Phosphorus Acids as Highly Efficient Promoters for the Palladium‐Phenanthroline Catalyzed Carbonylation of Nitrobenzene to Methyl Phenylcarbamate^†

Abstract: A new family of promoters, based on phosphorus acids, is reported for the catalytic carbonylation of nitrobenzene to methyl phenylcarbamate by palladium-phenanthroline complexes. With the new promoters, unprecedented reaction rates (TOF up to 6000/h) and catalyst stability (TON up to 10 5 ) could be reached. The best promoter is phosphoric acid, which is also very cheap, nontoxic and easily separable from the reaction products.

“…The reactivity of the alcohols was highest for MeOH, and decreased with increasing the alkyl chain length (entries [1][2][3][4][5]. This result may be ascribed to stronger inductive effect on the carbonyl of urea with higher polarity of the longer chain alcohol.…”

“…The catalytic performances of different Zn to AlPO 4 molar ratios for ZnAlPO 4 catalysts were investigated. The results are shown in Table 1.…”

“…The reason could be due to the rate of both 3 and 4 production from Reactions (1) and (2) [24,25], being higher with an increase of urea/HDA molar ratio from 2.0 to 3.0 than that of the consumption from Reactions (3), (4), (5) and (6), respectively. On the other hand, for both 1 and 5, the rate of production from Reactions (3), (4) and (7) [20,26], were lower at the urea/HDA molar ratio higher than 2.2 than that of consumption from Reactions (8) and (9) Figure 3 presents the effect of the urea/HDA molar ratio on the conversion of HDA, yield of 2, and selectivities for the four main byproducts (1, 3-5) under the reaction conditions: HDA 0.9 mol, ZnAlPO4 3.0 g, butanol 7.74 mol (708.0 mL), time 6 h, temperature 493 K and pressure 1.2 MPa. With the increase of urea/HDA molar ratio from 2.0:1 to 3.0:1, the conversion of HDA and the yield of 2 increased rapidly from 2.0:1 to 2.6:1 while it increased only slightly from 2.6:1 to 3.0:1, and a maximum value of 92.0% was achieved for the yield of 2 at the urea/HDA molar ratio of 3.0:1.…”

“…The berlinite-structured AlPO 4 and ZnAlPO 4 were hydrothermally synthesized by the same procedure as reported in our previous work [17]. The synthesized specimens were denoted as ZnAlPO 4 (X), where X refers to the Zn/Al molar ratio in the specimen.…”

“…However, a number of drawbacks may occur in the route, including difficult handling of the toxic phosgene and the seriously corrosive side product HCl [2]. Several phosgene-free routes for organic carbamates synthesis have also been reported [4][5][6][7][8][9], among which the synthesis from amines, urea and alcohols by a one-pot reaction [9] has received considerable attention. This route appears to be promising because, on the one hand, ammonia is obtained as a main byproduct and, on the other hand, urea can be prepared on a large scale by the dehydration of ammonia and CO 2 [10].…”

One-Pot Synthesis of Dialkyl Hexane-1,6-Dicarbamate from 1,6-Hexanediamine, Urea, and Alcohol over Zinc-Incorporated Berlinite (ZnAlPO4) Catalyst

“…The reactivity of the alcohols was highest for MeOH, and decreased with increasing the alkyl chain length (entries [1][2][3][4][5]. This result may be ascribed to stronger inductive effect on the carbonyl of urea with higher polarity of the longer chain alcohol.…”

“…The catalytic performances of different Zn to AlPO 4 molar ratios for ZnAlPO 4 catalysts were investigated. The results are shown in Table 1.…”

“…The reason could be due to the rate of both 3 and 4 production from Reactions (1) and (2) [24,25], being higher with an increase of urea/HDA molar ratio from 2.0 to 3.0 than that of the consumption from Reactions (3), (4), (5) and (6), respectively. On the other hand, for both 1 and 5, the rate of production from Reactions (3), (4) and (7) [20,26], were lower at the urea/HDA molar ratio higher than 2.2 than that of consumption from Reactions (8) and (9) Figure 3 presents the effect of the urea/HDA molar ratio on the conversion of HDA, yield of 2, and selectivities for the four main byproducts (1, 3-5) under the reaction conditions: HDA 0.9 mol, ZnAlPO4 3.0 g, butanol 7.74 mol (708.0 mL), time 6 h, temperature 493 K and pressure 1.2 MPa. With the increase of urea/HDA molar ratio from 2.0:1 to 3.0:1, the conversion of HDA and the yield of 2 increased rapidly from 2.0:1 to 2.6:1 while it increased only slightly from 2.6:1 to 3.0:1, and a maximum value of 92.0% was achieved for the yield of 2 at the urea/HDA molar ratio of 3.0:1.…”

“…The berlinite-structured AlPO 4 and ZnAlPO 4 were hydrothermally synthesized by the same procedure as reported in our previous work [17]. The synthesized specimens were denoted as ZnAlPO 4 (X), where X refers to the Zn/Al molar ratio in the specimen.…”

“…However, a number of drawbacks may occur in the route, including difficult handling of the toxic phosgene and the seriously corrosive side product HCl [2]. Several phosgene-free routes for organic carbamates synthesis have also been reported [4][5][6][7][8][9], among which the synthesis from amines, urea and alcohols by a one-pot reaction [9] has received considerable attention. This route appears to be promising because, on the one hand, ammonia is obtained as a main byproduct and, on the other hand, urea can be prepared on a large scale by the dehydration of ammonia and CO 2 [10].…”

One-Pot Synthesis of Dialkyl Hexane-1,6-Dicarbamate from 1,6-Hexanediamine, Urea, and Alcohol over Zinc-Incorporated Berlinite (ZnAlPO4) Catalyst

Carbonylation of Nitroarenes and Aromatic Amines

isocyanates