Towards a Phosgene-Free Synthesis of Aryl Isocyanates: Alcoholysis of N-phenylurea to N-phenyl-O-methyl Carbamate Promoted by Basic Metal Oxide Nanoparticles and Organocatalysts

Juárez, Raquel; Corma, Avelino; Garcı́a, Hermenegildo

doi:10.1007/s11244-009-9303-4

Cited by 29 publications

(17 citation statements)

References 47 publications

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“…Carbamates attract much attention because of their many applications to pharmaceuticals, agrochemicals, protecting groups and polyurethanes . Carbamates are traditionally produced by using toxic and hazardous reagents such as phosgene or CO, and environmentally‐friendly alternative catalytic methods have been intensively investigated: aminolysis of organic carbonates, alcoholysis of ureas, coupling reaction of dimethyl carbonate (DMC) and N , N′ ‐substituted urea and so on. Recently, carbamate syntheses with CO 2 as a carbonyl source have been demonstrated using reactive reagents such as N ‐tosylhydrazones, alkylhalides, metal alkoxides and silicate esters .…”

Section: Methodsmentioning

confidence: 99%

Direct Catalytic Synthesis of N‐Arylcarbamates from CO₂, Anilines and Alcohols

et al. 2018

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The direct catalytic synthesis of carbamates from CO 2 , amines and methanol was achieved by controlling both the reaction equilibrium and the reactivity of the three components. The combination of CeO 2 and 2-cyanopyridine was an effective catalyst, providing various carbamates including N-arylcarbamates in high selectivities.Transformation of CO 2 to valuable chemicals can contribute not only to CO 2 fixation but also to effective CO 2 utilization as a C1 resource. Carbamates attract much attention because of their many applications to pharmaceuticals, agrochemicals, protecting groups and polyurethanes. [1] Carbamates are traditionally produced by using toxic and hazardous reagents such as phosgene or CO, [2] and environmentally-friendly alternative catalytic methods have been intensively investigated: aminolysis of organic carbonates, [3] alcoholysis of ureas, [4] coupling reaction of dimethyl carbonate (DMC) and N,N'-substituted urea [5] and so on. Recently, carbamate syntheses with CO 2 as a carbonyl source have been demonstrated using reactive reagents such as N-tosylhydrazones, [6] alkylhalides, [7] metal alkoxides [8] and silicate esters. [9] Compared with these approaches, carbamate synthesis from CO 2 , amines and alcohols will be ideal (Scheme 1) because the by-product is theoretically only water and all substrates are easily available. [10] N-Arylcarbamates are the most useful among various carbamates, [11] however there are no effective catalyst systems for the arylcarbamate synthesis from CO 2 , arylamines and alcohols (yield 10 %, Table S1) owing to the inert character of CO 2 , equilibrium limitation and side reactions as well as the low reactivity (low basicity and nucleophilicity) of arylamines. [6] The prospective byproducts are organic carbonates from CO 2 and alcohols, and N,N'-disubstituted ureas from CO 2 and amines (Scheme 1). Therefore, development of catalyst systems which can sophisticatedly control the reactivities of the three components and overcome the equilibrium limitation is desirable. Recently, we found that combination of CeO 2 and 2cyanopyridine was an effective catalyst system for the synthesis of dimethyl carbonate (DMC) from CO 2 + CH 3 OH [12] and cyclic carbonates [13] and polycarbonates [14] from CO 2 + diols. Urakawa and co-workers also applied the combination catalyst system to the DMC synthesis at high CO 2 pressure. [15] The severe equilibrium was overcome by removal of H 2 O from the reaction media through the nitrile hydration over CeO 2 . In addition, 2cyanopyridine can be recovered by dehydration of the produced 2-picolinamide over alkali metal-supported SiO 2 catalysts. [12a,d] We envisioned that the combination catalyst was applicable to the one-pot carbamate synthesis from CO 2 , amines and alcohols.At first, we applied the catalyst of CeO 2 and 2-cyanopyridine to methyl N-phenylcarbamate (MPC) formation from CO 2 , aniline and CH 3 OH as a model reaction (Figure 1 and Table S2). Fortunately, the reaction with CeO 2 and 2-cyanopyridine proceeded smooth...

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Section: Methodsmentioning

confidence: 99%

Direct Catalytic Synthesis of N‐Arylcarbamates from CO₂, Anilines and Alcohols

et al. 2018

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“…There are several green alternative routes for carbamates syntheses, such as reductive carbonylation of nitro compounds, oxidative carbonylation of amines, methoxycarbonylation of amines, and alcoholysis of substituted ureas …”

Section: Nipu Obtained By Polycondensation Methodsmentioning

confidence: 99%

Non‐isocyanate polyurethanes: synthesis, properties, and applications

Rokicki

Parzuchowski

Mazurek

2015

Polymers for Advanced Techs

338

233

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Conventional polyurethanes are typically obtained from polyisocyanates, polyols, and chain extenders. The main starting materials-isocyanates used in this process-raise severe health hazard concerns. Therefore, there is a growing demand for environment-friendly processes and products. This review article summarizes progress that has been made in recent years in the development of alternative methods of polyurethane synthesis. In most of them, carbon dioxide is applied as a sustainable feedstock for polyurethane production directly or indirectly. The resulting nonisocyanate polyurethanes are characterized by a solvent-free synthesis, resistance to chemical degradation, 20% more wear resistance than conventional polyurethane, and can be applied on wet substrates and cured under cold conditions. Three general polymer synthetic methods, step-growth polyaddition, polycondensation, and ring-opening polymerization, are presented in the review. Much attention is given to the most popular and having potential industrial importance method of obtaining non-isocyanate polyurethanes, poly(hydroxy-urethane)s, based upon multicyclic carbonates and aliphatic amines. It is evident from the present review that considerable effort has been made during the last years to develop environmentally friendly methods of obtaining polyurethanes, especially those with the use of carbon dioxide or simple esters of carbonic acid. Scheme 1. [n,m]-Polyurethane synthesis from alkylene bis(chloroformate)s and diamines. Scheme 2. Synthesis of NIPU in the reaction of alkylene bis(phenyl carbonate) with diamine. Scheme 3. Synthesis of [n]-polyurethane from aminoalkyl chloroformate.Scheme 4. Synthesis of [6]-polyurethane from 6-amino-1-hexanol. Scheme 5. Synthesis of allylcarbamate monomer and poly(thioether-urethane).708 Scheme 8. Synthesis of NIPU via AB-type self-polycondensation.Scheme 7. Multistep synthesis of isosorbide-based polyurethane (polycondensation mode). Scheme 6. Multistep synthesis of isosorbide-based polyurethane (polyaddition mode).

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“…Synthesis of carbamates starting from isocyanates could be achieved through the use of strong bases [32], and metal halides [33] etc. Carbamates could be converted into isocyanates by thermal decomposition at higher temperatures using different reaction conditions such as use of metal catalysts [34], chlorocatecholborane/boron halides with triethylamine [35], silanes [36], chlorosilanes [37], dichlorosilanes [ conditions [39], montmorillonite K-10 [40], Bi 2 O 3 [41], and recently used basic metal oxide nanoparticles [42] etc.…”

Section: CLmentioning

confidence: 99%

Recent Developments on the Carbamation of Amines

Chaturvedi

2011

COC

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Organic carbamates represent an important class of compounds showing various interesting properties. They find wide utility in various areas as pharmaceuticals, agrochemicals (pesticides, herbicides, insecticides, fungicides etc.), intermediates in organic synthesis, protection of amino group in peptide chemistry, and as linker in combinatorial chemistry etc. Classical synthesis of carbamates involves use of harmful reagents such as phosgene, its derivatives and carbon monoxide. Recently, various kinds of synthetic methods have been developed for the synthesis of organic carbamates. In the present review, I would like to highlight the recent developments on the synthesis of organic carbamates using variety of reagents.

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Towards a Phosgene-Free Synthesis of Aryl Isocyanates: Alcoholysis of N-phenylurea to N-phenyl-O-methyl Carbamate Promoted by Basic Metal Oxide Nanoparticles and Organocatalysts

Cited by 29 publications

References 47 publications

Direct Catalytic Synthesis of N‐Arylcarbamates from CO₂, Anilines and Alcohols

Direct Catalytic Synthesis of N‐Arylcarbamates from CO₂, Anilines and Alcohols

Non‐isocyanate polyurethanes: synthesis, properties, and applications

Recent Developments on the Carbamation of Amines

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Towards a Phosgene-Free Synthesis of Aryl Isocyanates: Alcoholysis of N-phenylurea to N-phenyl-O-methyl Carbamate Promoted by Basic Metal Oxide Nanoparticles and Organocatalysts

Cited by 29 publications

References 47 publications

Direct Catalytic Synthesis of N‐Arylcarbamates from CO2, Anilines and Alcohols

Direct Catalytic Synthesis of N‐Arylcarbamates from CO2, Anilines and Alcohols

Non‐isocyanate polyurethanes: synthesis, properties, and applications

Recent Developments on the Carbamation of Amines

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Product

Resources

About

Direct Catalytic Synthesis of N‐Arylcarbamates from CO₂, Anilines and Alcohols

Direct Catalytic Synthesis of N‐Arylcarbamates from CO₂, Anilines and Alcohols