690 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
REFERENCES
[1] Wu, J., Yang, B., Martin, R., et al., 2024. Anisotropic
adsorption of xanthate species on molybdenite faces
and edges and its implication on the flotation of
molybdenite fines. Minerals Engineering 207: 108571.
[2] Zheng, Y., Zhang, Y., Wang, Y., et al., 2024. Enhanced
photocatalytic degradation of xanthate over carbon
quantum dots embedded on BiOI nanosheets under
visible light. Optical Materials 148: 114890.
[3] Yuan, J., Ding, Z., Li, J., et al., 2024. An innovative
method to degrade xanthate from flotation tailings
wastewater in acid mine drainage (AMD) system:
Performance, degradation mechanism and pathways.
Journal of Environmental Management 349: 119395.
[4] Kirk, C.H., Wang, P., Chong, C.Y.D., et al. (2024)
TiO2 photocatalytic ceramic membranes for water
and wastewater treatment: Technical readiness
and pathway ahead. Journal of Materials Science &
Technology 183: 152–164.
[5] Rengifo-Herrera, J.A. and Pulgarin, C. 2023 Why
five decades of massive research on heterogeneous
photocatalysis, especially on TiO2, has not yet driven
to water disinfection and detoxification applications?
Critical review of drawbacks and challenges. Chemical
Engineering Journal 477: 146875.
[6] Dziewiątka, K., Matusik, J., Trenczek-Zając, A., et al.,
2023. TiO2-loaded nanotubular kaolin group miner-
als: The effect of mineral support on photodegrada-
tion of dyes as model pollutants. Applied Clay Science
245: 107123.
Figure 11. Effect of different scavengers on the degradation efficiency of SIPX in the presence of the composite photocatalysts
(a) TC (b) ATC (c) MTC (d) BTC
REFERENCES
[1] Wu, J., Yang, B., Martin, R., et al., 2024. Anisotropic
adsorption of xanthate species on molybdenite faces
and edges and its implication on the flotation of
molybdenite fines. Minerals Engineering 207: 108571.
[2] Zheng, Y., Zhang, Y., Wang, Y., et al., 2024. Enhanced
photocatalytic degradation of xanthate over carbon
quantum dots embedded on BiOI nanosheets under
visible light. Optical Materials 148: 114890.
[3] Yuan, J., Ding, Z., Li, J., et al., 2024. An innovative
method to degrade xanthate from flotation tailings
wastewater in acid mine drainage (AMD) system:
Performance, degradation mechanism and pathways.
Journal of Environmental Management 349: 119395.
[4] Kirk, C.H., Wang, P., Chong, C.Y.D., et al. (2024)
TiO2 photocatalytic ceramic membranes for water
and wastewater treatment: Technical readiness
and pathway ahead. Journal of Materials Science &
Technology 183: 152–164.
[5] Rengifo-Herrera, J.A. and Pulgarin, C. 2023 Why
five decades of massive research on heterogeneous
photocatalysis, especially on TiO2, has not yet driven
to water disinfection and detoxification applications?
Critical review of drawbacks and challenges. Chemical
Engineering Journal 477: 146875.
[6] Dziewiątka, K., Matusik, J., Trenczek-Zając, A., et al.,
2023. TiO2-loaded nanotubular kaolin group miner-
als: The effect of mineral support on photodegrada-
tion of dyes as model pollutants. Applied Clay Science
245: 107123.
Figure 11. Effect of different scavengers on the degradation efficiency of SIPX in the presence of the composite photocatalysts
(a) TC (b) ATC (c) MTC (d) BTC