Tag: M.W=200-250

Xie, Heping published the artcileElectricity generation by a novel CO2 mineralization cell based on organic proton-coupled electron transfer, SDS of cas: 23783-42-8, the main research area is carbon dioxide organic proton coupled electron transfer electricity mineralization.

Carbon dioxide (CO2) mineralization is an advantageous and effective way to reduce CO2 emissions. In previous work, our research group presented a CO2 mineralization cell that sued alk. solid waste and CO2 as raw materials to produce both electricity and baking soda. Two generations of the cell have been developed. In this paper, we report a novel version of the CO2 mineralization cell in which a highly soluble, proton-coupled electron transfer (PCET), organic redox couple is used to facilitate CO2 mineralization and electricity generation without the need of a precious metal catalyst such as platinum. The cell presented a maximum power d. of 96.75 W m-2 (much higher than that the previously reported mineralization cells without a PCET redox couple). This cell could generate 146 kWh per ton of CO2 mineralized. The reaction mechanism of the cell is based on PCET considerably improved power generation capacity towing to the excellent characteristics of the organic catalyst. This idea provides a new direction toward solving the problem of needing precious metal catalysts in fuel cells.

Applied Energy published new progress about Basicity. 23783-42-8 belongs to class ethers-buliding-blocks, name is 2,5,8,11-Tetraoxatridecan-13-ol, and the molecular formula is C9H20O5, SDS of cas: 23783-42-8.

Referemce:
Ether – Wikipedia,
Ether | (C2H5)2O – PubChem

Brunner, Andrea M. published the artcileIntegration of target analyses, non-target screening and effect-based monitoring to assess OMP related water quality changes in drinking water treatment, Name: 2,5,8,11,14-Pentaoxapentadecane, the main research area is drinking water treatment monitoring organic micro pollutant; Bioassays; Drinking water treatment; HRMS-based non-target screening; Organic micro-pollutants; Target analyses; Water quality.

The ever-increasing production and use of chems. lead to the occurrence of organic micro-pollutants (OMPs) in drinking water sources, and consequently the need for their removal during drinking water treatment. Due to the sheer number of OMPs, monitoring using targeted chem. analyses alone is not sufficient to assess drinking water quality as well as changes thereof during treatment. High-resolution mass spectrometry (HRMS) based non-target screening (NTS) as well as effect-based monitoring using bioassays are promising monitoring tools for a more complete assessment of water quality and treatment performance. Here, we developed a strategy that integrates data from chem. target analyses, NTS and bioassays. We applied it to the assessment of OMP related water quality changes at three drinking water treatment pilot installations. These installations included advanced oxidation processes, ultrafiltration in combination with reverse osmosis, and granular activated carbon filtration. OMPs relevant for the drinking water sector were spiked into the water treated in these installations. Target analyses, NTS and bioassays were performed on samples from all three installations. The NTS data was screened for predicted and known transformation products of the spike-in compounds In parallel, trend profiles of NTS features were evaluated using multivariate anal. methods. Through integration of the chem. data with the biol. effect-based results potential toxicity was accounted for during prioritization. Together, the synergy of the three anal. methods allowed the monitoring of OMPs and transformation products, as well as the integrative biol. effects of the mixture of chems. Through efficient anal., visualization and interpretation of complex data, the developed strategy enabled to assess water quality and the impact of water treatment from multiple perspectives. Such information could not be obtained by any of the three methods alone. The developed strategy thereby provides drinking water companies with an integrative tool for comprehensive water quality assessment.

Science of the Total Environment published new progress about Bioassay. 143-24-8 belongs to class ethers-buliding-blocks, name is 2,5,8,11,14-Pentaoxapentadecane, and the molecular formula is C10H22O5, Name: 2,5,8,11,14-Pentaoxapentadecane.

Referemce:
Ether – Wikipedia,
Ether | (C2H5)2O – PubChem

Merrill, Laura C. published the artcilePolymer-Ceramic Composite Electrolytes for Lithium Batteries: A Comparison between the Single-Ion-Conducting Polymer Matrix and Its Counterpart, Application of 2,5,8,11,14-Pentaoxapentadecane, the main research area is polymer ceramic composite single ion conducting electrolyte lithium battery.

Single-ion-conducting polymer electrolytes are attractive to use in lithium batteries as the transference number of the lithium cation approaches unity. This helps prevent concentration gradients across the electrolyte, which can result in dendrite formation. The addition of ceramic particles to polymer electrolytes at high loadings can increase the mech. strength of the polymer, which can also help suppress dendrite formation. Here, a single-ion-conducting polymer electrolyte is blended with lithium-conducting oxide ceramic particles to make a composite electrolyte. This electrolyte is studied in comparison to a composite electrolyte containing freely dissolved lithium salt. It is found that the addition of ceramic particles to the single-ion-conducting polymer can result in increased cation dissociation and consequent increased ionic conductivity The electrolytes are cycled in lithium sym. cells, and it is found that the ceramic-containing electrolytes show increased interfacial stability with the lithium metal compared to the pristine polymer electrolytes. Our findings shed light on how to optimize the polymer host chem. to form composite electrolytes that can meet the challenging requirements to stabilize the lithium metal anode.

ACS Applied Energy Materials published new progress about Ceramics. 143-24-8 belongs to class ethers-buliding-blocks, name is 2,5,8,11,14-Pentaoxapentadecane, and the molecular formula is C10H22O5, Application of 2,5,8,11,14-Pentaoxapentadecane.

Referemce:
Ether – Wikipedia,
Ether | (C2H5)2O – PubChem

Semlali, Sanaa published the artcileEffect of solvent on silicon nanoparticle formation and size: a mechanistic study, Recommanded Product: 2,5,8,11,14-Pentaoxapentadecane, the main research area is silicon nanoparticle formation size solvent effect.

Silicon has emerged as the most desirable material for optical dielec. metamaterials, however chemists struggle to obtain the required silicon nanoparticle dimensions. Here the average diameter of silicon nanoparticles is varied between 3 and 15 nm by changing the reaction solvent. Electrochem. and NMR elucidate the role of solvent on the synthetic mechanism. Surprisingly the solvent does not stabilize the nanoparticles and there is no trend associated with chain length or open-chain vs. cyclical solvent mols. The solvent’s main role is to stabilize the byproducts, which prolongs the reaction lifetime.

Nanoscale published new progress about Clusters. 143-24-8 belongs to class ethers-buliding-blocks, name is 2,5,8,11,14-Pentaoxapentadecane, and the molecular formula is C10H22O5, Recommanded Product: 2,5,8,11,14-Pentaoxapentadecane.

Referemce:
Ether – Wikipedia,
Ether | (C2H5)2O – PubChem

Li, Ming-Shuang published the artcileCucurbit[n]urils (n = 7, 8) can strongly bind neutral hydrophilic molecules in water, Recommanded Product: 2,5,8,11,14-Pentaoxapentadecane, the main research area is cucurbituril crown ether dioxane inclusion reaction kinetics hydrogen bond.

It is challenging to recognize neutral hydrophilic mols. in water. Effective use of hydrogen bonds in water is generally accepted to be the key to success. In contrast, hydrophobic cavity is usually considered to play an insignificant role or only to provide a nonpolar microenvironment for hydrogen bonds. Herein, we report that hydrophobic cavity alone can also strongly bind neutral, highly hydrophilic mols. in water. We found that cucurbit[n]urils (n = 7, 8) bind 1,4-dioxane, crown ethers and monosaccharides in water with remarkable affinities. The best binding constant reaches 107 M-1 for cucurbit[8]uril, which is higher than its binding affinities to common organic cations. D. functional theory (DFT) calculations and control experiments reveal that the hydrophobic effect is the major contributor to the binding through releasing the cavity water and/or properly occupying the weakly hydrated cavity. However, hydrophobic cavity still prefers nonpolar guests over polar guests with similar size and shape.

Science China: Chemistry published new progress about Enthalpy. 143-24-8 belongs to class ethers-buliding-blocks, name is 2,5,8,11,14-Pentaoxapentadecane, and the molecular formula is C10H22O5, Recommanded Product: 2,5,8,11,14-Pentaoxapentadecane.

Referemce:
Ether – Wikipedia,
Ether | (C2H5)2O – PubChem

Januszewski, Rafal published the artcileSynthesis and Properties of Epoxy Resin Modified with Novel Reactive Liquid Rubber-Based Systems, Recommanded Product: 2,5,8,11,14-Pentaoxapentadecane, the main research area is epoxy resin reactive liquid rubber.

In this work, the influence of the new epoxy-containing liquid rubber-based modifiers on the thermal and mech. properties of the cured epoxy resins was investigated. The epoxy-functional polybutadienes obtained via the conventional epoxidation reaction or catalytic hydrosilylation have been successfully applied for modification of com. available epoxy resin to modulate its mech. properties. Different locations of oxirane rings in the polybutadiene chains revealed a significant impact of the rubber-based modifier structure on the thermal and mech. properties of cured resins.

Industrial & Engineering Chemistry Research published new progress about Enthalpy. 143-24-8 belongs to class ethers-buliding-blocks, name is 2,5,8,11,14-Pentaoxapentadecane, and the molecular formula is C10H22O5, Recommanded Product: 2,5,8,11,14-Pentaoxapentadecane.

Referemce:
Ether – Wikipedia,
Ether | (C2H5)2O – PubChem

Jozwiak, Malgorzata published the artcileSolvation enthalpy of selected glymes in the mixtures of N,N-dimethylformamide with propan-1-ol or methanol at 298.15 K. The solvent contribution to the solvation enthalpy of glymes, HPLC of Formula: 143-24-8, the main research area is solvation enthalpy glymes DMF methanol solvent.

The enthalpies of solution of monoglyme, diglyme, triglyme, tetraglyme, pentaglyme and hexaglyme in N,N-dimethylforamide+propan-1-ol mixtures have been measured at 298.15 K. The preferential solvation process of glymes mols. in the mixtures of N,N-dimethylformamide with methanol or propan-1-ol has been discussed. Then the contribution of DMF, PrOH, and MeOH to the solvation enthalpy of group (-CH2- and -O-) of glymes has been calculated On the basis of the obtained data, the effect of the structural and energetic properties of the N,N-dimethylforamide+propan-1-ol mixtures on the solution enthalpy of glymes in this mixtures has been analyzed.

Journal of Molecular Liquids published new progress about Enthalpy. 143-24-8 belongs to class ethers-buliding-blocks, name is 2,5,8,11,14-Pentaoxapentadecane, and the molecular formula is C10H22O5, HPLC of Formula: 143-24-8.

Referemce:
Ether – Wikipedia,
Ether | (C2H5)2O – PubChem

Potangale, Mangesh published the artcileCorrelation of the empirical polarity parameters of solvate ionic liquids (SILs) with molecular structure, Related Products of ethers-buliding-blocks, the main research area is solvate ionic liquid mol structure empirical polarity parameter.

Empirical polarity parameters for 10 solvate ionic liquids (SILs) have been determined using Catalans probes. The solvation environment surrounding the probe mols. in the SILs is dependent on the mutual interactions between the cation, anion and chelating ligand, leading to characteristic values of the polarity parameters. The acidity of the SILs is comparable to the acidity of polar protic solvents, which is attributed to the ability of the Li cation to interact with the probe in a manner similar to H-bond donor. The choice of anion influenced the measured acidity of SILs by determining the extent of cation-probe interactions possible. The basicity showed a strong correlation with the nature of the anion but was also influenced by the extent of cation-anion interaction and choice of ligand. Temperature dependence of polarity parameters in SILs is relatively small, but shows some interesting trends.

Journal of Molecular Liquids published new progress about Acidity. 143-24-8 belongs to class ethers-buliding-blocks, name is 2,5,8,11,14-Pentaoxapentadecane, and the molecular formula is C10H22O5, Related Products of ethers-buliding-blocks.

Referemce:
Ether – Wikipedia,
Ether | (C2H5)2O – PubChem

Lee, Dawoon published the artcileHighly Flexible and Stable Solid-State Supercapacitors Based on a Homogeneous Thin Ion Gel Polymer Electrolyte Using a Poly(dimethylsiloxane) Stamp, Formula: C10H22O5, the main research area is flexible supercapacitor ion gel polymer electrolyte methylsiloxane stamp; ion gel polymer electrolyte (IGPE); metal−insulator−metal (MIM) capacitor; silicone-based elastomer; stamping method; supercapacitor.

To achieve both high structural integrity and excellent ion transport, designing ion gel polymer electrolytes (IGPEs) composed of an ionic conducting phase and a mech. supporting polymer matrix is one of the promising material strategies for the development of next-generation all-solid-state energy storage systems. Herein, an IGPE thin film is prepared, in which an ion-diffusing phase containing ionic liquids and lithium salts was bicontinuously intertwined with a cross-linked epoxy phase, using a silicon elastomer-based stamping method, thus producing a homogeneous IGPE-based thin film with low surface roughness = 0.5 nm. Following the optimization of the IGPE thin film in terms of the concentrations of ionic constituents, the film thickness, and various process parameters, the IGPE itself showed a high ionic conductivity of 0.23 mS/cm with a low activation energy for lithium-ion transport, as well as the high capacitance of approx. 10μF/cm2 based on the metal-insulator-metal configuration. Furthermore, an all-solid-state supercapacitor containing two IGPE coating-activated carbon electrodes produced using the poly(dimethylsiloxane) (PDMS) stamping method exhibited high energy and power densities (44 W h/kg at 875 W/kg and 28 kW/kg at 3 W h/kg). It was also found that this supercapacitor showed a dramatic reduction (> 50%) of the current-resistance (IR) drop, which is an indicator of low interface resistance, while maintaining the initial electrochem. performance even after severe mech. deformation such as bending or rolling. Therefore, all these results support the fact that our developed PDMS stamping method enables the rendering of a high-performance ion gel polymer thin-film-based electrolyte with acceptable stability and mech. flexibility for all-solid-state wearable energy storage devices.

ACS Applied Materials & Interfaces published new progress about Bending. 143-24-8 belongs to class ethers-buliding-blocks, name is 2,5,8,11,14-Pentaoxapentadecane, and the molecular formula is C10H22O5, Formula: C10H22O5.

Referemce:
Ether – Wikipedia,
Ether | (C2H5)2O – PubChem

Jabbari, Vahid published the artcileA Smart Lithium Battery with Shape Memory Function, Category: ethers-buliding-blocks, the main research area is lithium battery shape memory polymer ionic conductivity mech deformation; flexible electronics; mechanical deformation; shape memory polymer electrolytes; shape recovery; shape-adjustable batteries.

Rapidly growing flexible and wearable electronics highly demand the development of flexible energy storage devices. Yet, these devices are susceptible to extreme, repeated mech. deformations under working circumstances. Herein, the design and fabrication of a smart, flexible Li-ion battery with shape memory function, which has the ability to restore its shape against severe mech. deformations, bending, twisting, rolling or elongation, is reported. The shape memory function is induced by the integration of a shape-adjustable solid polymer electrolyte. This Li-ion battery delivers a specific discharge capacity of ≈140 mAh g-1 at 0.2 C charge/discharge rate with ≈92% capacity retention after 100 cycles and ≈99.85% Coulombic efficiency, at 20°C. Besides recovery from mech. deformations, it is visually demonstrated that the shape of this smart battery can be programmed to adjust itself in response to an internal/external heat stimulus for task-specific and advanced applications. Considering the vast range of available shape memory polymers with tunable chem., phys., and mech. characteristics, this study offers a promising approach for engineering smart batteries responsive to unfavorable internal or external stimulus, with potential to have a broad impact on other energy storage technologies in different sizes and shapes.

Small published new progress about Bending. 143-24-8 belongs to class ethers-buliding-blocks, name is 2,5,8,11,14-Pentaoxapentadecane, and the molecular formula is C10H22O5, Category: ethers-buliding-blocks.

Referemce:
Ether – Wikipedia,
Ether | (C2H5)2O – PubChem