In high-rise buildings,secondary water supply systems(SWSSs)are pivotal yet provide a conducive milieu for microbial proliferation due to intermittent flow,low disinfectant residual,and high specific pipe-surface area...In high-rise buildings,secondary water supply systems(SWSSs)are pivotal yet provide a conducive milieu for microbial proliferation due to intermittent flow,low disinfectant residual,and high specific pipe-surface area,raising concerns about tap water quality deterioration.Despite their ubiquity,a comprehensive understanding of bacterial community dynamics within SWSSs remains elusive.Here we show how intrinsic SWSS variables critically shape the tap water microbiome at distal ends.In an office setting,distinct from residential complexes,the diversity in piping materials instigates a noticeable bacterial community shift,exemplified by a transition from a-Proteobacteria to g-Proteobacteria dominance,alongside an upsurge in bacterial diversity and microbial propagation potential.Extended water retention within SWSSs invariably escalates microbial regrowth propensities and modulates bacterial consortia,yet secondary disinfection emerges as a robust strategy for preserving water quality integrity.Additionally,the regularity of water usage modulates proximal flow dynamics,thereby influencing tap water's microbial landscape.Insights garnered from this investigation lay the groundwork for devising effective interventions aimed at safeguarding microbiological standards at the consumer's endpoint.展开更多
The Lingshan Island scientific drill confirms that two episodes(Laiyang period and Qingshan period) of rifting developed in the central Sulu orogenic belt(SOB) in Late Mesozoic. With a set of methods including fieldwo...The Lingshan Island scientific drill confirms that two episodes(Laiyang period and Qingshan period) of rifting developed in the central Sulu orogenic belt(SOB) in Late Mesozoic. With a set of methods including fieldwork, drilling, core logging, zircon U-Pb dating and whole rock geochemistry applied, the age, the depositional sequence and the deep dynamic mechanisms of rift evolution were unraveled. The stratigraphic sequence of the Laiyang-Qingshan Groups on Lingshan Island was composed of two different rifting sequences:(1) Laiyang Group(147–125 Ma), which consists of deep-water gravity flow deposits with interlayers of intermediate volcanic rocks;and(2) Lower Qingshan Group(125–119 Ma), which unconformably overlies the former sequence and contains subaerial volcanic deposits and terrestrial deposits. The tectonic environment changed during the evolution of these two episodes of rifting: the rift was in a NNW-SSE extensional environment in the Laiyang period and showed the typical passive rifting character that “lithospheric extension and rifting preceded volcanism”. The passive rifting period was ended by a short WNW-ESE compression at about 125 Ma. After that, the tectonic environment transferred to a strong NW-SE extensional environment and the rifting evolved into a volcanic arc basin in the Qingshan period. The igneous rocks are shoshonitic to high-K calc-alkaline trachyandesites to trachytes with a few intercalated lamprophyres and a rhyolite.The geochemical characteristics of the igneous rocks indicate that they are mantle-derived melts with a metasomatized mantle source and/or crustal contamination. In addition, an increased thinning of the lithosphere happened during the rifting episodes.The low-angle subduction of the Paleo-Pacific plate in the Jurassic weakened the thickened SOB lithospheric mantle. The rollback of the subducting plate started in late Jurassic to early Cretaceous, and the SOB lithospheric mantle was delaminated synchronously because of the gravity collapse. Thus, this caused passive rifting in the Laiyang period. Thereafter, the rollback and trench retreat of the high-angle subducting Paleo-Pacific plate would have achieved its climax, resulting in the strong regional extension. Passive rifting was ended by the crustal uplift caused by asthenospheric upwelling beneath the rift. The lower crust was heated by the upwelling asthenosphere and partially melted to form felsic melts, which were emplaced upwards and erupted explosively. The rift evolved into a volcanic arc basin in the Qingshan period and showed some characteristics of active rifting. Above all, a passive rifting in the Laiyang period and a volcanic arc basin in the Qingshan period developed successively in the Lingshan Island area(the central SOB). This records the transfer of the study area from the Paleo-Tethys tectonic domain to the circum-Pacific tectonic domain. The delamination of SOB lithospheric mantle and the upwelling of asthenospheric material were the deep dynamic mechanisms driving the development and evolution of two rift episodes. Additionally, the rift development was controlled remotely by the subduction of the Paleo-Pacific plate.展开更多
基金supported by the National Natural Science Foundation of China[No.52009060]the Open Research Fund Program of the State Key Laboratory of Hydroscience and Engineering[sklhse-2023-A-03].
文摘In high-rise buildings,secondary water supply systems(SWSSs)are pivotal yet provide a conducive milieu for microbial proliferation due to intermittent flow,low disinfectant residual,and high specific pipe-surface area,raising concerns about tap water quality deterioration.Despite their ubiquity,a comprehensive understanding of bacterial community dynamics within SWSSs remains elusive.Here we show how intrinsic SWSS variables critically shape the tap water microbiome at distal ends.In an office setting,distinct from residential complexes,the diversity in piping materials instigates a noticeable bacterial community shift,exemplified by a transition from a-Proteobacteria to g-Proteobacteria dominance,alongside an upsurge in bacterial diversity and microbial propagation potential.Extended water retention within SWSSs invariably escalates microbial regrowth propensities and modulates bacterial consortia,yet secondary disinfection emerges as a robust strategy for preserving water quality integrity.Additionally,the regularity of water usage modulates proximal flow dynamics,thereby influencing tap water's microbial landscape.Insights garnered from this investigation lay the groundwork for devising effective interventions aimed at safeguarding microbiological standards at the consumer's endpoint.
基金supported by the Key R&D Plan of Shandong Province (Grant No. 2017CXGC1608)the Project of Department of Science and Technology of Sinopec (Grant No. P20028)+1 种基金the Shandong Natural Science Foundation Youth Fund Project (Grant No. ZR2020QD026)the Fundamental Research Funds for the Central Universities (Grant Nos. 18CX06019A, 19CX05004A)。
文摘The Lingshan Island scientific drill confirms that two episodes(Laiyang period and Qingshan period) of rifting developed in the central Sulu orogenic belt(SOB) in Late Mesozoic. With a set of methods including fieldwork, drilling, core logging, zircon U-Pb dating and whole rock geochemistry applied, the age, the depositional sequence and the deep dynamic mechanisms of rift evolution were unraveled. The stratigraphic sequence of the Laiyang-Qingshan Groups on Lingshan Island was composed of two different rifting sequences:(1) Laiyang Group(147–125 Ma), which consists of deep-water gravity flow deposits with interlayers of intermediate volcanic rocks;and(2) Lower Qingshan Group(125–119 Ma), which unconformably overlies the former sequence and contains subaerial volcanic deposits and terrestrial deposits. The tectonic environment changed during the evolution of these two episodes of rifting: the rift was in a NNW-SSE extensional environment in the Laiyang period and showed the typical passive rifting character that “lithospheric extension and rifting preceded volcanism”. The passive rifting period was ended by a short WNW-ESE compression at about 125 Ma. After that, the tectonic environment transferred to a strong NW-SE extensional environment and the rifting evolved into a volcanic arc basin in the Qingshan period. The igneous rocks are shoshonitic to high-K calc-alkaline trachyandesites to trachytes with a few intercalated lamprophyres and a rhyolite.The geochemical characteristics of the igneous rocks indicate that they are mantle-derived melts with a metasomatized mantle source and/or crustal contamination. In addition, an increased thinning of the lithosphere happened during the rifting episodes.The low-angle subduction of the Paleo-Pacific plate in the Jurassic weakened the thickened SOB lithospheric mantle. The rollback of the subducting plate started in late Jurassic to early Cretaceous, and the SOB lithospheric mantle was delaminated synchronously because of the gravity collapse. Thus, this caused passive rifting in the Laiyang period. Thereafter, the rollback and trench retreat of the high-angle subducting Paleo-Pacific plate would have achieved its climax, resulting in the strong regional extension. Passive rifting was ended by the crustal uplift caused by asthenospheric upwelling beneath the rift. The lower crust was heated by the upwelling asthenosphere and partially melted to form felsic melts, which were emplaced upwards and erupted explosively. The rift evolved into a volcanic arc basin in the Qingshan period and showed some characteristics of active rifting. Above all, a passive rifting in the Laiyang period and a volcanic arc basin in the Qingshan period developed successively in the Lingshan Island area(the central SOB). This records the transfer of the study area from the Paleo-Tethys tectonic domain to the circum-Pacific tectonic domain. The delamination of SOB lithospheric mantle and the upwelling of asthenospheric material were the deep dynamic mechanisms driving the development and evolution of two rift episodes. Additionally, the rift development was controlled remotely by the subduction of the Paleo-Pacific plate.
