The development of high-performance semiconductor photo-catalysts using solar energy has become a hot topic, which is crucial for a sustainable future. However, construction of a nontoxic and efficient catalyst still remains an enormous challenge. Here, we uncover a simple hydrothermal recalcination method to prepare a novel potassium (K)-doped porous ultrathin g-C3N4 (denoted as KMCN) photocatalyst with efficient catalytic performance, eco-friendly characteristics, and excellent stability. The obtained KMCN nanosheets were applied to the photodegradation of tetracycline (TC) under different reaction condition to simulate practical wastewater treatment. It was found, that the porous structure and K+ addition of g-C3N4 enhanced the pore size and specific surface area, and they increased the photoabsorption region and activity sites. The optical properties of KMCN nanosheets were systematically characterized by PL, UV-DRS, etc. The results revealed that the KMCN(0.05) sample possessed a narrowed band gap, lower recombination of photogenerated charges, and higher electron and hole transfer efficiency. Benefiting from these advantages, KMCN(0.05) photocatalysts demonstrated excellent photocatalytic performance for TC degradation (85.13%), which was approximately a 2.88-fold and 1.40-fold increase compared to bare g-C3N4 (29.60%) and porous ultrathin g-C3N4 (60.84%), respectively. These results suggest a reasonable way for the design of economic and high-efficiency photocatalysis.

• 出版日期2018-11-5
• 单位中南大学; 湖南大学