<p>Partial denitrification granules (PDG) offer a novel approach to supplying nitrite (NO<sub>2</sub><sup>−</sup>) for anammox. Shear stress (τ) induced by mechanical stirring has been recognized as an effective operational strategy for enhancing mass transfer in continuous-flow PDG systems with minimal gas production. However, the effects of shear stress intensity on nitrite (NO<sub>2</sub><sup>−</sup>) accumulation, granular structure, and microbial succession remains unclear. This study established two continuously up-flow PDG systems to assess the influence of low-strength τ (0.2–0.5 Pa) and high-strength τ (1.2–1.4 Pa) on PDG performance under dynamic nitrate (NO<sub>3</sub><sup>−</sup>) loading rates (NLR). Results indicated that low-strength τ promoted the formation of 1–2 mm granules, mitigating the washout of flocs and smaller granules, and sustaining a stable nitrite production rate (NPR) of 7.7 kg N/m<sup>3</sup>·d) at an NLR as high as 11.7 kg N/(m<sup>3</sup>·d). In contrast, high-strength τ caused particle fragmentation and reaggregation, accompanied by the washout of sludge containing PD bacteria, leading to a lower NPR of 0.2 kg N/(m<sup>3</sup>·d). Metagenomic analysis revealed that low-strength τ enhanced nitrogen-carbon metabolism, with <i>Thauera.</i>sp. and <i>Thauera</i>_phenylacetica synergistically driving NO<sub>2</sub><sup>−</sup> accumulation. Although high-strength τ promoted the enrichment of <i>Thauera</i> (∼70%), <i>Thauera.</i>sp. decreased its contribution to <i>napA</i> and improved to <i>nirK</i>, whereas <i>Thauera</i>_phenylacetica reduced its contribution to <i>napA</i>, thereby constraining NO<sub>2</sub><sup>−</sup> accumulation. These findings provide critical insights into optimizing shear conditions for PDG and enhance the understanding of the metagenomic mechanisms of PD.</p>

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Unraveling mechanisms of mechanical shear stress-regulated high nitrite production in denitrification: granular structure and metagenomic evidence

  • Jiarui Fan,
  • Shenbin Cao,
  • Xiangchen Li,
  • Yongzhen Peng,
  • Rui Du

摘要

Partial denitrification granules (PDG) offer a novel approach to supplying nitrite (NO2) for anammox. Shear stress (τ) induced by mechanical stirring has been recognized as an effective operational strategy for enhancing mass transfer in continuous-flow PDG systems with minimal gas production. However, the effects of shear stress intensity on nitrite (NO2) accumulation, granular structure, and microbial succession remains unclear. This study established two continuously up-flow PDG systems to assess the influence of low-strength τ (0.2–0.5 Pa) and high-strength τ (1.2–1.4 Pa) on PDG performance under dynamic nitrate (NO3) loading rates (NLR). Results indicated that low-strength τ promoted the formation of 1–2 mm granules, mitigating the washout of flocs and smaller granules, and sustaining a stable nitrite production rate (NPR) of 7.7 kg N/m3·d) at an NLR as high as 11.7 kg N/(m3·d). In contrast, high-strength τ caused particle fragmentation and reaggregation, accompanied by the washout of sludge containing PD bacteria, leading to a lower NPR of 0.2 kg N/(m3·d). Metagenomic analysis revealed that low-strength τ enhanced nitrogen-carbon metabolism, with Thauera.sp. and Thauera_phenylacetica synergistically driving NO2 accumulation. Although high-strength τ promoted the enrichment of Thauera (∼70%), Thauera.sp. decreased its contribution to napA and improved to nirK, whereas Thauera_phenylacetica reduced its contribution to napA, thereby constraining NO2 accumulation. These findings provide critical insights into optimizing shear conditions for PDG and enhance the understanding of the metagenomic mechanisms of PD.