关键词: 基于亚硝化的全程自养脱氮(CANON), 潮汐流人工湿地(TFCW), 厌氧氨氧化(ANAMMOX), 脱氮, 温度

Abstract: A selfdeveloped binder was used for the solidification of construction refuse piles and whole soil matrix, and a technology of this solidification combining with grassplanting was adopted to ecologically protect the rural riverbanks at Tianshan Village of Shanghai. This technology and other ecological engineering techniques were also employed to reconstruct the ecological environment of a sewage pond at the Village. The results showed that the solidified piles had an anticompression strength of up to 73 MPa, with good hydraulic permeability, fast hardening rate, and low drying shrinkage, which met the requirements for ecological safety. The solidified stakes could be used at a low temperature of above -18 ℃ with addition of certain antifreezing agents. The riverbank underpinned with the solidified stakes had higher anticompressive strength, higher ability of antisoil erosion, and better hydraulic permeability; and its soil had the similar moisture content to bare riverbank soil, with no detrimental effects on the root growth of planted grass. After soil solidification, the shearing strength of the riverbank increased by 50 times, and its soil loss was only 5% of the bare riverbank. In the first 10 days after adopting this technology, parts of Cynodon dactylon roots on the surface of solidified soil matrix began to extend into soil; after one month, 60% of the roots penetrated into deeper soil layer; and 11 months later, the grass roots completely grew in-depth in the soil. The combination of our solidification technique with vegetation reconstruction satisfied the requirements of both stabilizing riverbank and improving riparian habitat.

Key words: completely autotrophic nitrogen removal over nitrite (CANON), tidal flow constructed wetland (TFCW), nitrogen removal, anaerobic ammonia oxidation (ANAMMOX), temperature