Category: alcohols-buliding-blocks

HPLC of Formula: C8H10O2. Authors Alam, MN; Dash, SR; Mukherjee, A; Pandole, S; Marelli, UK; Vanka, K; Maity, P in AMER CHEMICAL SOC published article about in [Alam, Md Nirshad; Mukherjee, Anirban; Pandole, Satish; Marelli, Udaya Kiran; Maity, Pradip] CSIR Natl Chem Lab, Organ Chem Div, Pune 411008, Maharashtra, India; [Alam, Md Nirshad; Dash, Soumya Ranjan; Marelli, Udaya Kiran; Vanka, Kumar] Acad Sci & Innovat Res AcSIR, Ghaziabad 201002, India; [Dash, Soumya Ranjan; Vanka, Kumar] CSIR Natl Chem Lab, Phys & Mat Chem Div, Pune 411008, Maharashtra, India in 2021, Cited 55. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5

A thermal O-to-C [1,3]-rearrangement of alpha-hydroxy acid derived enol ethers was achieved under mild conditions. The 2-aminothiophenol protection of carboxylic acids facilitates formation of the [1,3] precursor and its thermal rearrangement via stabilization of a radical intermediate. Experimental and theoretical evidence for dissociative radical pair formation, its captodative stability via aminothiophenol, and a unique solvent effect are presented. The aminothiophenol was deprotected from rearrangement products as well as after derivatization to useful synthons.

HPLC of Formula: C8H10O2. About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Alam, MN; Dash, SR; Mukherjee, A; Pandole, S; Marelli, UK; Vanka, K; Maity, P or concate me.

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Padmanaban, S; Gunasekar, GH; Yoon, S in [Padmanaban, Sudakar; Yoon, Sungho] Chung Ang Univ, Dept Chem, Seoul 06974, South Korea; [Padmanaban, Sudakar] Seoul Natl Univ, Dept Chem, Seoul 08826, South Korea; [Gunasekar, Gunniya Hariyanandam] Korea Inst Sci & Technol, Clean Energy Res Ctr, Seoul 136791, South Korea published Direct Heterogenization of the Ru-Macho Catalyst for the Chemoselective Hydrogenation of alpha,beta-Unsaturated Carbonyl Compounds in 2021, Cited 95. COA of Formula: C8H10O2. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5.

In this study, a commercially available homogeneous pincer-type complex, Ru-Macho, was directly heterogenized via the Lewis acid-catalyzed Friedel-Crafts reaction using dichloromethane as the cross-linker to obtain a heterogeneous, pincer-type Ru porous organometallic polymer (Ru-Macho-POMP) with a high surface area. Notably, Ru-Macho-POMP was demonstrated to be an efficient heterogeneous catalyst for the chemoselective hydrogenation of alpha,beta-unsaturated carbonyl compounds to their corresponding allylic alcohols using cinnamaldehyde as a model compound. The Ru-Macho-POMP catalyst showed a high turnover frequency (TOF = 920 h(-1)) and a high turnover number (TON = 2750), with high chemoselectivity (99%) and recyclability during the selective hydrogenation of alpha, beta-unsaturated carbonyl compounds.

COA of Formula: C8H10O2. About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Padmanaban, S; Gunasekar, GH; Yoon, S or concate me.

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An article Role of dietary carbohydrates on risk of lung cancer WOS:000644431300012 published article about GROWTH-FACTOR-I; GLYCEMIC LOAD; SCREENING TRIAL; MEAT MUTAGENS; HEME IRON; PROSTATE; INDEX; INSULIN; VALUES; FIBER in [Tao, Jun; Lam, Wendy W. T.; Pang, Herbert] Univ Hong Kong, Li Ka Shing Fac Med, Sch Publ Hlth, Hong Kong, Peoples R China; [Jatoi, Aminah] Mayo Clin, Dept Oncol, Rochester, MN USA; [Crawford, Jeffrey] Duke Univ, Med Ctr, Duke Canc Inst, Durham, NC USA; [Ho, James C.] Univ Hong Kong, Li Ka Shing Fac Med, Dept Med, Hong Kong, Peoples R China; [Wang, Xiaofei; Pang, Herbert] Duke Univ, Sch Med, Dept Biostat & Bioinformat, Durham, NC USA; [Lam, Wendy W. T.] Univ Hong Kong, Jockey Club Inst Canc Care, Hong Kong, Peoples R China in 2021, Cited 53. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5. Recommanded Product: 105-13-5

Objectives: Inconsistent findings have been reported on the link between dietary carbohydrates and lung cancer. This study aims to comprehensively evaluate the role of dietary carbohydrates on lung cancer risk. Materials and methods: The prospective study is based on the PLCO trial, which recruited 113,096 eligible participants across the United States. Participants had to have completed baseline and diet history questionnaires. The incidence of lung cancer was acquired through self-report and medical record follow-up. A multivariable logistic model adjusted for confounders was used to estimate odds ratios (ORs) and 95 % confidence intervals (CIs) of dietary carbohydrates, fiber, whole grains, glycemic index (GI) and glycemic load (GL) for lung cancer. Similar methods were applied in analyzing the carbohydrates and fiber from different food sources. Multinomial logistic models were used for sensitivity analysis with lung cancer subtypes as outcomes. Results: Dietary carbohydrates and GL were inversely associated with lung cancer incidence in the PLCO population. Among various carbohydrates, 30-g daily consumption of dietary fiber was related to a lower risk of lung cancer (fourth vs first quartile OR: 0.62, 95 % CI: 0.54-0.72) compared with 8.8-g. Furthermore, consuming whole grains 2.3 servings per day as opposed to 0.3 servings per day was associated with a lower risk of lung cancer (OR: 0.73, 95 % CI: 0.64-0.83). A higher risk of lung cancer was seen for the consumption of high-GI food (OR: 1.19, 95 % CI: 1.05?1.35) and refined carbohydrates from soft drinks (OR: 1.23, 95 % CI: 1.04?1.46). Conclusion: Carbohydrates and fiber from fruits, vegetables and whole grains are associated with lower lung cancer risk. Refined carbohydrates from processed food, such as soft drinks, appear to increase risk.

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Product Details of 105-13-5. In 2021 ORG BIOMOL CHEM published article about N,N-DIMETHYLFORMAMIDE-STABILIZED PALLADIUM NANOCLUSTERS; ALPHA-ALKYLATION; BORROWING HYDROGEN; GUERBET REACTION; N-BUTANOL; METHYLATION; KETONES; METHANOL; DIMETHYLFORMAMIDE; ALPHA,OMEGA-DIOLS in [Kobayashi, Masaki; Yamaguchi, Hiroki; Obora, Yasushi] Kansai Univ, Fac Chem Mat & Bioengn, Dept Chem & Mat Engn, Suita, Osaka 5648680, Japan; [Suzuki, Takeyuki] Osaka Univ, Comprehens Anal Ctr, Inst Sci & Ind Res ISIR, 8-1 Mihogaoka, Ibaraki, Osaka 5670057, Japan in 2021, Cited 64. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5.

A simple method for the cross beta-alkylation of linear alcohols with benzyl alcohols in the presence of DMF-stabilized iridium nanoparticles was developed. The nanoparticles were prepared in one-step and thoroughly characterized. Furthermore, the optimum reaction conditions have a wide substrate scope and excellent product selectivity.

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In 2021 CATAL SCI TECHNOL published article about EXPOSED 001 FACETS; SOOT OXIDATION ACTIVITY; VISIBLE PHOTOCATALYST; DOPED TIO2; PERCENTAGE; NANOCOMPOSITES; PERFORMANCE; NANOSHEETS; CATALYSTS; CRYSTALS in [Li, Dianfeng; Wang, Jinguo; Xu, Fengxia; Zhang, Nianchen; Men, Yong] Shanghai Univ Engn Sci, Sch Chem & Chem Engn, Shanghai 201620, Peoples R China in 2021, Cited 46. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5. Recommanded Product: (4-Methoxyphenyl)methanol

Selective conversion of aromatic alcohols to value-added chemicals is becoming an emerging research hotspot in heterogeneous photocatalysis, but its critical challenge is how to construct highly efficient photocatalysts. Herein, mesoporous (001)-TiO2 nanocrystals with tailored Ti3+ and surface oxygen vacancies have been fabricated by a facile hydrothermal route, showing remarkably boosted photoactivity for selective conversion of aromatic alcohols to carbonyl compounds in water medium under visible-light irradiation. Results attest that the remarkably boosted photoactivity was mainly correlated with the strong synergetic effect of exposed (001) facets, Ti3+ self-doping, and surface oxygen vacancies, leading to the enhanced reactant (aromatic alcohols and O-2) activation via the high surface energy of (001) facets, the improved visible-light absorbance via the intrinsic band gap narrowing, and the escalated photoelectron-hole separation efficiency via Ti3+ and surface oxygen vacancies acting as electron sinks. Meanwhile, a plausible photocatalytic mechanism for selective conversion of aromatic alcohols to carbonyl compounds has been elucidated in detail based on active species identified by capture experiments. It is hoped that this work can deliver some new insights into the rational design of highly efficient photocatalysts applied in future green organic selective transformation reactions.

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Quality Control of (4-Methoxyphenyl)methanol. Authors Li, HF; Lupp, D; Das, PK; Yang, L; Goncalves, TP; Huang, MH; El Hajoui, M; Liang, LC; Huang, KW in AMER CHEMICAL SOC published article about in [Lupp, Daniel; Das, Pradip K.; Yang, Li; Goncalves, Theo P.; Huang, Mei-Hui; El Hajoui, Marwa; Huang, Kuo-Wei] King Abdullah Univ Sci & Tech, Div Phys Sci & Engn, Thuwal 239556900, Saudi Arabia; [Li, Huaifeng] Guangxi Normal Univ, Sch Chem & Pharmaceut Sci, State Key Lab Chem & Mol Engn Med Resources, Guilin 541004, Peoples R China; [Liang, Lan-Chang] Natl Sun Yat Sen Univ, Dept Chem, Kaohsiung 80424, Taiwan; [Liang, Lan-Chang] Kaohsiung Med Univ, Dept Med & Appl Chem, Kaohsiung 80708, Taiwan; [Liang, Lan-Chang] Kaohsiung Med Univ, Sch Pharm, Kaohsiung 80708, Taiwan in 2021, Cited 37. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5

The traditional Staudinger/aza-Wittig reaction represents one of the most powerful tools for imine formation. However, for this multistep procedure, the sacrificial phosphine has to be used, resulting in difficulties in the purification process and waste disposal at the same time. Here, we report a redox-neutral azide-alcohol imination methodology enabled by a base-metal nickel PN3 pincer catalyst. The one-step, waste-free, and high atom-economical features highlight its advantages further. Moreover, mechanistic insight suggests a non-metal-ligand cooperation pathway based on the observation of an intermediate and density functional theory calculations.

Quality Control of (4-Methoxyphenyl)methanol. About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Li, HF; Lupp, D; Das, PK; Yang, L; Goncalves, TP; Huang, MH; El Hajoui, M; Liang, LC; Huang, KW or concate me.

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Behera, PK; Choudhury, P; Sahu, SK; Sahu, RR; Harvat, AN; McNulty, C; Stitgen, A; Scanlon, J; Kar, M; Rout, L in [Behera, Pradyota Kumar; Choudhury, Prabhupada; Sahu, Santosh Kumar; Sahu, Rashmi Ranjan; Rout, Laxmidhar] Berhampur Univ, Dept Chem, Berhampur 760007, Orissa, India; [Rout, Laxmidhar] IISER, Dept Chem, Berhampur 760010, Odisha, India; [Harvat, Alisha N.; McNulty, Caitlin; Stitgen, Abigail; Scanlon, Joseph] Ripon Coll, Ripon, WI 54971 USA; [Kar, Manoranjan] IIT Patna, Patna 801106, Bihar, India published Oxygen Bridged Bimetallic CuMoO4 Nanocatalyst for Benzylic Alcohol Oxidation; Mechanism and DFT Study in 2021, Cited 113. Recommanded Product: 105-13-5. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5.

Though concept of oxygen bridged bimetallic catalyst for organic reaction is not well understood. Herein, we have tried to explain the concept by experimental as well as its support by full DFT study. We report here a competent protocol for dehydrogenative oxidation of benzylic alcohol using an oxygen bridged bimetallic CuMoO4 nano catalyst. Careful demonstration reveals that oxidation is not effective either with mono-metallic Cu (II) or Mo(VI); instead combination of both the metals through the oxygen bridge [Cu-O-Mo] unexpectedly and interestingly catalyzed the reaction efficiently. The new concept is strongly supported by computational DFT study. DFT study reveals dehydrogenative oxidation is preferred at copper centre over molybdenum and aromatic benzyl alcohols are greatly stabilised. Interaction barrier energy of monometallic CuO and MoO3 catalyst is much higher than bimetallic CuMoO4. Hydrogen transfer has larger barrier heights for CuO (31.5 kcal/mol) and MoO3 (40.3 kcal/mol) than bimetallic CuMoO4.

About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Behera, PK; Choudhury, P; Sahu, SK; Sahu, RR; Harvat, AN; McNulty, C; Stitgen, A; Scanlon, J; Kar, M; Rout, L or concate me.. Recommanded Product: 105-13-5

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Authors Kalita, T; Dev, D; Mondal, S; Giri, RS; Mandal, B in WILEY-V C H VERLAG GMBH published article about SOLID-PHASE SYNTHESES; ETHYL 2-CYANO-2-(2-NITROBENZENESULFONYLOXYIMINO)ACETATE; UNSYMMETRICAL UREAS; INHIBITORS; PEPTIDE; REAGENT; DESIGN; KINASE; ACIDS in [Kalita, Tapasi; Dev, Dharm; Mondal, Sandip; Giri, Rajat Subhra; Mandal, Bhubaneswar] Indian Inst Technol Guwahati, Dept Chem, Gauhati 781039, Assam, India in 2021, Cited 39. COA of Formula: C8H10O2. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5

Direct conversion of carboxylic acids to ureas, carbamates, and thiocarbamates in a single pot via Curtius rearrangement is accomplished. One recently established coupling reagent, Ethyl-2-cyano-2-(2-nitrophenylsulfonyloximino)acetate (ortho-NosylOXY, I), is successfully used for the racemization free synthesis of ureas, di-peptidyl ureas, and carbamates with moderate to good yield (82-69%). This single-pot hassle-free procedure works with a diverse range of N-protecting groups Fmoc, Boc, and Cbz. Various amine, including aromatic, methyl esters of amino acids, t-butylamine, alcohols, and thiols, are used as nucleophiles. A detailed NMR-based mechanism study is incorporated here. Racemization suppression, easy removal of by-products, and less waste generation make this methodology useful.

COA of Formula: C8H10O2. About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Kalita, T; Dev, D; Mondal, S; Giri, RS; Mandal, B or concate me.

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Application In Synthesis of (4-Methoxyphenyl)methanol. Kumar, A; Kurbah, SD; Syiemlieh, I; Dhanpat, SA; Borthakur, R; Lal, RA in [Kumar, Arvind; Dhanpat, Shobha A.] Univ West Indies, Fac Sci & Technol, Dept Chem, St Augustine Campus, St Augustine, Trinidad Tobago; [Kurbah, Sunshine D.; Syiemlieh, Ibanphylla; Lal, Ram A.] North Eastern Hill Univ, Dept Chem, Ctr Adv Study, Shillong 793022, Meghalaya, India; [Borthakur, Rosmita] Tata Inst Fundamental Res, Ctr Interdisciplinary Sci, Hyderabad 500107, India published Synthesis, characterization, reactivity, and catalytic studies of heterobimetallic vanadium(V) complexes containing hydrazone ligands in 2021, Cited 100. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5.

Six heterobimetallic alkali metal dioxidovanadium(V) coordination polymer complexes {[M-6{VO(mu-O)}(2)(mu-OH)(4)(mu(4)-slox/nph)].n DMF}(infinity) where M = Na, K, and Cs; n = 1 for (1), 0 for (2)-(6) of two dihydrazone ligands, disalicylaldehydeoxaloyldihydrazone (H4slox) and bis(2-hydroxy-1-naphthaldehyde)oxaloyldihydrazone (H4nph) are reported. All the complexes have been characterized by various physicochemical techniques such as elemental analyses, molar conductance, IR, NMR, UV-vis, and cyclic voltammetry. The IR, (HNMR)-H-1, and (CNMR)-C-13 spectral data suggest that the dihydrazones are coordinated through phenolate/naphtholate oxygen, enolate oxygen, and azine nitrogen atoms to the metal centres. The structure of complex {[Na-6{VO(mu-O)}(2)(mu-OH)(4)(mu(4)-slox)].DMF}(infinity) (1) is also determined by single crystal X-ray data, which revealed that the H(4)slox coordinated via all possible dative sites to metal centres as tetrabasic octadentate ligand. The vanadium metal centres adopted distorted square-pyramidal coordination geometries, and the sodium atoms are also in five coordination atmospheres. The electronic spectra of the complexes showed LMCT bands in addition to intra-ligand pi -> pi* and n -> pi* transitions. As evident from the cyclic voltammetry, the complexes showed two metal centred electron transfer reactions {[((VVV)-V-V(slox)(2-)/(VVIV)-V-V(slox)(3-)] and [((VVIV)-V-V(slox)(3-)/(VVIV)-V-V(slox)(4-)]}, in addition to the ligand centred electron transfer reactions. Further, bovine serum albumin (BSA interaction studies of the complexes {[Na (6){VO(mu-O)} (2)(mu-OH) (4)(mu(4)-slox)].DMF} (infinity) (1) and [Na-6{VO(mu-O)}(2)(mu-OH)(4)(mu(4)nph)](infinity) (4) revealed strong binding affinity. Moreover, the catalytic studies of the complexes (1) and (4) were found to be effective for the oxidation of alcohols into their corresponding aldehydes and ketones and bromination of some organic substrates in the presence of H2O2 as an oxidizing agent.

About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Kumar, A; Kurbah, SD; Syiemlieh, I; Dhanpat, SA; Borthakur, R; Lal, RA or concate me.. Application In Synthesis of (4-Methoxyphenyl)methanol

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Recommanded Product: 105-13-5. I found the field of Chemistry very interesting. Saw the article A green approach for aerobic oxidation of benzylic alcohols catalysed by Cu-I-Y zeolite/TEMPO in ethanol without additional additives published in 2021, Reprint Addresses Zhong, W; Liu, XM (corresponding author), Jiaxing Univ, Coll Biol Chem Sci & Engn, Jiaxing, Zhejiang, Peoples R China.. The CAS is 105-13-5. Through research, I have a further understanding and discovery of (4-Methoxyphenyl)methanol.

An efficient and green protocol for aerobic oxidation of benzylic alcohols in ethanol using Cu-I-Y zeolite catalysts assisted by TEMPO (TEMPO = 2,2,6,6-tetramethyl-1-piperidine-N-oxyl) as the radical co-catalyst in the presence of atmospheric air under mild conditions is reported. The Cu-I-Y zeolite prepared via ion exchange between CuCl and HY zeolite was fully characterized by a variety of spectroscopic techniques including XRD, XPS, SEM, EDX and HRTEM. The incorporation of Cu(i) into the 3D-framework of the zeolite rendered the catalyst with good durability. The results of repetitive runs revealed that in the first three runs, there was hardly a decline in activity and a more substantial decrease in yield was observed afterwards, while the selectivity remained almost unchanged. The loss in activity was attributed to both the formation of CuO and the bleaching of copper into the liquid phase during the catalysis, of which the formation of CuO was believed to be the major contributor since the bleaching loss for each run was negligible (<2%). In this catalytic system, except TEMPO, no other additives were needed, either a base or a ligand, which was essential in some reported catalytic systems for the oxidation of alcohols. The aerobic oxidation proceeded under mild conditions (60 degrees C, and 18 hours) to quantitatively and selectively convert a wide range of benzylic alcohols to corresponding aldehydes, which shows great potential in developing green and environmentally benign catalysts for aerobic oxidation of alcohols. The system demonstrated excellent tolerance against electron-withdrawing groups on the phenyl ring of the alcohols and showed sensitivity to steric hindrance of the substrates, which is due to the confinement of the pores of the zeolite in which the oxidation occurred. Based on the mechanism reported in the literature for homogenous oxidation, a mechanism was analogously proposed for the aerobic oxidation of benzylic alcohols catalysed by this Cu(i)-containing zeolite catalyst. About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Senthilkumar, S; Zhong, W; Natarajan, M; Lu, CX; Xu, BY; Liu, XM or concate me.. Recommanded Product: 105-13-5

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