A facile hydrothermal approach for construction of carbon coating on TiO2 nanoparticles

Abstract: Herein a facile hydrothermal approach is used to construct carbon coated TiO2 nanoparticles employing dextrose as the source of carbon. The procedure is operated at a low temperature of 200 °C. Fourier infrared spectroscopy demonstrated the successful coating of carbon on TiO2 nanoparticles. The phase composition of TiO2 and carbon coated TiO2 nanoparticles were studied using X-ray diffraction and the surface morphology was analyzed by scanning and transmission electron microscopy. The existence of carbon coat… Show more

“…As illustrated in Scheme , the reference plasmonic photocatalyst consists of Au NPs randomly deposited at the surface of TiO 2 NBs (structure I, Figure S3, Supporting Information). Various methods have been developed to synthesize TiO 2 –C hybrids, e.g., hydrothermal carbonization (HTC) of biomass and ultraviolet (UV) light/HTC reduction of graphene oxide . However, these approaches usually do not allow for facile colocalization of both C and Au.…”

“…Surprisingly, depollution tests and photoelectrochemical cell (PEC) tests and incident photo to current efficient (IPCE) results under visible light (λ > 420 nm) point toward an entirely different conclusion. The photodegradation of methylene blue (MB) as test pollutant was used to assess the catalytic activity of the TiO 2 –Au–C nanostructures under visible light ( Figure ), which also has been widely used for the assessment of the catalytic activity of semiconductor photocatalyst . The plots of C / C 0 versus time ( t ), where C 0 and C are the concentrations of MO at initial reaction time ( t = 0) and at time t , respectively, are shown in Figure a.The activity of the three TiO 2 –Au–C samples is appreciably higher than the one of TiO 2 , TiO 2 @C, and TiO 2 –Au samples.…”

“…The photodegradation of methylene blue (MB) as test pollutant was used to assess the catalytic activity of the TiO 2 -Au-C nanostructures under visible light (Figure 4), which also has been widely used for the assessment of the catalytic activity of semiconductor photocatalyst. [17][18][19][20] The plots of C/C 0 versus time (t), where C 0 and C are the concentrations of MO at initial reaction time (t = 0) and at time t, respectively, are shown in Figure 4a.The activity of the three TiO 2 -Au-C samples is appreciably higher than the one of TiO 2 , TiO 2 @C, and TiO 2 -Au samples. This photodegradation reaction kinetics follows a first-order rate law, [17][18][19][20][21] as shown by a highly linear ln(C 0 /C) versus t plot (R 2 > 0.992, Figure 4b) with the slope corresponding to the reaction rate constant k. The TiO 2 @C-Au@C sample has a photocatalytic activity (k = 9.37 × 10 −3 min −1 ) which is ≈13 times higher than TiO 2 NBs (k = 6.81 × 10 −4 min −1 ) and ≈5 times higher than TiO 2 @C (k = 1.87 × 10 −3 min −1 ).…”

“…[17][18][19][20] The plots of C/C 0 versus time (t), where C 0 and C are the concentrations of MO at initial reaction time (t = 0) and at time t, respectively, are shown in Figure 4a.The activity of the three TiO 2 -Au-C samples is appreciably higher than the one of TiO 2 , TiO 2 @C, and TiO 2 -Au samples. This photodegradation reaction kinetics follows a first-order rate law, [17][18][19][20][21] as shown by a highly linear ln(C 0 /C) versus t plot (R 2 > 0.992, Figure 4b) with the slope corresponding to the reaction rate constant k. The TiO 2 @C-Au@C sample has a photocatalytic activity (k = 9.37 × 10 −3 min −1 ) which is ≈13 times higher than TiO 2 NBs (k = 6.81 × 10 −4 min −1 ) and ≈5 times higher than TiO 2 @C (k = 1.87 × 10 −3 min −1 ). These results suggest that the combination of Au NPs and graphene-like carbon coating on TiO 2 surface introduces a strong synergistic effect for catalysis under visible light radiation as their k values are far greater than the sum of the individual contributions from TiO 2 @C and TiO 2 -Au samples.…”

An In Situ Polymerization‐Encapsulation Approach to Prepare TiO₂–Graphite Carbon–Au Photocatalysts for Efficient Photocatalysis

“…As illustrated in Scheme , the reference plasmonic photocatalyst consists of Au NPs randomly deposited at the surface of TiO 2 NBs (structure I, Figure S3, Supporting Information). Various methods have been developed to synthesize TiO 2 –C hybrids, e.g., hydrothermal carbonization (HTC) of biomass and ultraviolet (UV) light/HTC reduction of graphene oxide . However, these approaches usually do not allow for facile colocalization of both C and Au.…”

“…Surprisingly, depollution tests and photoelectrochemical cell (PEC) tests and incident photo to current efficient (IPCE) results under visible light (λ > 420 nm) point toward an entirely different conclusion. The photodegradation of methylene blue (MB) as test pollutant was used to assess the catalytic activity of the TiO 2 –Au–C nanostructures under visible light ( Figure ), which also has been widely used for the assessment of the catalytic activity of semiconductor photocatalyst . The plots of C / C 0 versus time ( t ), where C 0 and C are the concentrations of MO at initial reaction time ( t = 0) and at time t , respectively, are shown in Figure a.The activity of the three TiO 2 –Au–C samples is appreciably higher than the one of TiO 2 , TiO 2 @C, and TiO 2 –Au samples.…”

“…The photodegradation of methylene blue (MB) as test pollutant was used to assess the catalytic activity of the TiO 2 -Au-C nanostructures under visible light (Figure 4), which also has been widely used for the assessment of the catalytic activity of semiconductor photocatalyst. [17][18][19][20] The plots of C/C 0 versus time (t), where C 0 and C are the concentrations of MO at initial reaction time (t = 0) and at time t, respectively, are shown in Figure 4a.The activity of the three TiO 2 -Au-C samples is appreciably higher than the one of TiO 2 , TiO 2 @C, and TiO 2 -Au samples. This photodegradation reaction kinetics follows a first-order rate law, [17][18][19][20][21] as shown by a highly linear ln(C 0 /C) versus t plot (R 2 > 0.992, Figure 4b) with the slope corresponding to the reaction rate constant k. The TiO 2 @C-Au@C sample has a photocatalytic activity (k = 9.37 × 10 −3 min −1 ) which is ≈13 times higher than TiO 2 NBs (k = 6.81 × 10 −4 min −1 ) and ≈5 times higher than TiO 2 @C (k = 1.87 × 10 −3 min −1 ).…”

“…[17][18][19][20] The plots of C/C 0 versus time (t), where C 0 and C are the concentrations of MO at initial reaction time (t = 0) and at time t, respectively, are shown in Figure 4a.The activity of the three TiO 2 -Au-C samples is appreciably higher than the one of TiO 2 , TiO 2 @C, and TiO 2 -Au samples. This photodegradation reaction kinetics follows a first-order rate law, [17][18][19][20][21] as shown by a highly linear ln(C 0 /C) versus t plot (R 2 > 0.992, Figure 4b) with the slope corresponding to the reaction rate constant k. The TiO 2 @C-Au@C sample has a photocatalytic activity (k = 9.37 × 10 −3 min −1 ) which is ≈13 times higher than TiO 2 NBs (k = 6.81 × 10 −4 min −1 ) and ≈5 times higher than TiO 2 @C (k = 1.87 × 10 −3 min −1 ). These results suggest that the combination of Au NPs and graphene-like carbon coating on TiO 2 surface introduces a strong synergistic effect for catalysis under visible light radiation as their k values are far greater than the sum of the individual contributions from TiO 2 @C and TiO 2 -Au samples.…”

An In Situ Polymerization‐Encapsulation Approach to Prepare TiO₂–Graphite Carbon–Au Photocatalysts for Efficient Photocatalysis

“…En esta se observan las bandas correspondientes a los bordes Ti-OH, que se encuentran en el rango entre 3391 -3438 cm -1 y corresponden a estiramientos simétricos y asimétricos del grupo hidroxilo [20,21]. Además, se observa una banda amplia alrededor de 3400 cm -1 y un pico en 1640 cm -1 , que han sido reportados como agua adsorbida en la superficie, [22]. Finalmente, se encuentra en el espectro una banda de absorción débil en 2300 -2400 cm -1 correspondiente al enlace Ti-O del dióxido de titanio [21].…”

Evaluación de un reactor para la degradación fotocatalítica de glifosato empleando un catalizador de TiO2-Mn

3D Printing Conductive Composites with Poly(ionic liquid) as a Noncovalent Intermedia to Fabricate Carbon Circuits