Synthesis and characterization of Cu-doped polymeric carbon nitride

“…The band at 891░cm 1 occurs due to deformation of the polymer skeleton. The peak at 805░cm 1 is associated with the deformation of the tri-s-triazine ring (14,9). The IR spectra of CN-Cu and CN-Fe did not show any evident effect of either copper or iron on the characteristic bands, and are similar to the spectrum of CN (9).…”

“…The polymeric carbon nitride characteristic bands were reported by Lin et al (14) and Dante et al (9). The interaction of the N-H bond generates the bands between 3250░cm 1 and 3083░cm 1 .…”

“…The structure of graphite carbon nitride allows it to interact with ions and polar species, so it is possible to dope this material with fluorine, boron (6), iron (7), copper (8,9), manganese (10), nickel, or cobalt (11). The doping of carbon nitride enhances either the conversion or selectivity of the catalyst (9) by affecting its morphology, its response to visible light and its photocatalytic activity (12).…”

Photocatalytic activity of a new composite material of Fe (III) oxide nanoparticles wrapped by a matrix of polymeric carbon nitride and amorphous carbon

“…The band at 891░cm 1 occurs due to deformation of the polymer skeleton. The peak at 805░cm 1 is associated with the deformation of the tri-s-triazine ring (14,9). The IR spectra of CN-Cu and CN-Fe did not show any evident effect of either copper or iron on the characteristic bands, and are similar to the spectrum of CN (9).…”

“…The polymeric carbon nitride characteristic bands were reported by Lin et al (14) and Dante et al (9). The interaction of the N-H bond generates the bands between 3250░cm 1 and 3083░cm 1 .…”

“…The structure of graphite carbon nitride allows it to interact with ions and polar species, so it is possible to dope this material with fluorine, boron (6), iron (7), copper (8,9), manganese (10), nickel, or cobalt (11). The doping of carbon nitride enhances either the conversion or selectivity of the catalyst (9) by affecting its morphology, its response to visible light and its photocatalytic activity (12).…”

Photocatalytic activity of a new composite material of Fe (III) oxide nanoparticles wrapped by a matrix of polymeric carbon nitride and amorphous carbon

“…The FTIR analysis correlates to previous reports on g-C3N4. 32,[45][46][47][48][49][50][51][52] The finger printing from 807 to 1650 cm -1 and from 3100 to 3500 cm -1 by FTIR analysis demonstrates that the materials synthesized are C3N4 structure type ( Figure 2). The peaks at 807 cm −1 are the characteristic breathing mode of the s-triazine ring system.…”

“…Essentially, carbon has two unique bonding configurations (C1, C2) whilst nitrogen adopts four unique configurations (from N1 to N4) in the carbon nitride structure. 45 This causes a splitting in the XPS signal for each configuration allowing investigation of structure. Both elements C and N, in the C3N4 graphitic structure, generate the signal due to the π to π* transition (shake-up) at around 293.8 eV and 404.2 eV respectively, as reported in Table 2.…”

An Investigation into the Stability of Graphitic C₃N₄ as a Photocatalyst for CO₂ Reduction

Insights into photochemical stability of graphitic carbon nitride-based photocatalysts in water treatment