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uranium fuel waste treatment and detection in an aque-
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Selected bond lengths (Å) and angles (deg) for CPs‐(1–4)
are listed in Table S1‐S4. Hydrogen bond lengths (Å)
and angles (°) for the CPs‐(1–4) are listed in Table S5.
Table S6 shows the attribution of IR (cm−1) for ligand
H3TIBTC and CPs‐(1–4). And the characteristics data of
UV–Vis spectra is listed in Table S7. Infrared spectra of
the ligand H3TIBTC and CPs‐(1–4) are shown in Figure
S1. Solid dichroism of CP‐1 and its isomeric crystal coor-
dination polymers are shown in Figure S2. UV–vis spec-
trum of the ligand H3TIBTC and CP‐1 is shown in
Figure S3. The TG curves of the CPs‐(1–4) are shown in
Figure S4. PXRD patterns for the CPs‐(1–4) are shown in
Figure S5. The fluorescence lifetime of the CP‐1 is shown
in Figure S6. The EDAX spectra of the CP‐1 before and
after detection are shown in Figure S7. The SEM micro-
graphs of the CP‐1 before and after detection are shown
in Figure S8. CIF files have also been deposited at the
Cambridge Crystallographic Database Centre and may
CCDC for the CP‐1: 1554191; CP‐2: 1554192; CP‐3:
1554195; CP‐4: 1554193.
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ACKNOWLEDGEMENTS
This work was supported by the grants of the National
Natural Science Foundation of China (No. 21571091),
Commonweal Research Foundation of Liaoning province
in China (No. 20170055), and Guangxi Key Laboratory of
Information Materials, Guilin University of Electronic
Technology, P.R. China (Project No. 151002‐K) for finan-
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