443 research outputs found
Synergistic Reinforcing Mechanisms in Cellulose Nanofibrils Composite Hydrogels: Interfacial Dynamics, Energy Dissipation, and Damage Resistance
Engineering
reversible cross-links between nanoparticles and polymer
matrix is a promising avenue to reinforce the mechanical properties
of elastomers and in particular soft hydrogels. In this work, we study
a model system of composite hydrogel reinforced with cellulose nanofibrils
(CNFs), where the integration of reversible hydrogen bonds into a
lightly covalently cross-linked polyacrylamide (PAAm) matrix. This
approach yields the dual cross-linked networks with synergistically
improved strength, modulus, and toughness. The reversible nature of
the hydrogen-bonded cross-links manifests a strong strain rate (ΔÌ)
dependent dynamics properties. The CNF-PAAm interaction among physically
adsorbed chains on the surface of CNF is examined as a function of
CNF fraction by sum frequency generation spectroscopy. The results
indicate a decrease of the number of free âOH groups on the
CNF surface. Moreover, the deformation-resting experiments show a
unique interface stiffening mechanism where the polymer chains desorbed
from the CNF surface under oscillatory shear become entangled during
resting time. The bending micromechanics test reveals that the CNF
interfacial slip imparts the capability to strengthen the composites
during deformation. The fibril pull-out process activates a series
of dissipation mechanisms that increase the crack propagation resistance.
These findings advance our understanding the role of interfacial layer
in microscopic reinforcement mechanism and provide a constitutive
foundation for exploring the deformation behaviors of the cellulosic
hydrogels
Simulation codes for PDE and generalised Landauâ Levich equation
Simulation codes for PDE and generalised Landauâ Levich equatio
An Anionic Heptacopper(II) Oxo-Cluster {Cu<sup>II</sup><sub>7</sub>} with an <i>S</i> = 7/2 Ground State
An anionic heptacopperÂ(II)
oxo-cluster {Cu<sub>7</sub>} was obtained
from a simple reaction in aqueous solution without heating. In a similar
reaction, another cage compound {Sb<sub>12</sub>} with an encapsulated
{Cu<sub>2</sub>} core was produced, implying the structural versatility
of copperÂ(II)-oxide assemblies constructed from potassium antimonyl
tartrate as the ligand in aqueous solution. The ferromagnetic <i>S</i> = 7/2 ground state of {Cu<sub>7</sub>} is confirmed by
magnetization measurements
Enantiomerically Pure Chiral {Cu<sup>II</sup><sub>32</sub>}âBased 2D-Layered Frameworks: From the Asymmetric Octacopper(II) Subcomponents to 3D Hierarchical Supramolecular Structures
Two new chiral copperÂ(II) coordination
polymers comprising octacopperÂ(II) subcomponents were synthesized
through investigation of the interplay among tartrate ligands, guanidinium
cations, and metals. Our analysis confirms that these compounds are
enantiomers exhibiting 3D hierarchical supramolecular structures that
are constituted by 2D sublayers and sustained by noncovalent bonding
interactions
Discovery of components in honeysuckle for treating COVID-19 and diabetes based on molecular docking, network analysis and experimental validation
Molecular docking screening identified ochnaflavone, madreselvin B and hydnocarpin as key components for treating COVID-19 with diabetes in honeysuckle using 3âC-like protease (Mpro), angiotensin-converting enzyme 2 (ACE2), and dipeptidyl peptidase 4 (DPP4) as molecular docking targets, ACE2, DPP4, IL2, NFKB1, PLG, TBK1, TLR4 and TNF were the core targets, and multiple antiviral and anti-inflammatory signalling pathways were involved. Further, the levels of IL-1ÎČ and DPP4 in cell supernatant that had been activated by LPS was decreased by hypnocarpin, and ACE2 protein and DPP4 mRNA in cells were down-regulated. Overall, we have identified three components from honeysuckle that have potency to treat COVID-19 combined with diabetes. SARS-CoV-2 transcription may be inhibited by these components in honeysuckle, reducing virus invasion, inhibiting inflammatory factors, and improving immune response. Our findings could provide a basis for the clinical application and further development of honeysuckle.</p
Model estimate results.
<p>Model estimate results.</p
Bottom-Up Self-Assembly of the Sphere-Shaped Icosametallic Oxo Clusters {Cu<sub>20</sub>} and {Cu<sub>12</sub>Zn<sub>8</sub>}
A discrete nanospheric icosametallic
cluster comprised of 20 Cu ions (<b>1</b>) was self-assembled
from facile synthesis. Adjustment of the synthesis by the choice of
ligands gave rise to another cluster (<b>2</b>) with an intact
icosacupric core and improved stability. Referring to the synthesis
of <b>1</b> and <b>2</b>, a heterometallic cluster (<b>3</b>), which contains 12 Cu<sup>II</sup> and 8 Zn<sup>II</sup>, was designed and characterized by single-crystal X-ray diffraction,
combined with elemental analysis, energy-dispersive X-ray, X-ray photoelectron
spectroscopy, thermogravimetric analysis, and element mapping. The
magnetic measurements of <b>2</b> and <b>3</b> and the
scanning electron microscopy images and UVâvisible diffuse-reflectance
measurements of metal oxides from <b>2</b> and <b>3</b> indicate that isolation of {Cu<sub>12</sub>M<sub>8</sub>} is a new
synthetic route to materials with engineered properties
2013 regional PM<sub>2.5</sub> concentration trends.
<p>2013 regional PM<sub>2.5</sub> concentration trends.</p
Bottom-Up Self-Assembly of the Sphere-Shaped Icosametallic Oxo Clusters {Cu<sub>20</sub>} and {Cu<sub>12</sub>Zn<sub>8</sub>}
A discrete nanospheric icosametallic
cluster comprised of 20 Cu ions (<b>1</b>) was self-assembled
from facile synthesis. Adjustment of the synthesis by the choice of
ligands gave rise to another cluster (<b>2</b>) with an intact
icosacupric core and improved stability. Referring to the synthesis
of <b>1</b> and <b>2</b>, a heterometallic cluster (<b>3</b>), which contains 12 Cu<sup>II</sup> and 8 Zn<sup>II</sup>, was designed and characterized by single-crystal X-ray diffraction,
combined with elemental analysis, energy-dispersive X-ray, X-ray photoelectron
spectroscopy, thermogravimetric analysis, and element mapping. The
magnetic measurements of <b>2</b> and <b>3</b> and the
scanning electron microscopy images and UVâvisible diffuse-reflectance
measurements of metal oxides from <b>2</b> and <b>3</b> indicate that isolation of {Cu<sub>12</sub>M<sub>8</sub>} is a new
synthetic route to materials with engineered properties
Bottom-Up Self-Assembly of the Sphere-Shaped Icosametallic Oxo Clusters {Cu<sub>20</sub>} and {Cu<sub>12</sub>Zn<sub>8</sub>}
A discrete nanospheric icosametallic
cluster comprised of 20 Cu ions (<b>1</b>) was self-assembled
from facile synthesis. Adjustment of the synthesis by the choice of
ligands gave rise to another cluster (<b>2</b>) with an intact
icosacupric core and improved stability. Referring to the synthesis
of <b>1</b> and <b>2</b>, a heterometallic cluster (<b>3</b>), which contains 12 Cu<sup>II</sup> and 8 Zn<sup>II</sup>, was designed and characterized by single-crystal X-ray diffraction,
combined with elemental analysis, energy-dispersive X-ray, X-ray photoelectron
spectroscopy, thermogravimetric analysis, and element mapping. The
magnetic measurements of <b>2</b> and <b>3</b> and the
scanning electron microscopy images and UVâvisible diffuse-reflectance
measurements of metal oxides from <b>2</b> and <b>3</b> indicate that isolation of {Cu<sub>12</sub>M<sub>8</sub>} is a new
synthetic route to materials with engineered properties
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