Esters-buliding-blocks

Soudagar, Manzoore Elahi. M. published the artcileThe effects of graphene oxide nanoparticle additive stably dispersed in dairy scum oil biodiesel-diesel fuel blend on CI engine: performance, emission and combustion characteristics, Product Details of C9H18O2, the main research area is graphene oxide nanoparticle biodiesel diesel blend engine combustion emission.

In the present investigation, the effects of graphene oxide nanoparticles on performance and emissions of a CI engine fueled with dairy scum oil biodiesel was studied. Nanofuel blend was prepared by dispersing graphene oxide in varying quantities in dairy scum oil Me ester (DSOME)-diesel blend. Sodium dodecyl sulfate (SDS) was used as a surfactant for a steady dispersion of graphene oxide nanoparticles in the fuel blends. The dispersion and homogeneity were characterized by UV-visible spectrometry. An ideal graphene-to-surfactant ratio was defined, highest absolute value UV-absorbency was seen for a mass fraction of 1:4. The concentration of surfactant above or below this ratio resulted in reduction in the stability of dispersion. Graphene oxide nanoparticles were amalgamated with dairy scum oil biodiesel at proportions of 20, 40 and 60 ppm using ultrasonication technique. Experiments were performed at a constant speed and varying the brake power and load condtions. The results were notable enhancements in the performance and emissions characteristics, the brake thermal efficiency improved by 11.56%, a reduction in brake specific fuel consumption by 8.34%, unburnt hydrocarbon by 21.68%, smoke by 24.88%, carbon monoxide by 38.662% for the nanofuel blend DSOME2040 and oxides of nitrogen emission by 5.62% for fuel DSOME(B20). Similarly, the addition of graphene nanoparticles in DSOME fuel blends resulted in significant reduction in the combustion duration, ignition delay period, improvement in the peak pressure and heat release rate at maximum load condition. Finally, it is concluded that nano-graphene oxide nanoparticles can be introduced as a suitable substitute fuel additive for dairy scum oil biodiesel blends to enhance the overall engine performance and emissions characteristics.

Fuel published new progress about Absorption. 111-11-5 belongs to class esters-buliding-blocks, name is Methyl octanoate, and the molecular formula is C9H18O2, Product Details of C9H18O2.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Soudagar, Manzoore Elahi. M. published the artcileThe effects of graphene oxide nanoparticle additive stably dispersed in dairy scum oil biodiesel-diesel fuel blend on CI engine: performance, emission and combustion characteristics, Synthetic Route of 110-42-9, the main research area is graphene oxide nanoparticle biodiesel diesel blend engine combustion emission.

In the present investigation, the effects of graphene oxide nanoparticles on performance and emissions of a CI engine fueled with dairy scum oil biodiesel was studied. Nanofuel blend was prepared by dispersing graphene oxide in varying quantities in dairy scum oil Me ester (DSOME)-diesel blend. Sodium dodecyl sulfate (SDS) was used as a surfactant for a steady dispersion of graphene oxide nanoparticles in the fuel blends. The dispersion and homogeneity were characterized by UV-visible spectrometry. An ideal graphene-to-surfactant ratio was defined, highest absolute value UV-absorbency was seen for a mass fraction of 1:4. The concentration of surfactant above or below this ratio resulted in reduction in the stability of dispersion. Graphene oxide nanoparticles were amalgamated with dairy scum oil biodiesel at proportions of 20, 40 and 60 ppm using ultrasonication technique. Experiments were performed at a constant speed and varying the brake power and load condtions. The results were notable enhancements in the performance and emissions characteristics, the brake thermal efficiency improved by 11.56%, a reduction in brake specific fuel consumption by 8.34%, unburnt hydrocarbon by 21.68%, smoke by 24.88%, carbon monoxide by 38.662% for the nanofuel blend DSOME2040 and oxides of nitrogen emission by 5.62% for fuel DSOME(B20). Similarly, the addition of graphene nanoparticles in DSOME fuel blends resulted in significant reduction in the combustion duration, ignition delay period, improvement in the peak pressure and heat release rate at maximum load condition. Finally, it is concluded that nano-graphene oxide nanoparticles can be introduced as a suitable substitute fuel additive for dairy scum oil biodiesel blends to enhance the overall engine performance and emissions characteristics.

Fuel published new progress about Absorption. 110-42-9 belongs to class esters-buliding-blocks, name is Methyl decanoate, and the molecular formula is C11H22O2, Synthetic Route of 110-42-9.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Bryuzgin, Evgeny published the artcileBiodegradation Control of Chitosan Materials by Surface Modification with Copolymers of Glycidyl Methacrylate and Alkyl Methacrylates, SDS of cas: 142-90-5, the main research area is glycidyl methacrylate chitosan biodegradation surface modification.

Chitosan is a promising polymer from natural polysaccharides, which is an environmentally friendly compound from renewable raw materials. Chitosan has biodegradability, biocompatibility, and antibacterial and other activities. In this article, we report the biodegradation control of chitosan materials by use of random copolymers based on glycidyl methacrylate and (fluoro)alkyl methacrylates as surface modifiers. We show that grafting of copolymers allows increasing the hydrophobicity of chitosan materials with initial contact angles up to 114° from 89° for films and up to 154° from 123° for aerogels. We demonstrate that modified aerogels retain contact angles of more than 150° for a long contact time with water while the initial aerogel fully wets for 30 s. The resulting chitosan aerogels have high porosity with a pore size of 100-200 μm, and the pore walls are 0.6-0.7-μm-thick film formations. Our study of lyophilic properties of modified chitosan substrates showed a change in the hydrophobicity of the materials as a function of length of the hydrocarbon radical in the side groups of the (fluoro)alkyl methacrylates in the copolymers. We demonstrate that the rate of biodegradation of the resulting materials decreases with an increase in the number of hydrophobic groups in the modifier. The obtained chitosan materials with hydrophobic coatings have potential as a protective layer for wound dressings with an extended service life.

Fibers and Polymers published new progress about Absorption. 142-90-5 belongs to class esters-buliding-blocks, name is Dodecyl 2-methylacrylate, and the molecular formula is C16H30O2, SDS of cas: 142-90-5.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Yang, Ruijie published the artcileThe performance and reaction pathway of δ-MnO2/USY for catalytic oxidation of toluene in the presence of ozone at room temperature, Computed Properties of 140-11-4, the main research area is manganese oxide zeolite toluene catalytic oxidation ozone removal; Catalytic oxidation pathway; Ozone; Toluene; USY; δ-MnO(2).

In this work, a series of δ-MnO2/USY with different contents of δ-MnO2 (0.3 wt%, 1.5 wt%, 3.0 wt%, 10.0 wt%, and 15.0 wt%) were prepared In addition, their performances of the adsorption of toluene, degradation and mineralization of toluene, and removal of ozone (O3) were investigated. The results showed that, among all the samples, 3.0 wt% δ-MnO2/USY displayed the best performance of toluene adsorption, degradation and mineralization. Furthermore, according to the in situ DRIFTS and GC-MS anal., the intermediate byproducts during the toluene degradation progress were ascertained and the possible pathway of catalytic oxidation toluene by δ-MnO2/USY in the presence of O3 was proposed.

Chemosphere published new progress about Absorption. 140-11-4 belongs to class esters-buliding-blocks, name is Benzyl acetate, and the molecular formula is C9H10O2, Computed Properties of 140-11-4.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Shang, Hui published the artcileBiomimetic organohydrogel actuator with high response speed and synergistic fluorescent variation, Formula: C16H30O2, the main research area is biomimetic organohydrogel actuator synergistic fluorescent variation.

Current hydrogel-based actuators have achieved rapid development due to their excellent performance such as shape-morphing and color-changing for application in fields such as camouflage, biomimetic soft-robotics and so on. However, it is still challenging to fabricate soft robots with the capability of simultaneous changes in shape and fluorescent color at a fast speed when triggered by one single stimulus. Herein, an anisotropic organohydogel actuator made up of rGO-doped hydrophilic poly(N-isopropylacrylamide) (PNIPAM) network and hydrophobic poly(lauryl methacrylate) (PLMA) network is prepared via a two-step interpenetrating method. Bearing fluorescent monomer N-(4-(1,2,2-triphenylvinyl)phenyl)acrylamide (ATPE) as well as fluorescent ligand 6-acrylamidopicolinic acid (6APA), the PLMA network shows fluorescent changes in color or brightness depending on the presence or absence of Eu3+ ions in response to heat/NIR. In a word, the proposed organohydrogel actuator, which exhibits simultaneous fluorescence color variation and fast morphing in response to one stimulus, provides insights in designing and fabricating novel soft robots.

Chemical Engineering Journal (Amsterdam, Netherlands) published new progress about Absorption. 142-90-5 belongs to class esters-buliding-blocks, name is Dodecyl 2-methylacrylate, and the molecular formula is C16H30O2, Formula: C16H30O2.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Zhang, Tong published the artcileRational design of lycopene emulsion-based nanofood for Lactobacillus plantarum to enhance the growth and flavor production, HPLC of Formula: 106-32-1, the main research area is Lactobacillus lycopene emulsion nanofood growth flavor.

Lactobacillus plantarum (L. plantarum) is an important probiotic with numerous pos. effects on human health and food processing. Although many studies have focused on improving the growth and activities of probiotics with water-soluble additives, the bioavailability and functional benefits of fat-soluble active substances (FSAS) to probiotics have been neglected their poor water-solubility, which impedes absorption by probiotics. To explore the application of FSAS to L. plantarum, in this work, the emulsion-based nanofood (EBN) was designed to enable adsorption and improve the bioavailability of FSAS to L. plantarum. Properties (including particle size, zeta potential, microstructure, encapsulation rate and storage stability) of the EBN consisting of lycopene-casein-soybean soluble polysaccharide complexes were assayed, and the functions of nanofood in the growing environment of L. plantarum (pH and fluid nutrient medium stability) was explored. The results showed that EBN possessed good properties and stability for the culture of L. plantarum. Compared to resp. control groups, groups containing lycopene EBN not only showed an obvious promotion effect on L. plantarum growth in plate count, but also, at MRS culture medium, greatly enhanced the contents of acids, aldehydes, and other volatile compounds, and increased the total numbers and contents of volatile components by L. plantarum. This study demonstrated that this nanofood is an effective way to regulate the relationship of microorganisms and FSAS.

Food Hydrocolloids published new progress about Absorption. 106-32-1 belongs to class esters-buliding-blocks, name is Ethyl octanoate, and the molecular formula is C10H20O2, HPLC of Formula: 106-32-1.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Srinivasa Rao, B. published the artcileDehydrative etherification of carbohydrates to 5-ethoxymethylfurfural over SBA-15-supported Sn-modified heteropolysilicate catalysts, COA of Formula: C7H12O3, the main research area is carbohydrate ethoxymethylfurfural silica tin heteropolysilicate catalyst dehydrative etherification.

Dehydration followed by the alcoholysis of glucose/fructose to 5-ethoxymethylfurfural (EMF) was carried out over SBA-15-supported tin-modified heteropolysilicate (SnSTA) catalysts. The physico-chem. properties of the catalysts were explored by X-ray diffraction, Fourier-transform IR spectroscopy (FT-IR), pyridine-adsorbed FT-IR spectroscopy, transmission electron microscopy (TEM), N2 physisorption, laser Raman and NH3 temperature-programmed desorption techniques. The characterization results confirmed that the Sn-exchanged STA species were productively embedded inside the pores of SBA-15 without disturbing the parent hexagonal structure. High conversion and selectivity towards EMF were achieved with 20 wt% Sn0.75STA on SBA-15. The high activity of the catalyst could be attributed to the well-dispersed intact Keggin Sn0.75STA on the support, which led to the generation of sufficient Bronsted and Lewis acidic sites. The influence of various reaction parameters such as catalyst weight, reaction temperature, and time was studied along with the stability and reusability of the catalyst.

Sustainable Energy & Fuels published new progress about Absorption. 539-88-8 belongs to class esters-buliding-blocks, name is Ethyl 4-oxopentanoate, and the molecular formula is C7H12O3, COA of Formula: C7H12O3.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Manjunathan, Pandian published the artcileOne-pot fructose conversion into 5-ethoxymethylfurfural using a sulfonated hydrophobic mesoporous organic polymer as a highly active and stable heterogeneous catalyst, Computed Properties of 539-88-8, the main research area is fructose ethoxymethylfurfural organic polymer heterogeneous catalyst.

We report a sulfonated hydrophobic mesoporous organic polymer (MOP-SO3H) as a highly efficient heterogeneous catalyst for one-pot 5-ethoxymethylfurfural (EMF) production from fructose in ethanol solvent. MOP-SO3H was fabricated by co-polymerization of divinylbenzene (DVB) and sodium p-styrene sulfonate (SPSS) followed by ion exchange with dilute H2SO4, and its pore structure and acid d. could be tuned easily by varying the mole ratio of SPSS to DVB. 31P MAS NMR anal. using trimethylphosphine oxide as a base probe mol. indicated that MOP-SO3H possessed a weaker Bronsted acid site than conventional cation-exchange resins. The superhydrophobic properties of MOP-SO3H were retained even after incorporating a greater number of sulfonic acid groups into the polymer framework, while conventional solid acid resins exhibited hydrophilic properties. MOP-SO3H exhibited a superior catalytic performance in comparison with conventional acid resins, a mesoporous acid catalyst, and homogeneous acid catalysts in EMF production from fructose. After optimization of various reaction conditions using MOP-SO3H, a high EMF yield of 72.2% at 99.3% fructose conversion was achieved at 100°C in a very short reaction time of 5 h. Notably, MOP-SO3H showed a much higher EMF formation rate than the Amberlyst-15 catalyst (53.5 vs. 6.1μmol g-1 min-1). This superior performance of the MOP-SO3H catalyst was attributed to its unique feature of large surface area containing a large quantity of readily accessible acid sites distributed throughout the hydrophobic polymer framework. In addition to its high catalytic activity, the notable stability of the MOP-SO3H catalyst was also confirmed by leaching and recyclability tests. Thus, owing to its excellent catalytic performance and easy scalability, MOP-SO3H can potentially be used as an industrial heterogeneous catalyst to produce EMF from various fructose-containing biomass.

Catalysis Science & Technology published new progress about Absorption. 539-88-8 belongs to class esters-buliding-blocks, name is Ethyl 4-oxopentanoate, and the molecular formula is C7H12O3, Computed Properties of 539-88-8.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Gu, Jing published the artcileEfficient transfer hydrogenation of biomass derived furfural and levulinic acid via magnetic zirconium nanoparticles: Experimental and kinetic study, Formula: C7H12O3, the main research area is furfural levulinic acid hydrogenation magnetic zirconium nanoparticle catalyst preparation.

A series of magnetic zirconium nanoparticles with varied Zr/Fe molar ratios were synthesized and developed as acid-base bifunctional catalysts in the catalytic transfer hydrogenation (CTH) of biomass-derived furfural (FFR) and levulinic acid (LA) using 2-propanol as both hydrogen donor and solvent. Zirconium constituents coated on nano-sized Fe3O4 endowed the catalysts with abundant acid-base sites, moderate surface areas (94.0-187.6 m2/g) and pore sizes (3.42-9.51 nm), thus giving nearly 100% yields of furfuryl alc. (FA) and γ-valerolactone (GVL) after 2 h of reaction. Particularly, competitive activation energy (Ea) for the CTH of FFR into FA over Zr1Fe1-300 was as low as 50.9 kJ/mol. Moreover, the easily separable nanocatalyst Zr1Fe1-150 was also applicable to CTH of various alkyl levulinates into GVL in high efficiency and could be reused for multiple cycles without obvious loss of its catalytic performance in the transfer hydrogenation of LA.

Industrial Crops and Products published new progress about Absorption. 539-88-8 belongs to class esters-buliding-blocks, name is Ethyl 4-oxopentanoate, and the molecular formula is C7H12O3, Formula: C7H12O3.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Lei, Lyu published the artcileBio-modified rubberized asphalt binder: A clean, sustainable approach to recycle rubber into construction, Application of Methyl octanoate, the main research area is recycle rubber biomodified rubberized asphalt binder.

This paper introduces a hybrid utilization of scrap tires and bio-oil made from biomass waste to create bio-modified rubberized asphalt for use in roadway construction. This in turn promotes clean and sustainable manufacturing while enhancing resource conservation and durability of pavements. The durability of pavements is impacted by the resistance of their asphalt binder to moisture damage and aging. This study examines the moisture resistance of bio-modified rubberized asphalt when exposed to thermal aging and UV aging. Study results show that thermal aging significantly weakens the cohesive properties of rubberized asphalt binder, while UV aging reduces its adhesive properties when exposed to water. Bio-modification of rubberized asphalt binder was found to be effective to improve resistance to cohesive damage by three times based on the rheol. test, and resistance to adhesive damage by 70% as measured by the moisture-induced shear-thinning index. The observed improvement is attributed to the bio-oil’s role as a sacrificial agent, delaying the reaction of free radicals and asphalt. Also, computational modeling shows that bio-oil mols. supersede asphalt mols. in adsorption to stones aggregates creating a stable bridge between stone and asphalt. The outcome of this study promotes clean and sustainable manufacturing while turning two waste streams (rubber and biomass waste) into a product (bio-modified rubber) in support of resource conservation and sustainability.

Journal of Cleaner Production published new progress about Absorption. 111-11-5 belongs to class esters-buliding-blocks, name is Methyl octanoate, and the molecular formula is C9H18O2, Application of Methyl octanoate.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics