Benign Hydrothermal Synthesis of N‐doped TiO₂ and TiO₂‐CoS Nanostructures for Enhanced Visible‐Light Driven Photocatalytic Activity

Abstract: An efficient utilization of broad‐spectrum solar light to harvest energy for photocatalysis in a sustainable manner remains a critical challenge in the area of environmental remediation for a long time. To address this challenge, N‐doped TiO2‐CoS nanocomposite was successfully synthesized for the first‐time via a benign hydrothermal treatment adopting combination of doping, dimensional diversity and coupling strategies. The phase composition, surface morphology, nitrogen adsorption‐desorption analysis and phot… Show more

“…In order to overcome this drawback, many researches have been focused on modification of TiO 2 , such as the doping with metals (like Au, Pt, Fe, Mn, W, Cu or Cr) [7][8][9][10][11][12][13][14][15][16] or nonmetals (like P, F, C, S or N), [7][8][9][10]17] sensitization by other semiconductors (like g-CN, ZnO or Fe 3 O 4 ) [7][8][9][10] or organic dyes (like porphyrin, anthocyanin, curcumin or phthalocyanine). [18][19][20][21][22][23] Among them, organic dye sensitization has shown excellent capability compared with other methods in TiO 2 extent the ultra-violet light. [18][19][20][21][22][23] Corroles are 18π aromatic macrocyclic molecules.…”

“…[18][19][20][21][22][23] Among them, organic dye sensitization has shown excellent capability compared with other methods in TiO 2 extent the ultra-violet light. [18][19][20][21][22][23] Corroles are 18π aromatic macrocyclic molecules. [24][25][26][27][28] Due to the fascinating structure, corroles and their analogs including free base and metallated corroles can absorb intensively in the visible range of light, precisely in 400-450 nm and 500-700 nm, which represents the major constituents of the solar light.…”

“…However, the wide energy band gap makes TiO 2 suffer from its limited visible light absorption (less than 387 nm). In order to overcome this drawback, many researches have been focused on modification of TiO 2 , such as the doping with metals (like Au, Pt, Fe, Mn, W, Cu or Cr) [7–16] or nonmetals (like P, F, C, S or N), [7–10,17] sensitization by other semiconductors (like g‐CN, ZnO or Fe 3 O 4 ) [7–10] or organic dyes (like porphyrin, anthocyanin, curcumin or phthalocyanine) [18–23] . Among them, organic dye sensitization has shown excellent capability compared with other methods in TiO 2 extent the ultra‐violet light [18–23] …”

Preparation and Photocatalytic Studies on Nanocomposites of 4‐Hydroxylphenyl‐Substituted Corrole/TiO₂ towards Methyl Orange Photodegradation

“…In order to overcome this drawback, many researches have been focused on modification of TiO 2 , such as the doping with metals (like Au, Pt, Fe, Mn, W, Cu or Cr) [7][8][9][10][11][12][13][14][15][16] or nonmetals (like P, F, C, S or N), [7][8][9][10]17] sensitization by other semiconductors (like g-CN, ZnO or Fe 3 O 4 ) [7][8][9][10] or organic dyes (like porphyrin, anthocyanin, curcumin or phthalocyanine). [18][19][20][21][22][23] Among them, organic dye sensitization has shown excellent capability compared with other methods in TiO 2 extent the ultra-violet light. [18][19][20][21][22][23] Corroles are 18π aromatic macrocyclic molecules.…”

“…[18][19][20][21][22][23] Among them, organic dye sensitization has shown excellent capability compared with other methods in TiO 2 extent the ultra-violet light. [18][19][20][21][22][23] Corroles are 18π aromatic macrocyclic molecules. [24][25][26][27][28] Due to the fascinating structure, corroles and their analogs including free base and metallated corroles can absorb intensively in the visible range of light, precisely in 400-450 nm and 500-700 nm, which represents the major constituents of the solar light.…”

“…However, the wide energy band gap makes TiO 2 suffer from its limited visible light absorption (less than 387 nm). In order to overcome this drawback, many researches have been focused on modification of TiO 2 , such as the doping with metals (like Au, Pt, Fe, Mn, W, Cu or Cr) [7–16] or nonmetals (like P, F, C, S or N), [7–10,17] sensitization by other semiconductors (like g‐CN, ZnO or Fe 3 O 4 ) [7–10] or organic dyes (like porphyrin, anthocyanin, curcumin or phthalocyanine) [18–23] . Among them, organic dye sensitization has shown excellent capability compared with other methods in TiO 2 extent the ultra‐violet light [18–23] …”

Preparation and Photocatalytic Studies on Nanocomposites of 4‐Hydroxylphenyl‐Substituted Corrole/TiO₂ towards Methyl Orange Photodegradation

“…Over the past decades, a large number of researchers have done a lot of work to enhance photocatalytic properties of TiO 2 , [14][15][16] such as fabricating mesoporous nanostructure, [17] doping of inorganic elements and addition of narrower band gap semiconductors (CoS, [18] CuO, [19] g-C 3 N 4 [20] etc. ).One of the promising strategies is to introduce noble metals into TiO 2 nanoparticles such as, Au, [21] Ag [22] and Pt.…”

Synthesis of Core‐Shell Au@TiO₂@C Nanoparticles and Their Photocatalytic Properties for the Degradation of Rhodamine B Under Simulated‐Solar Light

Role of TiO2-Based Photocatalysts in Waste Water Treatment