posted on 2021-02-03, 20:07authored byScott E. Crawford, James E. Ellis, Paul R. Ohodnicki, John P. Baltrus
Rare
earth elements (REEs) are critical to numerous technologies;
however, a combination of increasing demand, environmental concerns,
and monopolistic marketplace conditions has spurred interest in boosting
the domestic REE production from sources such as coal utilization
byproducts. The economic viability of this approach requires rapid,
inexpensive, and sensitive analytical techniques capable of characterizing
the REE content during resource exploration and downstream REE processing
(e.g., analyzing REE separation, concentration, and purification production
steps). Luminescence-based sensors are attractive because many REEs
may be sensitized to produce element-specific emission. Hence, a single
material may simultaneously detect and distinguish multiple REEs.
Metal–organic frameworks (MOFs) can sensitize multiple REEs,
but their viability has been hindered by sensitivity and selectivity
challenges. Understanding how the MOF structure impacts the REE sensing
efficacy is critical to the rational design of new sensors. Here,
we evaluate the sensing performance of seven different anionic zinc-adeninate
MOFs with different organic linkers and/or structures for the visible-emitting
REEs Tb, Dy, Sm, and Eu. The choice of a linker determines which REEs
are sensitized and significantly influences their sensitivity and
selectivity against competing species (here, Fe(II) and HCl). For
a given linker, structural changes to the MOF can further fine-tune
the performance. The MOFs produce some of the lowest detection limits
(sub-10 ppb for Tb) reported for the aqueous sensitization-based REE
detection. Importantly, the most selective MOFs demonstrated the ability
to sensitize the REE signal at sub-ppm levels in a REE-spiked acid
mine drainage matrix, highlighting their potential for use in real-world
sensing applications.