Phosphor-doped graphitic carbon nitride-supported Pd as a highly efficient catalyst for styrene hydrogenation

“…The Pd actual load and particle size with different PdCl 2 solution contents are shown, respectively, in Figure S8. With the increase of Pd addition, the content and particle size of Pd NPs increased gradually, which indicated that the loading and particle size could meet the requirements by adjusting the addition of PdCl . Experiments were carried out with different Pd addition; with the increase of Pd loading, the denitrification rate of the catalyst increased and then decreased, but the ammonia selectivity was in contrast as shown in Figure a.…”

“…The activity of the catalyst is evaluated with the turnover frequency (TOF) value, representing the number of conversions on a single active site per time . Experiments were performed in 200 mL of 30 mmol/L Fe­(II)­EDTA-NO with 100 mg catalyst, at pH 6 and 60 °C, and the TOF of catalysts was calculated using the formula as follows: where t is reaction time ( h ), n Pd is the molar amount of Pd on catalysts, and D is metal dispersion.…”

“…With the increase of Pd addition, the content and particle size of Pd NPs increased gradually, which indicated that the loading and particle size could meet the requirements by adjusting the addition of PdCl. 25 Experiments were carried out with different Pd addition; with the increase of Pd loading, the denitrification rate of the catalyst increased and then decreased, but the ammonia selectivity was in contrast as shown in Figure 5a. However, the increase of Pd content brought more catalytic sites, which improved the reaction rate.…”

“…Herein, to achieve the regeneration of complex solution without introducing new ions into the complex solution, we first report the use of Pd nanoparticles (NPs) as a catalyst to reduce the denitrification of complex solution by formic acid (FA). , FA was oxidized to CO 2 , NO­(aq) was reduced to N 2 , and the complex solution can obtain the ability to adsorb NO again. − Furthermore, higher activity and selectivity were obtained by the selection of N-doped porous carbons (NPCs) as the support. − Different from activated carbon (AC), the dispersion, particle size, and binding stability of Pd NPs (2.31 ± 0.43 nm) were improved by the interaction between Pd and N atoms in NPCs. − Fe­(II)­EDTA was used as the chelating agent because of its cheap price and simple preparation . As expected, at an Fe­(II)­EDTA-NO concentration of 30 mmol/L, the denitrification rate reached 90.4% with an N 2 selectivity of 99.6% within 5 min.…”

N-Doped Porous Carbon-Anchored Pd Nanoparticles: A Highly Efficient Catalyst for Fe(II)EDTA-NO Reduction

“…The Pd actual load and particle size with different PdCl 2 solution contents are shown, respectively, in Figure S8. With the increase of Pd addition, the content and particle size of Pd NPs increased gradually, which indicated that the loading and particle size could meet the requirements by adjusting the addition of PdCl . Experiments were carried out with different Pd addition; with the increase of Pd loading, the denitrification rate of the catalyst increased and then decreased, but the ammonia selectivity was in contrast as shown in Figure a.…”

“…The activity of the catalyst is evaluated with the turnover frequency (TOF) value, representing the number of conversions on a single active site per time . Experiments were performed in 200 mL of 30 mmol/L Fe­(II)­EDTA-NO with 100 mg catalyst, at pH 6 and 60 °C, and the TOF of catalysts was calculated using the formula as follows: where t is reaction time ( h ), n Pd is the molar amount of Pd on catalysts, and D is metal dispersion.…”

“…With the increase of Pd addition, the content and particle size of Pd NPs increased gradually, which indicated that the loading and particle size could meet the requirements by adjusting the addition of PdCl. 25 Experiments were carried out with different Pd addition; with the increase of Pd loading, the denitrification rate of the catalyst increased and then decreased, but the ammonia selectivity was in contrast as shown in Figure 5a. However, the increase of Pd content brought more catalytic sites, which improved the reaction rate.…”

“…Herein, to achieve the regeneration of complex solution without introducing new ions into the complex solution, we first report the use of Pd nanoparticles (NPs) as a catalyst to reduce the denitrification of complex solution by formic acid (FA). , FA was oxidized to CO 2 , NO­(aq) was reduced to N 2 , and the complex solution can obtain the ability to adsorb NO again. − Furthermore, higher activity and selectivity were obtained by the selection of N-doped porous carbons (NPCs) as the support. − Different from activated carbon (AC), the dispersion, particle size, and binding stability of Pd NPs (2.31 ± 0.43 nm) were improved by the interaction between Pd and N atoms in NPCs. − Fe­(II)­EDTA was used as the chelating agent because of its cheap price and simple preparation . As expected, at an Fe­(II)­EDTA-NO concentration of 30 mmol/L, the denitrification rate reached 90.4% with an N 2 selectivity of 99.6% within 5 min.…”

N-Doped Porous Carbon-Anchored Pd Nanoparticles: A Highly Efficient Catalyst for Fe(II)EDTA-NO Reduction

“…5 Although Pd catalysts show high activity in diolefins hydrogenation reactions, they suffer from low selectivity due to over-hydrogenation of monoolefins, as well as easy loss of active components leading to catalyst deactivation. 9–12 It is still necessary to develop high performance catalysts for isoprene selective hydrogenation.…”

Isoprene selective hydrogenation using AgCu-promoted Pd nanoalloys

Advanced Carbon‐Based Nanocatalysts and their Application in Catalytic Conversion of Renewable Platform Molecules