Tag: 0-100

Molecular and nanostructure designed superhydrophilic material with unprecedented antioil-fouling property for diverse oil/water separation was written by Wang, ZheCun;Guan, Min;Yang, Xin;Li, HanZhen;Wang, LaiGui. And the article was included in Science China: Technological Sciences in 2022.Name: Cuprichydroxide This article mentions the following:

The design and development of new advanced superwetting porous membranes with antioil-fouling performance are still rare and highly desirable because of their potential widespread applications. A metallic phosphate nanoflower-covered mesh membrane with superhydrophilic and unprecedented antioil-fouling properties is prepared by an exceptionally simple and effective in-situ solution corrosion method. As demonstrated, the outstanding antioil-fouling property of the resulting mesh membrane is connected with the special phosphate group and the three-dimensional (3D) nanoflower structure. Owing to the antioil-fouling property, upon to water, the oil-fouled mesh membrane can keep the surface free of various kinds of oils, including viscous crude oil to light n-hexane. Thanks to its unprecedented self-cleaning property, the superhydrophilic mesh membrane can effectively sep. different oil/water mixtures without prior wetted by water, exhibiting great potential for practical spilled oil remediation. In the experiment, the researchers used many compounds, for example, Cuprichydroxide (cas: 20427-59-2Name: Cuprichydroxide).

Cuprichydroxide (cas: 20427-59-2) belongs to copper catalysts. Copper catalyst has received great attention owing to the low toxicity and low cost. Copper nanoparticles can catalyze the Ullmann coupling reaction in a wide range of applications.Name: Cuprichydroxide

Referemce:
Copper catalysis in organic synthesis – NCBI,
Special Issue “Fundamentals and Applications of Copper-Based Catalysts”

Sulfurization-derived Cu⁰-Cu⁺ sites for electrochemical CO₂ reduction to ethanol was written by Dou, Tong;Du, Jiawei;He, Jinqing;Wang, Yiping;Zhao, Xuhui;Zhang, Fazhi;Lei, Xiaodong. And the article was included in Journal of Power Sources in 2022.Quality Control of Cuprichydroxide This article mentions the following:

The transformation of CO₂ into value-added products is a hot research topic. Metal copper as an electrochem. catalyst shows activity for generating multi-carbon products in CO₂ electroreduction Herein, Cu₂S nanorods/copper mesh (Cu₂S/CM) is successfully fabricated, and exhibits high performance of CO₂ electroreduction to ethanol. At -0.8 V vs RHE, it achieved the Faraday efficiency (FE) of 13.5%, the partial c.d. of 13.3 mA cm^-2 and the yield of 986.4μmol L^-1 h^-1 for ethanol. Experiments and theor. calculations indicated that the high performance is benefits from the high d. of Cu0 and Cu + pairs derived from Cu₂S/CM during CO₂ electroreduction and an appropriate surface Cu0/Cu + ratio of 0.17. The Cu0-Cu+ sites facilitate the adsorption of key intermediate *CH₂CHO and decrease the energy barrier of the ethanol pathway. This work provides not only a new comprehension of CO₂ electroreduction with Cu2S catalyst but also a design idea based on Cu0-Cu+ sites in Cu/Cu₂S catalyst. In the experiment, the researchers used many compounds, for example, Cuprichydroxide (cas: 20427-59-2Quality Control of Cuprichydroxide).

Cuprichydroxide (cas: 20427-59-2) belongs to copper catalysts. Copper has continued to be one of the most utilized and important transition metal catalysts in synthetic organic chemistry. The copper-mediated C-C, C-O, C-N, and C-S bond formation is a part of one oldest reaction, emphasizing the Ullmann cross-coupling reaction.Quality Control of Cuprichydroxide

Referemce:
Copper catalysis in organic synthesis – NCBI,
Special Issue “Fundamentals and Applications of Copper-Based Catalysts”

Underoil superhydrophilic CuC₂O₄@Cu-MOFs core-shell nanosheets-coated copper mesh membrane for on-demand emulsion separation and simultaneous removal of soluble dye was written by He, Huaqiang;Liu, Yajie;Zhu, Yingming;Zhang, Tian C.;Yuan, Shaojun. And the article was included in Separation and Purification Technology in 2022.Formula: CuH2O2 This article mentions the following:

Underoil superhydrophilic surface is of great significance for the separation of water-in-oil emulsions, but its preparation is still a great challenge due to limited wetting thermodn. Herein, a well-designed hierarchical CuC₂O₄@Cu-MOFs (HKUST-1) core-shell nanosheets-coated copper mesh membrane was fabricated by facile immersion processes for on demand separation of oil-in-water and water-in-oil emulsions as well as highly efficient removal of soluble dyes. The as-fabricated hierarchical CuC₂O₄@HKUST-1 core-shell nanostructure endowed the mesh membrane with underwater superoleophobicity, underoil superhydrophilicity and excellent underwater oil anti-adhesion capability. Such superwetting MOFs-coated membrane delivered an outstanding separation performance for oil-in-water emulsion with high water flux of up to 1800 L m^-2 h^-1and the COD (COD) value of lower than 110 mg L^-1 by selective water filtration, while it efficiently separated water-in-oil emulsion by adsorption with a water content of lower than 120 ppm. Furthermore, the as-prepared mesh membrane also exhibited high removal efficiency of soluble dyes at circa 94% within 165 min by the adsorption-photocatalytic coupled process. The postulated photocatalytic mechanism of CuC₂O₄@HKUST-1 composite was ascribed to the photogenerated superoxide (·O^–₂) and hydroxyl radicals (·OH). With the desirable separation performance to complex oil-in-water emulsion containing both emulsified oil droplets and soluble dyes, the as-synthesized mesh membrane enriches the preparation path of underoil superhydrophilic surface, and expands the application of MOFs-based membrane for complex oily wastewater treatment. In the experiment, the researchers used many compounds, for example, Cuprichydroxide (cas: 20427-59-2Formula: CuH2O2).

Cuprichydroxide (cas: 20427-59-2) belongs to copper catalysts. The applications of Copper-based nanoparticles have received great attention due to the earth-abundant, low toxicity and inexpensive. Copper nanoparticles can catalyze the Ullmann coupling reaction in a wide range of applications.Formula: CuH2O2

Referemce:
Copper catalysis in organic synthesis – NCBI,
Special Issue “Fundamentals and Applications of Copper-Based Catalysts”

Facile Synthesis of Energetic Nanoparticles of Copper Azide with High Initiation Ability for Micro-Initiator Applications Using Layered Copper Hydroxide was written by Yan, Zhenzhan;Yang, Li;Tong, Wenchao;Han, Ji-Min. And the article was included in Inorganic Chemistry in 2022.Application of 20427-59-2 This article mentions the following:

Copper azide (CA) is one of the preferred primary explosives in the micro-initiating device, and it is of conducive significance to develop high-content CA-modified materials. In this work, two types of CA composites are reported with CA nanorods embedded in carbon nanosheets (CA/C) and CA distributed on salicylic acid (CA/SA) using layered copper hydroxide nanosheets intercalated with salicylic acid as the precursor. The detailed characterizations demonstrated that CA/C exhibits eximious electrostatic sensitivity (1.06 mJ) due to the inherent structural characteristics of CA/C such as the limitation of the free movement of CA by the layered structure and preeminent elec. conductivity of carbon nanosheets. Surprisingly, CA/C with nearly 1.0 mg in the miro-initiating device can reliably detonate Hexanitrohexaazaisowurtzitane (CL-20). CA/C exhibits extremely high CA content (93%), excellent ignition ability, and detonation ability, and its performance is superior to pure CA and most CA-modified materials reported previously. CA/SA also has an excellent detonation ability and its electrostatic sensitivity is as low as 0.92 mJ. These findings provide a new perspective for the development of high-performance primary explosives for the micro-initiating device. In the experiment, the researchers used many compounds, for example, Cuprichydroxide (cas: 20427-59-2Application of 20427-59-2).

Cuprichydroxide (cas: 20427-59-2) belongs to copper catalysts. The applications of Copper-based nanoparticles have received great attention due to low toxicity and inexpensive, earth-abundant. The copper-mediated C-C, C-O, C-N, and C-S bond formation is a part of one oldest reaction, emphasizing the Ullmann cross-coupling reaction.Application of 20427-59-2

Referemce:
Copper catalysis in organic synthesis – NCBI,
Special Issue “Fundamentals and Applications of Copper-Based Catalysts”

Superhydrophobic copper foam modified with hierarchical stearic acid/CuSiO₃/Cu(OH)₂ nanocomposites for efficient water/oil separation was written by Li, Ji;Wang, Yuan;Gao, Ruixi;Zhang, Tian C.;Yuan, Shaojun. And the article was included in Journal of Environmental Chemical Engineering in 2022.Related Products of 20427-59-2 This article mentions the following:

Developing efficient, durable and affordable oil-water separation technologies is critical to address the challenges of oily wastewater treatment. In this work, a microsphere-like CuSiO₃ embedded Cu(OH)2 nanowires array was prepared on copper foam (CF) support (defined as CF/Cu(OH)₂/CuSiO₃) by using a simple chem. etching and hydrothermal method. After modifying with stearic acid (SA), such a novel CF/Cu(OH)₂/CuSiO₃-SA membrane presented excellent superhydrophobicity with a static water contact angle of 155.6°. The ammonia concentration in the precursor solution and the hydrothermal reaction time were critical for the morphol. and the associated hydrophobicity of the CF/Cu(OH)₂/CuSiO₃-SA membrane. The as-prepared superhydrophobic CF had efficient anti-corrosion and mech. properties and demonstrated an excellent separation capability of oil-water mixtures with a separation efficiency of 98.4%. It also exhibited a good separation efficiency of 98.3% for various water-in-oil emulsions, and delivered an outstanding separation efficiency of 98.2% towards oil/water mixture after operating successive 30 cycles of oil-water separation With the inherent advantages of high separation efficiency of oil/water emulsion, good physicochem. stability and durability, and high mech. and corrosion resistance, the novel CF/Cu(OH)₂/CuSiO₃-SA membrane is potentially useful in practical applications for oily wastewater treatment. In the experiment, the researchers used many compounds, for example, Cuprichydroxide (cas: 20427-59-2Related Products of 20427-59-2).

Cuprichydroxide (cas: 20427-59-2) belongs to copper catalysts. The transition metal-catalyzed chemical transformation of organic electrophiles and organometallic reagents has turned up as an exceedingly robust synthetic tool. It is clear from the impact copper catalysis has had on organic synthesis that copper should be considered a first line catalyst for many organic reactions.Related Products of 20427-59-2

Referemce:
Copper catalysis in organic synthesis – NCBI,
Special Issue “Fundamentals and Applications of Copper-Based Catalysts”

Micron flower-like CuO light trapping grown on the copper foam skeleton combined with PVDF membrane for solar-driven vacuum membrane distillation was written by Yu, Jingtong;Yue, Dongmin;Sun, De;Li, Bingbing;Ge, Yanxia;Lin, Yuanhang. And the article was included in Separation and Purification Technology in 2022.COA of Formula: CuH2O2 This article mentions the following:

Solar-driven photothermal conversion vacuum membrane distillation (SVMD) becomes an energy-efficient water treatment thanks to the thermal localization of photothermal membranes. Membrane photothermal activity and distillation performance are essential for creating photothermal composite membranes. Herein, a CuO/CF-PVDF photothermal composite membrane has been designed with flower-like copper oxide (CuO/CF) photothermal active-layer and polyvinylidene fluoride (PVDF) microporous hydrophobic separation layer. Firstly, the flower-like CuO/CF layer with the light trapping was obtained by in-situ surface oxidation on the copper foam (CF) surface. Then, by the NIPS method, PVDF microporous hydrophobic layer was scraped on one side of the CuO/CF photothermal active-layer and firmly fixed on the porous surface of CuO/CF layer by anchoring effect. The light trap consisted of CuO micron flowers and Cu(OH)₂ nanowires. The gaps among the petals increased the light refractive rate and absorption area, thus enhancing the photothermal performance of the CuO/CF. Under 1 kWm^-2 solar irradiation, the absorption rate reached up to 95%, and the photothermal conversion efficiency achieved 94%. For the SVMD process, compared to current research, the CuO/CF-PVDF achieved the permeate flux of 3.34 kgm^-2h_-1 and energy efficiency of 88% under average feed temperature Overall, the CuO/CF-PVDF membrane has promising potential for desalination by fully using sustainable energy. In the experiment, the researchers used many compounds, for example, Cuprichydroxide (cas: 20427-59-2COA of Formula: CuH2O2).

Cuprichydroxide (cas: 20427-59-2) belongs to copper catalysts. Copper has continued to be one of the most utilized and important transition metal catalysts in synthetic organic chemistry. It is clear from the impact copper catalysis has had on organic synthesis that copper should be considered a first line catalyst for many organic reactions.COA of Formula: CuH2O2

Referemce:
Copper catalysis in organic synthesis – NCBI,
Special Issue “Fundamentals and Applications of Copper-Based Catalysts”

Electrochemical energy storage application of CuO/CuO@Ni-CoMoO₄·0.75H₂O nanobelt arrays grown directly on Cu foam was written by Zhang, Bingbing;Liu, Qian;Xu, Kaibing;Zou, Rujia;Wang, Chunrui. And the article was included in Progress in Natural Science: Materials International in 2022.Related Products of 20427-59-2 This article mentions the following:

Supercapacitors are attracting huge research interest because they are expected to achieve battery-level energy d., and they have a longer calendar life and shorter charging time. However, due to the out shell materials without contact extra freeway for charge transports, the out shell materials have still limited contribution to high capacitance for array structure at high rates. Here, CO/CO@Ni-CMO NBs were designed and synthesized on Cu foam substrates with CuO NBs as cores or extra freeway and Ni-CoMoO_4·0.75H₂O nanobelt as shell by an easily synthetic method. CuO NBs will provide electron “superhighways” and extra outside freeway for charge storage and delivery. Besides, the Ni doped CoMoO_4·0.75H₂O NBs are conducive to the elec. conductivity, and open space among these nanosheets can act as an “ion reservoir”, the increment of active sites and the contribution of capacitive effects. Finally, the CO@Ni-CMO NBs directly grown on Cu foam could avoid the “dead” volume caused by the tedious process of mixing active materials with polymer binders/conductive additives. As expected, the CO/CO@Ni-CMO NBs exhibited the high specific capacitance, the good rate performance and the excellent electrochem. stability. In the experiment, the researchers used many compounds, for example, Cuprichydroxide (cas: 20427-59-2Related Products of 20427-59-2).

Cuprichydroxide (cas: 20427-59-2) belongs to copper catalysts. The applications of Copper-based nanoparticles have received great attention due to low toxicity and inexpensive, earth-abundant. Copper nanoparticles can also catalyze the coupling reaction of phenols, thiols, xanthogenates, nitrogen-containing nucleophiles, selenium ruthenium nucleophiles and the like.Related Products of 20427-59-2

Referemce:
Copper catalysis in organic synthesis – NCBI,
Special Issue “Fundamentals and Applications of Copper-Based Catalysts”

Testing the durability of copper based preservative treated bamboos in ground-contact for six years was written by Tomak, Eylem D.;Topaloglu, Elif;Ermeydan, Mahmut A.;Pesman, Emrah. And the article was included in Cellulose (Dordrecht, Netherlands) in 2022.COA of Formula: CuH2O2 This article mentions the following:

In this study, durability of bamboo samples in terms of the variability of location along culm height (top, middle and bottom) were evaluated in a ground-contact field test for six years in comparison to Scots pine and beech wood samples. Bamboo and wood samples were treated with Wolmanit-CB (CCB) and Tanalith-E (Tan-E) solutions, and installed in a field located in the North-West of Turkey. The decay resistance of samples was assessed by weight loss, and compared by SEM observations and FTIR anal. Results showed that un-treated bamboo and wood samples had a low durability such that weight losses were found as 64-80% for bamboo and 57-63% for wood samples. SEM micrographs showed the characteristics decay patterns of soft-rot type I and brown-rot fungi in the parenchyma cells, vessels and fibers in vascular bundles. FTIR anal. revealed the mechanism of the biodegradation, which indicates the reduction of carbohydrate content. The weight loss in CCB and Tan-E treated bamboo samples was reduced as 20-45% depending on bamboo height parts, but wood preservatives did not ensure sufficient resistance for six years against soil degrading organisms since more than half of the chem. amount leached out from the bamboos to soil. It was observed that the lower parts of culm were more durable, which was also in accordance with ICP-OES and SEM anal. Copper-based preservatives seemed to be more efficient in pine and beech wood samples than bamboos since the impregnability of bamboo was much lower than that of wood. In the experiment, the researchers used many compounds, for example, Cuprichydroxide (cas: 20427-59-2COA of Formula: CuH2O2).

Cuprichydroxide (cas: 20427-59-2) belongs to copper catalysts. Copper has continued to be one of the most utilized and important transition metal catalysts in synthetic organic chemistry. Copper nanoparticles can also catalyze the coupling reaction of phenols, thiols, xanthogenates, nitrogen-containing nucleophiles, selenium ruthenium nucleophiles and the like.COA of Formula: CuH2O2

Referemce:
Copper catalysis in organic synthesis – NCBI,
Special Issue “Fundamentals and Applications of Copper-Based Catalysts”

Screening Surface Structure-Electrochemical Activity Relationships of Copper Electrodes under CO₂ Electroreduction Conditions was written by Wahab, Oluwasegun J.;Kang, Minkyung;Daviddi, Enrico;Walker, Marc;Unwin, Patrick R.. And the article was included in ACS Catalysis in 2022.Name: Cuprichydroxide This article mentions the following:

Understanding how crystallog. orientation influences the electrocatalytic performance of metal catalysts can potentially advance the design of catalysts with improved efficiency. Although single crystal electrodes are typically used for such studies, the 1-at-a-time preparation procedure limits the range of secondary crystallog. orientations that can be profiled. This work employs scanning electrochem. cell microscopy (SECCM) together with co-located electron backscatter diffraction (EBSD) as a screening technique to study how surface crystallog. orientations on polycrystalline Cu correlate to activity under CO₂ electroreduction conditions. SECCM measures spatially resolved voltammetry on polycrystalline Cu covering low overpotentials of CO₂ conversion to intermediates, thereby screening the different activity from low-index facets where H₂ evolution is dominant to high-index facets where more reaction intermediates are expected. This approach allows the acquisition of 2500 voltammograms on ∼60 different Cu surface facets identified with EBSD. The order of activity is (111) < (100) < (110) among the Cu primary orientations. The collection of data over a wide range of secondary orientations leads to the construction of an electrochem.-crystallog. stereog. triangle that provides a broad comprehension of the trends among Cu secondary surface facets rarely studied in the literature, [particularly (941) and (741)], and clearly shows that the electroreduction activity scales with the step and kink d. of these surfaces. This work also reveals that the electrochem. stripping of the passive layer that is naturally formed on Cu in air is strongly grain-dependent, and the relative ease of stripping on low-index facets follows the order of (100) > (111) > (110). This allows a procedure to be implemented, whereby the oxide is removed (to an electrochem. undetectable level) prior to the kinetic analyses of electroreduction activity. SECCM screening allows for the most active surfaces to be ranked and prompts in-depth follow-up studies. In the experiment, the researchers used many compounds, for example, Cuprichydroxide (cas: 20427-59-2Name: Cuprichydroxide).

Cuprichydroxide (cas: 20427-59-2) belongs to copper catalysts. Transition metal-catalyzed chemical transformation of organic electrophiles and organometallic reagents belong to the most important cross-coupling reaction in organic synthesis. These ligands enable the reaction promoted in mild condition. The reaction scope has also been greatly expanded, rendering this copper-based cross-coupling attractive for both academia and industry. Name: Cuprichydroxide

Referemce:
Copper catalysis in organic synthesis – NCBI,
Special Issue “Fundamentals and Applications of Copper-Based Catalysts”

Roles of supports on reducibility and activities of Cu₃P catalysts for deoxygenation of oleic acid: In situ XRD and XAS studies was written by Kochaputi, Nopparuj;Khemthong, Pongtanawat;Kasamechonchung, Panita;Butburee, Teera;Limphirat, Wanwisa;Poo-arporn, Yingyot;Kuboon, Sanchai;Faungnawakij, Kajornsak;Kongmark, Chanapa. And the article was included in Molecular Catalysis in 2022.SDS of cas: 20427-59-2 This article mentions the following:

This work demonstrates for the first time that silicon dioxide (SiO₂) and ultra-stable zeolite Y (USY) supports play significant roles in the reducibility of cupric pyrophosphate (Cu₂P₂O₇) to form copper phosphide (Cu₃P), which consequently affects the selectivity of oleic acid deoxygenation. The formation of supported Cu₃P nanoparticles during hydrogen reduction of Cu₂P₂O₇ was carefully investigated by in situ X-ray diffraction (in situ XRD), and in situ X-ray absorption spectroscopy (in situ XAS). The results indicate that the transformation of Cu₂P₂O₇ to Cu₃P occurs through several steps. In the first step, all supported Cu₂P₂O₇ precursors are reduced to metallic copper. Then, copper particles on SiO₂ support react with phosphorus compounds and directly transform to Cu₃P. On the other hand, copper particles on USY support partially transform to copper diphosphide (CuP₂) and copper hydroxide (Cu(OH)₂) before all converting to Cu₃P. Despite multi-step transformations, Cu₂P₂O₇/USY exhibits the lowest onset reduction temperature and provides Cu₃P with small particle size. The deoxygenation of oleic acid over Cu₃P supported catalysts reaches nearly 100% conversion, both catalysts favor cyclization and aromatization to form cyclic and aromatic compounds The Cu₃P/SiO₂ achieves a higher dodecylbenzene yield (46%) than Cu₃P/USY (33%). A proposed mechanism consists of hydrogenation of oleic acid and deoxygenation, then followed by cracking, cyclization, aromatization, and alkyl rearrangement. In the experiment, the researchers used many compounds, for example, Cuprichydroxide (cas: 20427-59-2SDS of cas: 20427-59-2).

Cuprichydroxide (cas: 20427-59-2) belongs to copper catalysts. The applications of Copper-based nanoparticles have received great attention due to the earth-abundant, low toxicity and inexpensive. Due to these characteristics, copper nanoparticles have generated a great deal of interest especially in the field of catalysis. SDS of cas: 20427-59-2

Referemce:
Copper catalysis in organic synthesis – NCBI,
Special Issue “Fundamentals and Applications of Copper-Based Catalysts”