The effect of microbes and dissolved oxygen concentration on inorganic and organic substances elimination in a climate changing environment: The aerobic bioreactor

Q2 Environmental Science
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Abstract

Microbes and dissolved oxygen (DO) concentration are the drivers in the wastewater treatment plant, aerobic bioreactor for the oxidation and decomposition of inorganic and organic substances. Due to global warming, surface and freshwater temperatures are increasing at an average of 1.08 °C. The rising climate temperatures suppress DO which threatens the availability of oxygen for respiration and survival of microbes, risking poor effluent being discharged into the environment. This study aimed to analyze the effect of microbes and DO concentration simultaneously on the elimination of inorganic and organic substances in a climate-changing environment. The results showed that biomass, COD (-0.578⁎⁎), and ammonia (-0.700⁎⁎) produced a negative relation while DO, ammonia (-0.214⁎⁎), and COD (-0.250⁎⁎) produced a negative relation. Although rising climate temperatures suppress DO, microbes strived under these conditions resulting in an effective aerobic bioreactor. Rising climate temperature (32.5 °C) produced the highest biomass (6.51 g/L), COD (145 mg/L), and ammonia (14.5 mg/L) elimination at the lowest DO (3.81 mg/L) concentration. Whereas normal operating temperature produced the lowest biomass (2.289 g/L), COD (94 mg/L), and ammonia (4.5 mg/L) elimination at the highest DO (4.83 mg/L) concentration. In addition, rising climate temperatures produced the highest COD (72.5 mg/L) and ammonia (7.25 mg/L) elimination rate compared with normal operating temperatures that produced the lowest COD (47 mg/L) and ammonia (2.25 mg/L) elimination rate. Therefore, the rising climate temperatures will not affect the microbes and DO concentration during the elimination of inorganic and organic substances, but rather enhance the performance of the aerobic bioreactor.
微生物和溶解氧浓度对气候变化环境中无机物和有机物消除的影响:好氧生物反应器
微生物和溶解氧(DO)浓度是污水处理厂、好氧生物反应器氧化和分解无机物和有机物的驱动力。由于全球变暖,地表和淡水温度平均上升了 1.08 °C。气候温度的升高抑制了溶解氧,从而威胁到微生物呼吸和生存所需的氧气供应,有可能导致劣质污水排放到环境中。本研究旨在分析在气候变化的环境中,微生物和溶解氧浓度同时对无机物和有机物消除的影响。结果表明,生物量、化学需氧量(-0.578⁎⁎)和氨氮(-0.700⁎⁎)呈负相关,而溶解氧、氨氮(-0.214⁎⁎)和化学需氧量(-0.250⁎⁎)呈负相关。虽然气温升高抑制了溶解氧,但微生物在这些条件下仍在努力生长,从而形成了有效的好氧生物反应器。气候温度升高(32.5 °C)产生的生物量(6.51 克/升)、化学需氧量(145 毫克/升)和氨氮(14.5 毫克/升)消除量最高,而溶解氧(3.81 毫克/升)浓度最低。而正常工作温度在最高溶解氧(4.83 毫克/升)浓度下产生的生物量(2.289 克/升)、化学需氧量(94 毫克/升)和氨氮(4.5 毫克/升)去除率最低。此外,气候温度升高产生的化学需氧量(72.5 毫克/升)和氨氮(7.25 毫克/升)消除率最高,而正常工作温度产生的化学需氧量(47 毫克/升)和氨氮(2.25 毫克/升)消除率最低。因此,在消除无机和有机物质的过程中,气候温度升高不会影响微生物和溶解氧浓度,反而会提高好氧生物反应器的性能。
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来源期刊
Environmental Challenges
Environmental Challenges Environmental Science-Environmental Engineering
CiteScore
8.00
自引率
0.00%
发文量
249
审稿时长
8 weeks
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