posted on 2023-04-03, 14:13authored byWei Shi, Jinxing Ma, Fei Gao, Ruobin Dai, Xiao Su, Zhiwei Wang
Selective removal of trace, highly toxic arsenic from
water is
vital to ensure an adequate and safe drinking water supply for over
230 million people around the globe affected by arsenic contamination.
Here, we developed an Fe-based metal–organic framework (MOF)
with a ferrocene (Fc) redox-active bridge (termed Fe-MIL-88B-Fc) for
the highly selective removal of As(III) from water. At a cell voltage
of 1.2 V, Fe-MIL-88B-Fc can selectively separate and oxidize As(III)
into the less harmful As(V) state in the presence of a 100- to 1250-fold
excess of competing electrolyte, with an uptake capacity of >110
mg-As
g–1 adsorbent. The high affinity between the uncharged
As(III) and the μ3-O trimer (−36.55 kcal mol–1) in Fe-MIL-88B-Fc and the electron transfer between
As(III) and redox-active Fc+ synergistically govern the
selective capture and conversion of arsenic. The Fe-based MOF demonstrates
high selectivity and capacity to remediate arsenic-contaminated natural
water at a low energy cost (0.025 kWh m–3). This
study provides valuable guidance for the tailoring of effective and
robust electrodes, which can lead to a wider application of electrochemical
separation technologies.