Tag: M.W=100-150

Formula: C8H10O2. Authors Ghosh, R; Jana, NC; Panda, S; Bagh, B in AMER CHEMICAL SOC published article about in [Ghosh, Rahul; Jana, Narayan Ch; Panda, Surajit; Bagh, Bidraha] HBNI, Natl Inst Sci Educ & Res NISER, Sch Chem Sci, Bhubaneswar 752050, Odisha, India in 2021, Cited 111. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5

Coordination of 1,4-disubstituted 1,2,3-triazoles L-1 and L-2 with [(p-cymene)RuCl2](2) followed by dehydrochlorination in the presence of a base resulted in the formation of complexes 1 and 2, respectively. Both were tested for the transfer hydrogenation of aldehydes and ketones in air using ecologically benign and cheap ethanol as the hydrogen source in the presence of a catalytic amount of a base. Air-stable complex 1 was proved to be an active catalyst for the transfer hydrogenation of a wide variety of aromatic and aliphatic aldehydes and ketones bearing various functionalities. Catalyst 1 was also effective for the transfer hydrogenation of carbonyls using the simplest primary alcohol, methanol, under aerobic conditions. Under the present catalytic protocol, labile or reducible functionalities such as nitro, cyano, and ester groups were tolerated. Good selectivity was also observed for acyclic alpha,beta-unsaturated carbonyls. However, this catalytic protocol was not selective for 2-cyclohexen-1-one as both alkene and keto moieties were reduced. The transfer hydrogenations are believed to proceed via a ruthenium-hydride intermediate. Finally, transfer hydrogenation of acetophenone using isopropanol as a commonly used hydrogen source was also performed and the sustainable and green credentials of these catalytic protocols utilizing methanol, ethanol, and isopropanol were compared with the help of the CHEM21 green metrics toolkit.

Formula: C8H10O2. About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Ghosh, R; Jana, NC; Panda, S; Bagh, B or concate me.

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HPLC of Formula: C8H10O2. Authors Ghosh, R; Jana, NC; Panda, S; Bagh, B in AMER CHEMICAL SOC published article about in [Ghosh, Rahul; Jana, Narayan Ch; Panda, Surajit; Bagh, Bidraha] HBNI, Natl Inst Sci Educ & Res NISER, Sch Chem Sci, Bhubaneswar 752050, Odisha, India in 2021, Cited 111. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5

Coordination of 1,4-disubstituted 1,2,3-triazoles L-1 and L-2 with [(p-cymene)RuCl2](2) followed by dehydrochlorination in the presence of a base resulted in the formation of complexes 1 and 2, respectively. Both were tested for the transfer hydrogenation of aldehydes and ketones in air using ecologically benign and cheap ethanol as the hydrogen source in the presence of a catalytic amount of a base. Air-stable complex 1 was proved to be an active catalyst for the transfer hydrogenation of a wide variety of aromatic and aliphatic aldehydes and ketones bearing various functionalities. Catalyst 1 was also effective for the transfer hydrogenation of carbonyls using the simplest primary alcohol, methanol, under aerobic conditions. Under the present catalytic protocol, labile or reducible functionalities such as nitro, cyano, and ester groups were tolerated. Good selectivity was also observed for acyclic alpha,beta-unsaturated carbonyls. However, this catalytic protocol was not selective for 2-cyclohexen-1-one as both alkene and keto moieties were reduced. The transfer hydrogenations are believed to proceed via a ruthenium-hydride intermediate. Finally, transfer hydrogenation of acetophenone using isopropanol as a commonly used hydrogen source was also performed and the sustainable and green credentials of these catalytic protocols utilizing methanol, ethanol, and isopropanol were compared with the help of the CHEM21 green metrics toolkit.

About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Ghosh, R; Jana, NC; Panda, S; Bagh, B or concate me.. HPLC of Formula: C8H10O2

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An article Mesoporous (001)-TiO2 nanocrystals with tailored Ti3+ and surface oxygen vacancies for boosting photocatalytic selective conversion of aromatic alcohols WOS:000644065100024 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. Recommanded Product: 105-13-5. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5

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.

About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Li, DF; Wang, JG; Xu, FX; Zhang, NC; Men, Y or concate me.. Recommanded Product: 105-13-5

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Garg, S; Unruh, DK; Krempner, C in [Garg, Shipra; Unruh, Daniel K.; Krempner, Clemens] Texas Tech Univ, Dept Chem & Biochem, Mem Dr & Boston, Lubbock, TX 79409 USA published Zirconium and hafnium polyhedral oligosilsesquioxane complexes – green homogeneous catalysts in the formation of bio-derived ethers via a MPV/etherification reaction cascade in 2021, Cited 53. SDS of cas: 105-13-5. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5.

The polyhedral oligosilsesquioxane complexes, {[(isobutyl)(7)Si7O12]ZrOPri center dot(HOPri)}(2) (I), {[(cyclohexyl)(7)Si7O12]ZrOPri center dot(HOPri)}(2) (II), {[(isobutyl)(7)Si7O12]HfOPri center dot(HOPri)}(2) (III) and {[(cyclohexyl)(7)Si7O12]HfOPri center dot(HOPri)}(2) (IV), were synthesized in good yields from the reactions of M(OPri)(4) (M = Zr, Hf) with R-POSS(OH)(3) (R = isobutyl, cyclohexyl), resp. I-IV were characterized by H-1, C-13 and Si-29 NMR spectroscopy and their dimeric solid-state structures were confirmed by X-ray analysis. I-IV catalyze the reductive etherification of 2-hydroxy- and 4-hydroxy and 2-methoxy and 4-methoxybenzaldehyde and vanillin to their respective isopropyl ethers in isopropanol as a green solvent and reagent. I-IV are durable and robust homogeneous catalysts operating at temperatures of 100-160 degrees C for days without significant loss of catalytic activity. Likewise, I-IV selectively catalyze the conversion of 5-hydroxymethylfurfural (HMF) into 2,5-bis(isopropoxymethyl)furane (BPMF), a potentially high-performance fuel additive. Similar results were achieved by using a combination of M(OPri)(4) and ligand R-POSS(OH)(3) as a catalyst system demonstrating the potential of this in situ approach for applications in biomass transformations. A tentative reaction mechanism for the reductive etherification of aldehydes catalysed by I-IV is proposed.

SDS of cas: 105-13-5. About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Garg, S; Unruh, DK; Krempner, C or concate me.

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An article Introduction of a trinuclear manganese(iii) catalyst on the surface of magnetic cellulose as an eco-benign, efficient and reusable novel heterogeneous catalyst for the multi-component synthesis of new derivatives of xanthene WOS:000612191100006 published article about ONE-POT SYNTHESIS; RECOVERABLE NANO-CATALYST; FACILE SYNTHESIS; IONIC LIQUID; RECYCLABLE CATALYST; NATURAL PHOSPHATE; HIGHLY EFFICIENT; GREEN CHEMISTRY; SULFONIC-ACID; NANOPARTICLES in [Kargar, Pouya Ghamari; Bagherzade, Ghodsieh] Univ Birjand, Fac Sci, Dept Chem, Birjand 97175615, Iran; [Eshghi, Hossein] Ferdowsi Univ Mashhad, Fac Sci, Dept Chem, Mashhad, Razavi Khorasan, Iran in 2021, Cited 77. Name: (4-Methoxyphenyl)methanol. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5

In this work, the new trinuclear manganese catalyst defined as Fe3O4@NFC@NNSM-Mn(iii) was successfully manufactured and fully characterized by different techniques, including FT-IR, XRD, TEM, SEM, EDX, VSM, and ICP analysis. There have been reports of the use of magnetic catalysts for the synthesis of xanthine derivatives. The critical potential interest in the present method include short reaction time, high yields, recyclability of the catalyst, easy workup, and the ability to sustain a variety of functional groups, which give economical as well as ecological rewards. Also, the synthesized catalyst was used as a recyclable trinuclear catalyst in alcohol oxidation reactions at 40 degrees C. The magnetic catalyst activity of Fe3O4@NFC@NNSM-Mn(iii) could be attributed to the synergistic effects of the catalyst Fe3O4@NFC@NNS-Mn(iii) with melamine. Employing a sustainable and safe low temperature, using an eco-friendly solvent, no need to use any additive, and long-term stability and magnetic recyclability of the catalyst for at least six successive runs are the advantages of the current protocol towards green chemistry. This protocol is a benign, environmentally friendly method for heterocycle synthesis.

About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Kargar, PG; Bagherzade, G; Eshghi, H or concate me.. Name: (4-Methoxyphenyl)methanol

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Application In Synthesis of (4-Methoxyphenyl)methanol. Authors Feng, XY; Pi, YH; Song, Y; Xu, ZW; Li, Z; Lin, WB in AMER CHEMICAL SOC published article about in [Feng, Xuanyu; Pi, Yunhong; Song, Yang; Xu, Ziwan; Lin, Wenbin] Univ Chicago, Dept Chem, Chicago, IL 60637 USA; [Pi, Yunhong; Li, Zhong] South China Univ Technol, Sch Chem & Chem Engn, Guangzhou 510640, Peoples R China in 2021, Cited 63. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5

We report here the construction of two metal-organic frameworks (MOFs), Zr-6-Cu/Fe-1 and Zr-6–Cu/Fe-2, by integrating earth-abundant cuprous photosensitizers (Cu-PSs) and Fe catalysts for photocatalytic aerobic oxidation. Site isolation and pore confinement stabilize both Cu-PSs and Fe catalysts, while the proximity between active centers facilitates electron and mass transfer. Upon visible light irradiation and using O-2 as the only oxidant, Zr-6-Cu/Fe-1 and Zr-6-Cu/ Fe-2 efficiently oxidize alcohols and benzylic compounds to afford corresponding carbonyl products with broad substrate scopes, high turnover numbers of up to 500 with a 9.4-fold enhancement over homogeneous analogues, and excellent recyclability in four consecutive runs. Control experiments, spectroscopic evidence, and computational studies revealed the photooxidation mechanism: oxidative quenching of [Cu-PS]* by O-2 affords [Cu-II-PS], which efficiently oxidizes Fe-III-OH to generate a hydroxyl radical for substrate oxidation. This work highlights the potential of MOFs in promoting earth-abundant metal-based photocatalysis.

Application In Synthesis of (4-Methoxyphenyl)methanol. About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Feng, XY; Pi, YH; Song, Y; Xu, ZW; Li, Z; Lin, WB or concate me.

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An article Bioinspired Radical-Mediated Transition-Metal-Free Synthesis of N-Heterocycles under Visible Light WOS:000590308900001 published article about DEPENDENT AMINE OXIDASES; AEROBIC OXIDATION; CATALYTIC MECHANISM; ALCOHOL OXIDATION; TOPA QUINONE; ACTIVE-SITE; COPPER; HYDROGEN; MODEL; PYRIMIDINES in [K. Bains, Amreen; Adhikari, Debashis] Indian Inst Sci Educ & Res IISER Mohali, Dept Chem Sci, Sas Nagar 140306, Punjab, India; [Ankit, Yadav] Indian Inst Sci Educ & Res IISER Mohali, Dept Earth & Environm Sci, Sas Nagar 140306, Punjab, India in 2021, Cited 42. Recommanded Product: (4-Methoxyphenyl)methanol. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5

A redox-active iminoquinone motif connected with pi-delocalized pyrene core has been reported that can perform efficient two-electron oxidation of a class of substrates. The design of the molecule was inspired by the organic redox cofactor topaquinone (TPQ), which executes amine oxidation in the enzyme, copper amine oxidase. Easy oxidation of both primary and secondary alcohols happened in the presence of catalytic KOtBu, which could reduce the ligand backbone to its iminosemiquinonate form under photoinduced conditions. Moreover, this easy oxidation of alcohols under aerobic condition could be elegantly extended to multi-component, one-pot coupling for the synthesis of quinoline and pyrimidine. This organocatalytic approach is very mild (70 degrees C, 8 h) compared to a multitude of transition-metal catalysts that have been used to prepare these heterocycles. A detailed mechanistic study proves the intermediacy of the iminosemiquinonate-type radical and a critical hydrogen atom transfer step to be involved in the dehydrogenation reaction.

About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Bains, AK; Ankit, Y; Adhikari, D or concate me.. Recommanded Product: (4-Methoxyphenyl)methanol

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COA of Formula: C8H10O2. Authors Sait, N; Aliouane, N; Toukal, L; Hammache, H; Al-Noaimi, M; Helesbeux, JJ; Duval, O in ELSEVIER published article about in [Sait, N.; Aliouane, N.; Hammache, H.] Univ Bejaia, Dept Genie Proc, Lab Electrochim Corros & Valorisat Energet, Bejaia 06000, Algeria; [Toukal, L.] Univ Ferhat Abbas Setif 1, Dept Genie Proc, Lab Electrochim Ingn Mol & Catalyse Redox, Setif, Algeria; [Al-Noaimi, M.] Hashemite Univ, Fac Sci, Dept Chem, POB 330127, Zarqa 13133, Jordan; [Helesbeux, J. J.; Duval, O.] Univ Angers, Univ Bretagne Loire, SFR QUASAV 4207, Lab SONAS,EA921, 42 Rue Georges Morel, Beaucouze, France in 2021, Cited 83. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5

The inhibition performance of the newly synthesized Ethylene bis [(2-hydroxy-5,1,3-phenylene) bismethylene] tetraphosphonic acid (ETPA) toward carbon steel in 3% NaCl was investigated at different concentrations using potentiodynamic polarization (PDP) and impedance spectroscopy (EIS) methods. It was found that the inhibition capability was increased with increasing inhibitor dose and reach 92% at 10(-3) mol/L. Also, Polarization curves showed that ETPA acts as a mixed type inhibitor with predominantly control of anodic reaction. The new inhibitor was investigated by different spectroscopic methods such as H-1, C-13 and (PNMR)-P-31. The quantum parameters such as absolute electronegativity (chi), energy gap Delta(E) (E-HOMO-E-LUMO), global softness (sigma), global hardness (eta), electrophilicity index (omega) and the number of transfer electrons (Delta N) are calculated by density functional theory (DFT). The experimental also correlated with density functional theory results. The calculations show that ETPA has high density of negative charge located on the oxygen atoms of the phosphonate group facilitating the adsorption of ETPA on the surface of carbon steel. The inhibition efficiency of ETPA was discussed in terms of blocking of electrode surface by adsorption of ETPA molecules through active centers. The adsorption of ETPA on the surface of carbon steel obeyed the Langmuir isotherm paradigm. (C) 2021 Elsevier B.V. All rights reserved.

COA of Formula: C8H10O2. About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Sait, N; Aliouane, N; Toukal, L; Hammache, H; Al-Noaimi, M; Helesbeux, JJ; Duval, O or concate me.

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An article Synthesis of the C1-C16 fragment of bryostatin for incorporation into 20,20-fluorinated analogues WOS:000599822100009 published article about ANTINEOPLASTIC AGENTS; DERIVATIVES; MACROLIDE; LEADS in [Mears, Paul R.; Thomas, Eric J.] Univ Manchester, Dept Chem, Manchester M13 9PL, Lancs, England in 2021, Cited 44. Safety of (4-Methoxyphenyl)methanol. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5

The stereoselective synthesis of a carboxylic acid ester corresponding to the C1 -C16 fragment of bryostatin, with 4-methoxybenzyl (PMB) protection for the 7-hydroxyl group, is reported. The key steps included a Horner-Wadsworth-Emmons reaction between (5R)-3-[ (E)-2-tri- isop ropyls ilyloxy ethylidene]-6-(4-methoxybenzyloxy)-5-triethylsilyloxyhexanal and dimethyl (4,5,6R,85)-10-hydroxy-6,8-di-O-isopropylidene 4 (4 methoxybenzyloxy)-3,3-dimethyl-2-oxodecan-1-yl phosphonate, that gave the corresponding (E)-alkene, followed by selective cleavage of the triethylsilyl ether and cyclisation to give the required 2,6-cis-disubstituted 4-[(Z)-tri-isopropylsilyloxyethylide]tetrahydropyran. Oxidation of the primary alcohol gave the corresponding carboxylic acid that was converted into the required allyl ester. (C) 2020 Elsevier Ltd. All rights reserved.

Safety of (4-Methoxyphenyl)methanol. About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Mears, PR; Thomas, EJ or concate me.

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In 2021 SCI REP-UK published article about MANNOSE-BINDING LECTIN; IMMUNE COMPONENT FICOLIN-3; ALL-CAUSE MORTALITY; VASCULAR COMPLICATIONS; COMPLEMENT; ASSOCIATION; MICROALBUMINURIA; POPULATION; DEFICIENCY; SEVERITY in [Ostergaard, Jakob Appel] Aarhus Univ Hosp, Dept Endocrinol & Internal Med, Aarhus, Denmark; [Ostergaard, Jakob Appel; Hansen, Troels Krarup] Aarhus Univ Hosp, Steno Diabet Ctr Aarhus, Aarhus, Denmark; [Sigfrids, Fanny Jansson; Forsblom, Carol; Dahlstrom, Emma H.; Thorn, Lena M.; Harjutsalo, Valma; Groop, Per-Henrik] Folkhalsan Res Ctr, Folkhalsan Inst Genet, Helsinki, Finland; [Sigfrids, Fanny Jansson; Forsblom, Carol; Dahlstrom, Emma H.; Thorn, Lena M.; Harjutsalo, Valma; Groop, Per-Henrik] Univ Helsinki, Nephrol, Abdominal Ctr, Helsinki, Finland; [Sigfrids, Fanny Jansson; Forsblom, Carol; Dahlstrom, Emma H.; Thorn, Lena M.; Harjutsalo, Valma; Groop, Per-Henrik] Helsinki Univ Hosp, Helsinki, Finland; [Sigfrids, Fanny Jansson; Forsblom, Carol; Dahlstrom, Emma H.; Thorn, Lena M.; Harjutsalo, Valma; Groop, Per-Henrik] Univ Helsinki, Res Program Clin & Mol Metab, Fac Med, Helsinki, Finland; [Thorn, Lena M.] Univ Helsinki, Dept Gen Practice & Primary Hlth Care, Helsinki, Finland; [Harjutsalo, Valma] Natl Inst Hlth & Welf, Helsinki, Finland; [Flyvbjerg, Allan] Capital Reg Denmark, Steno Diabet Ctr Copenhagen, Copenhagen, Denmark; [Thiel, Steffen] Aarhus Univ, Dept Biomed, Aarhus, Denmark; [Groop, Per-Henrik] Monash Univ, Cent Clin Sch, Dept Diabet, Melbourne, Vic, Australia in 2021, Cited 39. The Name is (4-Methoxyphenyl)methanol. Through research, I have a further understanding and discovery of 105-13-5. SDS of cas: 105-13-5

H-ficolin recognizes patterns on microorganisms and stressed cells and can activate the lectin pathway of the complement system. We aimed to assess H-ficolin in relation to the progression of diabetic kidney disease (DKD), all-cause mortality, diabetes-related mortality, and cardiovascular events. Event rates per 10-unit H-ficolin-increase were compared in an observational follow-up of 2,410 individuals with type 1 diabetes from the FinnDiane Study. DKD progression occurred in 400 individuals. The unadjusted hazard ratio (HR) for progression was 1.29 (1.18-1.40) and 1.16 (1.05-1.29) after adjustment for diabetes duration, sex, HbA(1c), systolic blood pressure, and smoking status. After adding triglycerides to the model, the HR decreased to 1.07 (0.97-1.18). In all, 486 individuals died, including 268 deaths of cardiovascular causes and 192 deaths of complications to diabetes. HRs for all-cause mortality and cardiovascular mortality were 1.13 (1.04-1.22) and 1.05 (0.93-1.17), respectively, in unadjusted analyses. These estimates lost statistical significance in adjusted models. However, the unadjusted HR for diabetes-related mortality was 1.19 (1.05-1.35) and 1.18 (1.02-1.37) with the most stringent adjustment level. Our results, therefore, indicate that H-ficolin predicts diabetes-related mortality, but neither all-cause mortality nor fatal/non-fatal cardiovascular events. Furthermore, H-ficolin is associated with DKD progression, however, not independently of the fully adjusted model.

SDS of cas: 105-13-5. About (4-Methoxyphenyl)methanol, If you have any questions, you can contact Ostergaard, JA; Sigfrids, FJ; Forsblom, C; Dahlstrom, EH; Thorn, LM; Harjutsalo, V; Flyvbjerg, A; Thiel, S; Hansen, TK; Groop, PH or concate me.

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