Table 2.
Summary of different synthetic strategies for MOF composites with ECL properties.
| MOF Composites | Ligands | Metal Source | Ref. |
|---|---|---|---|
| In situ synthesis | |||
| MIL-101(Al)–NH2 | NH2-BDC | AlCl3 | [46] |
| IRMOF-3 | NH2-BDC | Zn(NO3)2 | [47] |
| Ru(bpy)32+/NH2-UiO-66 | NH2-BDC | ZrCl4 | [48] |
| Fe(III)-MIL-88B-NH2 | NH2-BDC | FeCl3 | [49] |
| UiO-67 | BPDC | ZrCl4 | [50] |
| GSH-Au NCS@ZIF-8 | 2-MI | Zn(NO3)2 | [51] |
| Zinc Oxalate MOFs | Oxalic acid | Zn(NO3)2 | [52] |
| Post-synthesis modifications | |||
| Ru-MOF-5 NFs | PTA | Zn(NO3)2 | [53] |
| Cu/Co-MOF | 2-MI | Co(NO3)2, Cu(NO3)2 | [54] |
| HH-Ru-UiO66-NH2 | NH2-BDC | ZrCl4 | [55] |
| Co-Ni/MOF | 2-MI | Co(NO3)2, Ni (NO3)2 | [56] |
| AgNPs@Ru-MOF | NH2-BDC | ZrCl4 | [57] |
| g-C3N4@NH2-MIL-101 | NH2-BDC | FeCl3·6H2O | [58] |
| Zn-Bp-MOFs | H3BTC,4,4-dipyridyl | Zn(NO3)2 | [59] |
| Ru-PCN-777 | H3TATB | ZrOCl2 | [60] |
| Self-luminous MOFs | |||
| Eu-MOFs | 5-bop | EuCl3 | [61] |
| RuMOF NS | [Ru(H2dcbpy)3]Cl2 | Zn(NO3)2 | [62] |
| Eu-MOF | [Ru(H2dcbpy)3]Cl2 | Eu(NO3)3 | [63] |
| Zr-TCBPE-MOF | H4TCBPE | ZrCl4 | [64] |
| Hf-TCBPE | H4TCBPE | HfCl4 | [65] |
| Zr12-adb | H2adb | ZrCl4 | [66] |
| Tb-Cu-PA MOF | IPA | TbCl3, Cu(NO3)2 | [67] |
| Zn-PTC | PTC | Zn(CH3COO)2 | [68] |
| Ru@Zr12-BPDC | BPDC, H2dcbpy | ZrCl4 | [69] |
| Cu:Tb-MOF | IPA | TbCl3, Cu(NO3)2 | [70] |
| UMV-Ce-MOF | H3BTC | Ce(NO3)3 | [71] |
| PTP/Eu MOF | H3BTC | Eu(NO3)3 | [72] |
| Ce-TCPP-LMOF | TCPP | Ce(NO3)3 | [73] |
| Zn-MOF | Hcptpy | ZnSO4 | [74] |