Category: 826-36-8

Zuo, Shiyu; Guan, Zeyu; Zhang, Yiming; Yang, Fan; Li, Xiaohu; Li, Dongya published their research in Chemical Engineering Journal (Amsterdam, Netherlands) on December 15 ,2022. The article was titled 《Bidentate binuclear coordination configuration for peroxymonosulfate catalytic regulation through incorporation of CuFeOx to iron-based metal organic frameworks》.Quality Control of Triacetonamine The article contains the following contents:

The scheme of coordination bridge modification provides a new vision for regulating the catalytic pathway, but how to change the surface coordination of peroxymonosulfate (PMS), thereby affecting the catalytic mechanism of PMS, is still an unknown field. In this, we found that MIL-101(Fe) is expected to control the surface catalytic pathway via the bidentate binuclear coordination configuration, thereby realizing the rapid oxidative detoxification of toxic organic pollutants and CO2 conversion. Introducing Cu on the surface of MIL-101(Fe) to change the surface chem. environment (MIL-101(Fe)/CuFeOx) can shift the catalytic pathway, thereby promoting a 14.5-fold improvement in Bisphenol A (BPA) oxidation kinetics (from 0.00697 min-1 to 0.101 min-1). Characterization, experiments, and d. functional theory (DFT) results show that Cu in the vicinity of Fe can tune the electronic structure and properties of Fe-O-Cu, thereby enhancing the electron transfer rate at the active center, facilitating electronic transitions and PMS adsorption. More importantly, shifting the binding configuration of PMS from monodentate mononuclear coordination on a single Fe center to bidentate binuclear coordination on Fe/Cu centers, shorter distance coordination structures and O-O pulling of PMS. The effect promoted PMS cleavage to generate more ROS and changed the catalytic pathway from the radical pathway to the 1O2 and high-valent metal species pathway. The free radical/non-radical pathway co-mediated by 1O2, high-valent metal species, ·OH and SO·-4 can effectively reduce the biotoxicity of toxic organic pollutants, and can utilize alkali environment captures CO2 as a stable carbonate for environmental use. This study provides a strategy for manipulating the catalytic pathway through coordination configuration and a feasible idea for CO2 conversion in wastewater treatment. The experimental part of the paper was very detailed, including the reaction process of Triacetonamine(cas: 826-36-8Quality Control of Triacetonamine)

Triacetonamine(cas: 826-36-8) is a member of piperidine. Piperidine-containing compounds are also frequently employed in synthesis as ligands or auxiliaries. Accordingly, many efforts have been devoted to the development of novel methods for the synthesis of these compounds over the years.Quality Control of Triacetonamine

Referemce:
Piperidine – Wikipedia,
Piperidine | C5H11N – PubChem

Ma, Wenjie; Wang, Na; Du, Yunchen; Tong, Tianze; Zhang, Leijiang; Andrew Lin, Kun-Yi; Han, Xijiang published an article on January 15 ,2019. The article was titled 《One-step synthesis of novel Fe3C@nitrogen-doped carbon nanotubes/graphene nanosheets for catalytic degradation of Bisphenol A in the presence of peroxymonosulfate》, and you may find the article in Chemical Engineering Journal (Amsterdam, Netherlands).Electric Literature of C9H17NO The information in the text is summarized as follows:

Developing novel carbocatalysts with available strategies for peroxymonosulfate (PMS) activation has become a popular topic in environmental remediation and protection fields. Herein, using com. K4Fe(CN)6 as the precursor, Fe3C@nitrogen-doped carbon nanotubes/graphene nanosheets (Fe3C@NCNTs/GNS) is synthesized by a direct high-temperature pyrolysis. Characterization results prove that Fe3C@NCNTs/GNS has a relatively high graphitization degree and rich nitrogen doping content, which endow it with excellent catalytic efficiency in PMS activation for powerful removal of Bisphenol A (BPA). Influences of catalyst/oxidant dosages, some inorganic anions, humic acid, and practical sewages are investigated in detail. For mechanism studies, it is found that tert-Bu alc. (TBA)/methanol fails to inhibit BPA degradation, and the primary reactive oxidative species (ROS) are superoxide radical (O·-2) and singlet oxygen (1O2). Discussion on the origin of 1O2 confirms that moderate modification of N atoms in graphitic carbon frameworks plays an essential role in inducing the non-radical mechanism. This work will provide new insights for the preparation of high-performance carbocatalysts in PMS activation and exploring critical roles of N-doping during non-radical processes. After reading the article, we found that the author used Triacetonamine(cas: 826-36-8Electric Literature of C9H17NO)

Triacetonamine(cas: 826-36-8) is a member of piperidine. Piperidine is ubiquitous structural motif widely occurred in diverse synthetically and naturally occurring bioactive molecules. Piperidines are an immensely important class of compounds medicinally: the piperidine ring is the most common heterocyclic subunit among FDA approved drugs.Electric Literature of C9H17NO

Referemce:
Piperidine – Wikipedia,
Piperidine | C5H11N – PubChem

Related Products of 826-36-8On October 1, 2021 ,《Highly-efficient and stable MgCo2O4 spinel for bisphenol a removal by activating peroxymonosulfate via radical and non-radical pathways》 was published in Chemical Engineering Journal (Amsterdam, Netherlands). The article was written by Yu, Jiaxin; Qiu, Wei; Xu, Haodan; Lu, Xiaohui; Ma, Jun; Lu, Dongwei. The article contains the following contents:

Nowadays, the limited catalytic efficiency, secondary pollution of metal leaching and stability decrease during reuse bring challenges to practical application of heterogeneous catalysts in sulfate radical-based advanced oxidation processes. Herein, MgCo2O4 spinel was synthesized through hydrothermal method and tested for its catalytic performance of activating PMS by using bisphenol A (BPA) as the target pollutant. MgCo2O4/PMS system can degrade 99.6% BPA efficiently at pH 7.2 within 10 min. The morphol. and physicochem. properties of MgCo2O4 were characterized by SEM (SEM), transmission electron microscopy (TEM), and X-ray diffraction (XRD). Unlike conventional PMS activation, radical and non-radical pathways were identified through utilizing XPS, ESR (EPR), and radical quenching experiments Tetrahedral Mg2+ might make MgCo2O4 more stable and promote the Co2+/Co3+ redox, which dominated the catalytic ability of MgCo2O4. MgCo2O4 spinel is efficient, stable, low-cost, and simple to synthesize, leading to BPA degradation via both radical and non-radical pathways. This research would extend the mechanism and potential application of spinel catalysis in water treatment. After reading the article, we found that the author used Triacetonamine(cas: 826-36-8Related Products of 826-36-8)

Triacetonamine(cas: 826-36-8) is a member of piperidine. Piperidine is ubiquitous structural motif widely occurred in diverse synthetically and naturally occurring bioactive molecules. Piperidines are an immensely important class of compounds medicinally: the piperidine ring is the most common heterocyclic subunit among FDA approved drugs.Related Products of 826-36-8

Referemce:
Piperidine – Wikipedia,
Piperidine | C5H11N – PubChem

Sun, Ping; Liu, Hui; Zhai, Zhicai; Zhang, Xuesheng; Fang, Yingsen; Tan, Jun; Wu, Jiaqiang published an article on January 15 ,2019. The article was titled 《Degradation of UV filter BP-1 with nitrogen-doped industrial graphene as a metal-free catalyst of peroxymonosulfate activation》, and you may find the article in Chemical Engineering Journal (Amsterdam, Netherlands).SDS of cas: 826-36-8 The information in the text is summarized as follows:

Instead of previously reported graphene oxide (GO), industrial graphene (reduced graphene oxide (IrGO)) was annealed with a nitrogen precursor. The obtained nitrogen-doped graphene (N-IrGO) was then employed as a novel catalyst for peroxymonosulfate (PMS) activation to degrade benzophenone-1 (BP-1) for the first time. The results show that N-IrGO exhibits excellent catalytic performance over conventional GO and its nitrogen-doped sample and was even better than the metal catalysts Co3O4 and Fe3O4. The enhanced catalytic performance might be attributed to graphitic-like nitrogen. Moreover, the effects of various factors were studied, including catalyst load, PMS concentration and reaction temperature Possible degradation pathways of BP-1 in the N-IrGO/PMS system were proposed based on detected intermediates and the frontier electron d. calculation Radical quenching experiments and ESR (EPR) tests indicated that nonradical oxidation (singlet oxygen (1O2)) plays a dominant role in the BP-1 degradation, in contrast to the previously proposed radical process. Finally, mineralization and stability experiments confirmed that N-IrGO may be an alternative catalyst for environmental remediation. This study contributes to designing novel graphene materials with N doping and gives new insight into nonradical oxidation on benzophenone-type UV filters degradation The results came from multiple reactions, including the reaction of Triacetonamine(cas: 826-36-8SDS of cas: 826-36-8)

Triacetonamine(cas: 826-36-8) is a member of piperidine. Piperidine-containing compounds are also frequently employed in synthesis as ligands or auxiliaries. Accordingly, many efforts have been devoted to the development of novel methods for the synthesis of these compounds over the years.SDS of cas: 826-36-8

Referemce:
Piperidine – Wikipedia,
Piperidine | C5H11N – PubChem

Reference of TriacetonamineOn March 1, 2022, Wei, Ying; Lu, Guanglu; Xie, Dongrun; Sun, Tianyi; Liu, Yu; Zhang, Ying; An, Jiutao; Li, Menghong; Guo, He published an article in Chemical Engineering Journal (Amsterdam, Netherlands). The article was 《Degradation of enrofloxacin in aqueous by DBD plasma and UV: Degradation performance, mechanism and toxicity assessment》. The article mentions the following:

Enrofloxacin (ENRO) as a highly toxic antibiotic poses great threats to human health and environmental safety. In this study, a novel technol. of coupling dielec. barrier discharge (DBD) and UV was investigated to efficiently degrade ENRO in aqueous, and had a higher degradation rate. The ENRO degradation rate achieved approx. 93.9% at 30 min, and approx. 1.20 g kWh-1 of energy yield (G50) was observed for the combined system. The addition of H2O2 and K2S2O4 improved the ENRO degradation due to the generation of ·OH and ·SO42-. In the presence of NO3-, the ENRO degradation played a tendency to promote first and then decrease, and the presence of SO42-resulted in the pos. effect, while the neg. effect was shown in the presence of Cl- and CO32-. The trapping experiment indicated that ·OH played an important part in the ENRO degradation The addition of UV into the DBD system decreased H2O2 concentration in deionized water, and increased ·OH concentration The DFT anal. showed the degradation mechanisms of ENRO at a mol. level. The degradation of ENRO mainly involved the oxidation of the piperazine group, the removal of Et acetate and the substitution of the F atom. The toxicity of ENRO and its degradation intermediates was evaluated. After reading the article, we found that the author used Triacetonamine(cas: 826-36-8Reference of Triacetonamine)

Triacetonamine(cas: 826-36-8) is a member of piperidine. Piperidine is a key saturated heterocyclic scaffold found in several of the top-selling small molecule pharmaceuticals and natural alkaloids, with a diverse range of biological activities. Hence, continuous efforts have been made to develop convenient methods to prepare piperidine derivatives.Reference of Triacetonamine

Referemce:
Piperidine – Wikipedia,
Piperidine | C5H11N – PubChem

Reference of TriacetonamineOn March 5, 2022, Wang, Gen; Ge, Lei; Liu, Zhuoyue; Zhu, Xiurong; Yang, Shengjiong; Wu, Kun; Jin, Pengkang; Zeng, Xiangkang; Zhang, Xiwang published an article in Chemical Engineering Journal (Amsterdam, Netherlands). The article was 《Activation of peroxydisulfate by defect-rich CuO nanoparticles supported on layered MgO for organic pollutants degradation: An electron transfer mechanism》. The article mentions the following:

Heterogeneous activation of peroxydisulfate (PDS) by transition metal oxides offers a promising strategy for organic pollutants removal but suffers from low electron transfer efficiency. Herein, layered MgO supported CuO nanoparticles was prepared by thermal conversion of metal-phenolic networks of Cu2+/Mg2+ and tannic acid. CuO nanoparticles (≈2 nm) were spatial monodispersed on layered MgO, inducing the formation of electron deficient Cu3+ and surface oxygen vacancies and thus facilitated adsorption and activation of PDS. The electron-rich CuO/MgO hybrid catalysts manifested good catalytic performance of PDS activation for organic pollutants removal. At 0.18 g/L of CuO/MgO hybrid catalyst and 0.2 mM of PDS, complete removal of bisphenol A (BPA) was achieved with a high kinetic constant (0.1 min-1, 50 min). Quenching experiments, ESR tests, PDS decomposition behaviors, electrochem. anal. and in situ ATR-FTIR and Raman spectroscopy revealed a nonradical pathway of electron transfer for PDS activation. The CuO/MgO hybrid catalysts exhibited wide working pH range from 3 to 11, selective oxidation capability, good resistance to halide ion and high utilization efficiency of PDS, and thus would be a promising candidate for wastewater remediation. The experimental part of the paper was very detailed, including the reaction process of Triacetonamine(cas: 826-36-8Reference of Triacetonamine)

Triacetonamine(cas: 826-36-8) is a member of piperidine. Piperidine is a key saturated heterocyclic scaffold found in several of the top-selling small molecule pharmaceuticals and natural alkaloids, with a diverse range of biological activities. Hence, continuous efforts have been made to develop convenient methods to prepare piperidine derivatives.Reference of Triacetonamine

Referemce:
Piperidine – Wikipedia,
Piperidine | C5H11N – PubChem

Sun, Qianqian; Liu, Bin; Wang, Zhao; Feng, Lili; Zhao, Ruoxi; Dong, Shuming; Dong, Yushan; Zhong, Lei; Gai, Shili; Yang, Piaoping published their research in Chemical Engineering Journal (Amsterdam, Netherlands) on December 1 ,2021. The article was titled 《H2O2/O2 self-supplementing and GSH-depleting Ca2+ nanogenerator with hyperthermia-triggered, TME-responsive capacities for combination cancer therapy》.Synthetic Route of C9H17NO The article contains the following contents:

The tumor microenvironment (TME) is complex in composition and unique in nature, and is closely related to the growth, invasion and metastasis of tumor cells. Improving and remodeling the TME to return it to a normalized state can fundamentally disrupt the environment and/or nutrient supply on which tumor cells depend. To achieve this goal, based on the unique physicochem. properties and biol. effects of CaO2, we designed and constructed a Ca2+ nanogenerator (named as CaO2-Cu/ICG@PCM) that enables H2O2/O2 self-supplementation and GSH depletion. The 808 nm laser induces the heat generation of photosensitizer indocyanine green (ICG) to initiate a series of reactions, followed by the production of copper ions, H2O2, O2 and large amounts of Ca2+, which can eventually lead to the combined treatment of photodynamic therapy (PDT), chemodynamic therapy (CDT) and calcium overload. Addnl., the reaction process is accompanied by the generation of Ca(OH)2, which greatly improves the acidic environment of TME and effectively promotes the oxidation process of GSH by H2O2, achieving the purpose of remodeling TME. It is worth mentioning that a large amount of free Ca2+ accumulating in tumor cells can rapidly initiate the process of calcium overload and calcification, which can not only play a role in tumor suppression, but also assist CT imaging to detect the effect of treatment. Thus, CaO2-Cu/ICG@PCM could be a promising candidate for bioimaging and tumor therapy. In the experimental materials used by the author, we found Triacetonamine(cas: 826-36-8Synthetic Route of C9H17NO)

Triacetonamine(cas: 826-36-8) is a member of piperidine. Piperidine is a key saturated heterocyclic scaffold found in several of the top-selling small molecule pharmaceuticals and natural alkaloids, with a diverse range of biological activities. Hence, continuous efforts have been made to develop convenient methods to prepare piperidine derivatives.Synthetic Route of C9H17NO

Referemce:
Piperidine – Wikipedia,
Piperidine | C5H11N – PubChem

Huang, Zhiyan; Wang, Tenglu; Shen, Minxian; Huang, Zhujian; Chong, Yunxiao; Cui, Lihua published their research in Chemical Engineering Journal (Amsterdam, Netherlands) on August 1 ,2019. The article was titled 《Coagulation treatment of swine wastewater by the method of in-situ forming layered double hydroxides and sludge recycling for preparation of biochar composite catalyst》.Category: piperidines The article contains the following contents:

In order to achieve enhanced treatment of swine wastewater as well as resource recycle, in this work, we applied coagulation treatment on swine wastewater by adding Fe and Mg ions, MgFe layered double hydroxides (LDHs) was yielded during coagulation process and the coagulation sludge was recycled to prepare biochar composite catalyst. The removal rates of total phosphorus (TP) and COD (COD) by Mg-Fe coagulation could achieve 82.55% and 98.51%, which is higher than that by coagulation with individual Mg2+ or individual Fe3+. Finely dispersed MgFe-LDHs flocculation was formed during the coagulation process and was embedded within zoogloea, suspended particles, organic matters, etc. The obtained coagulation sludge was recycled to prepare biochar composite catalyst by oxygen-limited pyrolysis. Redox reaction of iron compounds and electron shuttles capacity of biochar in the catalyst could activate potassium peroxymonosulfate (PMS) to generate ·OH, ·OOH and 1O2, which was responsible for catalysis potential. The as-prepared biochar composite catalyst showed satisfactory catalytic degradation capacity on tylosin and rhodamine B (pH value varied from 3 to 10), and the maximum degradation rate achieved 92.2% for tylosin and 81.9% for rhodamine B (RhB). Coagulation treatment of swine wastewater and in-situ formed layered double hydroxides recycling was suitable in wastewater treatment and resource recycling, of which the degradation rates of RhB were above 83% after five cycling experiments In general, the combined process exhibits great potential for the deep treatment of swine wastewater and resource recycling for sludge. In the part of experimental materials, we found many familiar compounds, such as Triacetonamine(cas: 826-36-8Category: piperidines)

Triacetonamine(cas: 826-36-8) is a member of piperidine. Piperidine is a key saturated heterocyclic scaffold found in several of the top-selling small molecule pharmaceuticals and natural alkaloids, with a diverse range of biological activities. Hence, continuous efforts have been made to develop convenient methods to prepare piperidine derivatives.Category: piperidines

Referemce:
Piperidine – Wikipedia,
Piperidine | C5H11N – PubChem

Recommanded Product: TriacetonamineOn September 1, 2020 ,《Defect-rich carbon based bimetallic oxides with abundant oxygen vacancies as highly active catalysts for enhanced 4-aminobenzoic acid ethyl ester (ABEE) degradation toward peroxymonosulfate activation》 was published in Chemical Engineering Journal (Amsterdam, Netherlands). The article was written by Huang, Zhiyan; Wu, Pingxiao; Liu, Juan; Yang, Shanshan; Chen, Meiqing; Li, Yihao; Niu, Wenchao; Ye, Quanyun. The article contains the following contents:

meeting severe environmental problems, highly efficient, environment-friendly, multiple reusable catalysts are demanding to develop. this work prepared C-based bimetallic oxides with O vacancies for peroxymonosulfate activation to degrade 4-aminobenzoic acid Et ester (ABEE). among different molar ratios of Fe2+ and Mn ions, Fe1Mn1-Fe NC had the optimum catalytic performance. ABEE degradation should have free radical and non-free radical pathways. all sulfate, hydroxyl, and superoxide radicals and singlet oxygen were responsible for efficient ABEE degradation and mineralization. lattice O was the main reactive site for ABEE degradation electron transport provided a good synergistic redox reaction between Fe and Mn and promoted lattice O release. a proposed pathway for ABEE degradation included electrophilic and radical addition, H-abstraction reaction, and diazotization. this work was expected to provide rational design of bimetallic materials with oxygen vacancies for in-situ environmental remediation. In the part of experimental materials, we found many familiar compounds, such as Triacetonamine(cas: 826-36-8Recommanded Product: Triacetonamine)

Triacetonamine(cas: 826-36-8) is a member of piperidine. Piperidine is ubiquitous structural motif widely occurred in diverse synthetically and naturally occurring bioactive molecules. Piperidines are an immensely important class of compounds medicinally: the piperidine ring is the most common heterocyclic subunit among FDA approved drugs.Recommanded Product: Triacetonamine

Referemce:
Piperidine – Wikipedia,
Piperidine | C5H11N – PubChem

Recommanded Product: TriacetonamineOn September 15, 2020 ,《Activation of persulfate for tetracycline degradation using the catalyst regenerated from Fenton sludge containing heavy metal: Synergistic effect of Cu for catalysis》 was published in Chemical Engineering Journal (Amsterdam, Netherlands). The article was written by Shen, Minxian; Huang, Zhujian; Luo, Xuewen; Ma, Yujia; Chen, Chengyu; Chen, Xian; Cui, Lihua. The article contains the following contents:

Fenton reaction is widely used as a unique oxidation method for industrial wastewater treatment; however, it generates a massive amount of Fe sludge, which mostly contains other hazardous heavy metal wastes which can harm the environment and humans. This work proposed a sustainable method to eliminate side effects of the Fenton reaction and to transform Cu-containing Fenton sludge into an efficient catalyst for peroxymonosulfate (PMS) activation for tetracycline (TC) degradation The existence of Cu, which can increase sludge O2 vacancies, was attributed to the activation efficiency compared to Fe sludge with no Cu. X-ray diffraction and XPS results showed Fe is present as α-Fe2O3 and γ-Fe2O3; Cu mostly exists as Cu2+. Catalyst and PMS doses, pH, and recycling time effect on PMS reaction was illustrated. OH-, SO4- O2-, and 1O2 were the critical reactive oxygen species. TC decomposes into CO2 and water through six possible pathway processes with these free radicals. Given its sustainable treatment and high catalytic efficiency, dealing with Fe sludge which contains heavy metals serves as a modal practice for harmful wastewater treatment and can be popularized for broader applications. The experimental process involved the reaction of Triacetonamine(cas: 826-36-8Recommanded Product: Triacetonamine)

Triacetonamine(cas: 826-36-8) is a member of piperidine. Piperidine is ubiquitous structural motif widely occurred in diverse synthetically and naturally occurring bioactive molecules. Piperidines are an immensely important class of compounds medicinally: the piperidine ring is the most common heterocyclic subunit among FDA approved drugs.Recommanded Product: Triacetonamine

Referemce:
Piperidine – Wikipedia,
Piperidine | C5H11N – PubChem