Innovative receiving phase for Chemcatcher® passive sampler for phosphorus in the water environment: Calibration of sampling rate by water temperature and pH
•New receiving phase for PO4-P developed for Chemcatcher® passive sampler.•Receiving phase showed sufficient capacity and good selectivity for PO4-P uptake.•Sampling rate for PO4-P calibrated by water temperature and pH.•Sampler performance investigated at a wastewater treatment plant and in lakes.•...
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Veröffentlicht in: | Water research (Oxford) 2023-09, Vol.243, p.120412-120412, Article 120412 |
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Sprache: | eng |
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Zusammenfassung: | •New receiving phase for PO4-P developed for Chemcatcher® passive sampler.•Receiving phase showed sufficient capacity and good selectivity for PO4-P uptake.•Sampling rate for PO4-P calibrated by water temperature and pH.•Sampler performance investigated at a wastewater treatment plant and in lakes.•Passive sampling can estimate PO4-P concentrations below 10 μg/L.
Passive sampling is a technique for monitoring orthophosphate (PO4-P) in the water environment. Compared with traditional grab sampling followed by PO4-P quantification, kinetic-type passive samplers such as Chemcatcher® express representative concentrations of PO4-P as time-weighted average concentrations (CTWA). They can also potentially evaluate much lower PO4-P concentrations, but the available receiving phases of Chemcatcher® used for PO4-P were extremely limited. We developed a new receiving phase, the PSfZS sheet, comprising a zirconium sulfate–surfactant micelle mesostructure and polysulfone matrix. We examined its performance in terms of PO4-P sorption characteristics, PO4-P selectivity, and PO4-P sampling rate (Rs). Its capacity was adequate (12.0 μg-P/cm2) and selectivity for PO4-P uptake was good. The Rs for PO4-P increased with increasing water temperature (8.1–29.1 °C) and decreasing pH (4.1–9.7) in a laboratory calibration, and ranged from 5.27 × 10−2 L/d to 1.66 × 10−1 L/d. We placed the samplers in a municipal wastewater treatment plant, a shallow eutrophic lake, and an oligotrophic caldera lake. The Rs in the deployment sites was calibrated by monitored water temperature and pH. The estimated CTWA of PO4-P in the municipal wastewater treatment plant was similar to the averaged concentration of soluble reactive phosphorus determined by multiple grab samplings. In the lake deployments, we found that the new sampler can quantify CTWA values of PO4-P below 10 μg/L, and thus it provides more technical monitoring options and contributes to the conservation and management of the water environment.
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ISSN: | 0043-1354 1879-2448 |
DOI: | 10.1016/j.watres.2023.120412 |