fully automated microsystem consisting of a disposable DNA extraction and PCR microchip, as well as a compact control instrument, has been successfully developed for genetic testing of hereditary hearing loss from human whole blood. DNA extraction and PCR were integrated into a single 15-μL reaction chamber, where a piece of filter paper was embedded for capturing genomic DNA, followed by in-situ PCR amplification without elution. Diaphragm microvalves actuated by external solenoids together with a "one-way" fluidic control strategy operated by a modular valve positioner and a syringe pump were employed to control the fluids and to seal the chamber during thermal cycling. Fully automated DNA extractions from as low as 0.3-μL human whole blood followed by amplifications of 59-bp β-actin fragments can be completed on the microsystem in about 100 min. Negative control tests that were performed between blood sample analyses proved the successful elimination of any contamination or carryover in the system. To more critically test the microsystem, a two-color multiplex allele-specific PCR (ASPCR) assay for detecting c.176&#95;191del16, c.235delC, and c.299&#95;300delAT mutations in GJB2 gene that accounts for hereditary hearing loss was constructed. Two allele-specific primers, one labeled with TAMRA for wild type and the other with FAM for mutation, were designed for each locus. DNA extraction from blood and ASPCR were performed on the microsystem, followed by an electrophoretic analysis on a portable microchip capillary electrophoresis system. Blood samples from a healthy donor and five persons with genetic mutations were all accurately analyzed with only two steps in less than 2 h.

Published

2015

39. A practical approach to semicarbazone and hydrazone derivatives via imino-isocyanates.

Author

Garland K, Gan W, Depatie-Sicard C, and Beauchemin AM

Subjects

Hydrazones chemistry, Molecular Structure, Semicarbazones chemistry, Hydrazones chemical synthesis, Imines chemistry, Isocyanates chemistry, Semicarbazones chemical synthesis

Abstract

Complex hydrazone derivatives can be accessed readily from hydrazones upon heating in the presence of nucleophiles. This reactivity likely involves imino-isocyanate intermediates, and a variety of leaving groups can be used at temperatures ranging from 20 to 150 °C. Alcohols, thiols, primary, and secondary amines can be used as nucleophiles, thus providing a simple alternative to the synthesis of hydrazones via condensation on the parent carbonyl precursor and allowing late-stage derivatization.

Published

2013

40. Synthesis and reactivity of unsymmetrical azomethine imines formed using alkene aminocarbonylation.

Author

Gan W, Moon PJ, Clavette C, Das Neves N, Markiewicz T, Toderian AB, and Beauchemin AM

Subjects

Azo Compounds chemistry, Catalysis, Combinatorial Chemistry Techniques, Cyclization, Imines chemistry, Ketones chemical synthesis, Ketones chemistry, Molecular Structure, Stereoisomerism, Thiosemicarbazones chemistry, Alkenes chemistry, Azo Compounds chemical synthesis, Hydrazones chemistry, Imines chemical synthesis, Thiosemicarbazones chemical synthesis

Abstract

Complex cyclic azomethine imines possessing a β-aminocarbonyl motif can be accessed readily from simple alkenes and hydrazones. This alkene aminocarbonylation approach allows formation of ketone-derived azomethine imines of unprecedented complexity. Since unsymmetrical hydrazones are used, two stereoisomers are formed: the reactivity of chiral derivatives is explored in both intra- and intermolecular systems.

Published

2013

41. A tunable route for the synthesis of azomethine imines and β-aminocarbonyl compounds from alkenes.

Author

Clavette C, Gan W, Bongers A, Markiewicz T, Toderian AB, Gorelsky SI, and Beauchemin AM

Subjects

Chemistry Techniques, Synthetic, Hydrazones chemistry, Ketones chemistry, Alkenes chemistry, Azo Compounds chemistry, Imines chemical synthesis, Imines chemistry, Thiosemicarbazones chemistry

Abstract

Cyclic azomethine imines possessing a β-aminocarbonyl motif are accessed from simple alkene and hydrazone starting materials. A thermal, concerted alkene aminocarbonylation pathway involving an imino-isocyanate intermediate is proposed and supported by DFT calculations. A notable feature of the process is the steric shielding present in the dipoles formed, which allows for facile purification of the products by chromatography or crystallization. In addition, a fluorenone-derived reagent is reported, which provides reactivity with several alkene classes and allows for mild derivatization of the dipoles into β-aminoamides, β-aminoesters, and β-amino acids.

Published

2012

42. Possible steric control of the relative strength of chelation enhanced fluorescence for zinc(II) compared to cadmium(II): metal ion complexing properties of tris(2-quinolylmethyl)amine, a crystallographic, UV-visible, and fluorometric study.

Author

Williams NJ, Gan W, Reibenspies JH, and Hancock RD

Subjects

Amines chemistry, Crystallography, X-Ray, Fluorometry, Ligands, Spectrophotometry, Ultraviolet, Cadmium chemistry, Chelating Agents chemistry, Fluorescence, Zinc chemistry

Abstract

The idea is examined that steric crowding in ligands can lead to diminution of the chelation enhanced fluorescence (CHEF) effect in complexes of the small Zn(II) ion as compared to the larger Cd(II) ion. Steric crowding is less severe for the larger ion and for the smaller Zn(II) ion leads to Zn-N bond length distortion, which allows some quenching of fluorescence by the photoinduced electron transfer (PET) mechanism. Some metal ion complexing properties of the ligand tris(2-quinolylmethyl)amine (TQA) are presented in support of the idea that more sterically efficient ligands, which lead to less M-N bond length distortion with the small Zn(II) ion, will lead to a greater CHEF effect with Zn(II) than Cd(II). The structures of [Zn(TQA)H(2)O](ClO(4))(2).1.5 H(2)O (1), ([Pb(TQA)(NO(3))(2)].C(2)H(5)OH) (2), ([Ag(TQA)(ClO(4))]) (3), and (TQA).C(2)H(5)OH (4) are reported. In 1, the Zn(II) is 5-coordinate, with four N-donors from the ligand and a water molecule making up the coordination sphere. The Zn-N bonds are all of normal length, showing that the level of steric crowding in 1 is not sufficient to cause significant Zn-N bond length distortion. This leads to the observation that, as expected, the CHEF effect in the Zn(II)/TQA complex is much stronger than that in the Cd(II)/TQA complex, in contrast to similar but more sterically crowded ligands, where the CHEF effect is stronger in the Cd(II) complex. The CHEF effect for TQA with the metal ions examined varies as Zn(II) >> Cd(II) >> Ni(II) > Pb(II) > Hg(II) > Cu(II). The structure of 2 shows an 8-coordinate Pb(II), with evidence of a stereochemically active lone pair, and normal Pb-N bond lengths. In 3, the Ag(I) is 5-coordinate, with four N-donors from the TQA and an oxygen from the perchlorate. The Ag(I) shows no distortion toward linear 2-coordinate geometry, and the Ag-N bonds fall slightly into the upper range for Ag-N bonds in 5-coordinate complexes. The structure of 4 shows the TQA ligand to be involved in pi-stacking between quinolyl groups from adjacent TQA molecules. Formation constants determined by UV-visible spectroscopy are reported in 0.1 M NaClO(4) at 25 degrees C for TQA with Zn(II), Cd(II), and Pb(II). When compared with other similar ligands, one sees that, as the level of steric crowding increases, the stability decreases most with the small Zn(II) ion and least with the large Pb(II) ion. This is in accordance with the idea that TQA has a moderate level of steric crowding and that steric crowding increases for TQA analogs tris(2-pyridylmethyl)amine (TPyA) < TQA < tris(6-methyl-2-pyridyl)amine (TMPyA).

Published

2009

43. Versatile cyclic templates for assembly of axially oriented ligands.

Author

Chopra N, Gan W, Schreiber H, Kurutz JW, and Meredith SC

Subjects

Amino Acid Sequence, Circular Dichroism, Ligands, Magnetic Resonance Spectroscopy, Microscopy, Electron, Models, Molecular, Molecular Sequence Data, Peptides, Cyclic chemistry, Peptides, Cyclic metabolism, Protein Conformation, Proteins metabolism, Drug Design, Peptides, Cyclic chemical synthesis

Abstract

In this paper, we describe two novel types of planar cyclic peptide templates for the facile addition of ligands that extend axially from the plane of the template ring. The first uses beta-amino acids of alternating D- and L-chirality, since the insertion of the additional methylene group in the peptide backbone was predicted and subsequently shown by NMR and molecular modeling, to reorient ligands attached to amino acid side chain axially with respect to the template ring. A second contains alternating D- and L-amino acids with an achiral Gly residue interposed between each chiral amino acid. The inserted Gly residues also tend to reorient side chains axially rather than radially, as was demonstrated by NMR and molecular modeling. The axial orientation of attached ligands is intended to foster or allow interactions among attached ligands in situations in which this is desired. Two such situations that we consider are (1) development of immunological reagents with avidity effects and (2) modeling of oligomers in fibril-forming peptides. Toward the first of these goals, we demonstrated that these templates are suitable for attaching macromolecules, by incorporating two types of protein, neutravidin and trypsinogen. Toward the second goal, we demonstrate the attachment of two different fibril-forming peptides to the template. The templates described herein thus have many of the desirable traits of such molecules, i.e., (1) multivalency for the attachment of multiple ligands, (2) suitable chemical functions for facile attachment of ligands, (3) versatility as to the number and spacing of ligand attachment sites, (4) sufficient rigidity so that the attached ligands can be similarly oriented with respect to the template, and (5) sufficient flexibility to allow even large ligands, such as proteins, to attach and interact.

Published

2009

44. C-H stretching vibrations of methyl, methylene and methine groups at the vapor/alcohol (N = 1-8) interfaces.

Author

Lu R, Gan W, Wu BH, Zhang Z, Guo Y, and Wang HF

Subjects

2-Propanol chemistry, Algorithms, Ethanol chemistry, Gases, Lasers, Light, Methanol chemistry, Phase Transition, Spectrophotometry, Infrared, Spectrum Analysis, Raman, Vibration, Volatilization, Carbon chemistry, Hydrogen chemistry, Models, Chemical

Abstract

In IR and Raman spectral studies, the congestion of the vibrational modes in the C-H stretching region between 2800 and 3000 cm(-1) has complicated spectral assignment, conformational analysis, and structural and dynamics studies, even with quite a few of the simplest molecules. To resolve these issues, polarized spectra measurement on a well aligned sample is generally required. Because the liquid interface is generally ordered and molecularly thin, and sum frequency generation vibrational spectroscopy (SFG-VS) is an intrinsically coherent polarization spectroscopy, SFG-VS can be used for discerning details in vibrational spectra of the interfacial molecules. Here we show that, from systematic molecular symmetry and SFG-VS polarization analysis, a set of polarization selection rules could be developed for explicit assignment of the SFG vibrational spectra of the C-H stretching modes. These polarization selection rules helped assignment of the SFG-VS spectra of vapor/alcohol (n = 1-8) interfaces with unprecedented details. Previous approach on assignment of these spectra relied on IR and Raman spectral assignment, and they were not able to give such detailed assignment of the SFG vibrational spectra. Sometimes inappropriate assignment was made, and consequently misleading conclusions on interfacial structure, conformation and even dynamics were reached. With these polarization rules in addition to knowledge from IR and Raman studies, new structural information and understanding of the molecular interactions at these interfaces were obtained, and some new spectral features for the C-H stretching modes were also identified. Generally speaking, these new features can be applied to IR and Raman spectroscopic studies in the condensed phase. Therefore, the advancement on vibrational spectra assignment may find broad applications in the related fields using IR and Raman as vibrational spectroscopic tools.

Published

2005

45. Determination of structure and energetics for gibbs surface adsorption layers of binary liquid mixture 2. Methanol + water.

Author

Chen H, Gan W, Lu R, Guo Y, and Wang HF

Abstract

Vapor/methanol and vapor/methanol-water mixture interfaces have been among the benchmark liquid interfaces under extensive experimental and theoretical investigation. In this report, we studied the orientation, structure and energetics of the vapor/methanol-water interface with newly developed techniques in sum frequency generation vibrational spectroscopy (SFG-VS). Different from the interpretations in previous SFG-VS studies for a more disordered interface at higher bulk methanol concentrations, we found that the methanol-water mixture interface is well ordered in the whole concentration region. We are able to do so because direct polarization null angle (PNA) measurement allowed us to accurately determine the CH3 orientation at the interface and to separate the orientational and interface density contributions to the SFG-VS signal. We found that the CH3 groups at the interface pointed out almost perpendicularly from the interface. We further found that this well-ordered vapor/methanol-water mixture interface has an antiparallel structure. With the double layer adsorption model (DAM) and Langmuir isotherm, the adsorption free energies for the first and second layer are obtained as -1.7 +/- 0.1 kcal/mol and 0.5 +/- 0.4 kcal/mol, respectively. Therefore, the second layer adsorption is slightly negative, and this means that replacement of the second layer water molecule with methanol molecule is energetically unfavorable. Comparing this interface with the vapor/acetone-water mixture interface reported previously, we are able to correlate the second layer adsorption free energy with the work of self-association using the pairwise self- and mutual interaction energies between the water and solute molecules. These results provided detailed microscopic structural evidences for understanding of liquid interfaces.

Published

2005

46. Determination of structure and energetics for gibbs surface adsorption layers of binary liquid mixture 1. Acetone + water.

Author

Chen H, Gan W, Wu BH, Wu D, Guo Y, and Wang HF

Abstract

The orientation, structure, and energetics of the vapor/acetone-water interface are studied with sum frequency generation vibrational spectroscopy (SFG-VS). We used the polarization null angle (PNA) method in SFG-VS to accurately determine the interfacial acetone molecule orientation, and we found that the acetone molecule has its C=O group pointing into bulk phase, one CH3 group pointing up from the bulk, and the other CH3 group pointing into the bulk phase. This well-ordered interface layer induces an antiparallel structure in the second layer through dimer formation from either dipolar or hydrogen bond interactions. With a double-layer adsorption model (DAM) and Langmuir isotherm, the adsorption free energies for the first and second layer are determined as deltaG degrees (ads,1) = - 1.9 +/- 0.2 kcal /mol and deltaG degrees (ads,2) = - 0.9 +/- 0.2 kcal /mol, respectively. Since deltaG degrees (ads,1) is much larger than the thermal energy kT = 0.59 kcal /mol, and deltaG degrees (ads,2) is close to kT, the second layer has to be less ordered. Without either strong dipolar or hydrogen bonding interactions between the second and the third layer, the third layer should be randomly thermalized as in the bulk liquid. Therefore, the thickness of the interface is not more than two layers thick. These results are consistent with previous MD simulations for the vapor/pure acetone interface, and undoubtedly provide direct microscopic structural evidences and new insight for the understanding of liquid and liquid mixture interfaces. The experimental techniques and quantitative analysis methodology used for detailed measurement of the liquid mixture interfaces in this report can also be applied to liquid interfaces, as well as other molecular interfaces in general.

Published

2005

47. Polymerization-induced viscoelastic phase separation in polyethersulfone-modified epoxy systems.

Author

Yu Y, Wang M, Gan W, Tao Q, and Li S

Abstract

The polymerization-induced phase-separation process of polyethersulfone (PES)-modified epoxy systems was monitored in situ continuously on a single sample throughout the entire curing process by using optical microscopes, time-resolved light scattering (TRLS), scanning electronic microscopes (SEM), and a rheometry instrument. At specific PES content a viscoelastic transformation process of phase inversion morphology to bicontinuous was found with an optical microscope. The rheological behavior during phase separation corresponds well with the morphology development. Light-scattering results monitoring the phase-separation process of systems with final phase inversion morphology show a typical exponential decay procedure of scattering vector qm. The characteristic relaxation time of phase separation can be described well by the WLF equation.

Published

2004

48. Self-assembly of unlike homopolymers into hollow spheres in nonselective solvent.

Author

Duan H, Chen D, Jiang M, Gan W, Li S, Wang M, and Gong J

Subjects

Chloroform chemistry, Macromolecular Substances, Micelles, Microscopy, Atomic Force, Microscopy, Electron, Solvents, Imides chemistry, Polymers chemistry, Polyvinyls chemistry

Published

2001

49. Quantitative structure-activity relationships of 2, 4-diamino-5-(2-X-benzyl)pyrimidines versus bacterial and avian dihydrofolate reductase.

Author

Selassie CD, Gan WX, Kallander LS, and Klein TE

Subjects

Animals, Anti-Bacterial Agents chemistry, Anti-Bacterial Agents metabolism, Anti-Bacterial Agents pharmacology, Chickens, Folic Acid Antagonists chemistry, Folic Acid Antagonists metabolism, Folic Acid Antagonists pharmacology, Lacticaseibacillus casei enzymology, Liver enzymology, Protein Binding, Structure-Activity Relationship, Anti-Bacterial Agents chemical synthesis, Folic Acid Antagonists chemical synthesis, Models, Molecular, Tetrahydrofolate Dehydrogenase metabolism

Abstract

Quantitative structure-activity relationships (QSAR) have been formulated for a set of 15 2,4-diamino-5-(2-X-benzyl)pyrimidines versus dihydrofolate reductase from Lactobacillus casei and chicken liver. QSARs were also developed for comprehensive data sets containing mono-, di-, and trisubstituted benzyl derivatives. Particular emphasis was placed on the role played by ortho substituents in the overall binding process and subsequent inhibition of the catalytic process in both the prokaryotic and eucaryotic DHFRs. Comparisons between the two QSARs reveal subtle differences at specific positions which can be optimized to design more selective antibacterial agents.

Published

1998