2020
DOI: 10.1021/acsaem.0c00389
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Optimizing Solid-State Ligand Exchange for Colloidal Quantum Dot Optoelectronics: How Much Is Enough?

Abstract: Progress in chalcogenide and perovskite CQD optoelectronics has relied to a significant extent on solid-state ligand exchanges (SSEs): the replacement of initial insulating ligands with shorter conducting linkers on CQD surfaces. Herein we develop a mechanistic model of SSE employing 3-mercapto­propionic acid (MPA) and 1,2-ethanedithiol (EDT) as the linkers. The model suggests that optimal linker concentrations lead to efficient exchange, resulting in ca. 200–300 exchanged ligands per CQD, a 50% thickness redu… Show more

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Cited by 35 publications
(37 citation statements)
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“…LHP NC Film Treatments: Solid-state ligand exchange is an alternative strategy to adjust the ligand shell composition of the LHP NCs in films. [412,414,415] This type of ligand exchange is especially promising for LHP NCs which, due to the labile nature of the native OA and OAm ligands, could be affected by solubility and stability issues in a traditional solution-phase ligand exchange strategy. [412] In a solid-state ligand exchange, the new ligand is dispersed in an antisolvent, which is then dropped onto the surface of a NC film (Figure 12H).…”
Section: Ligand Modification In Nc Films For Led Device Improvementmentioning
confidence: 99%
See 1 more Smart Citation
“…LHP NC Film Treatments: Solid-state ligand exchange is an alternative strategy to adjust the ligand shell composition of the LHP NCs in films. [412,414,415] This type of ligand exchange is especially promising for LHP NCs which, due to the labile nature of the native OA and OAm ligands, could be affected by solubility and stability issues in a traditional solution-phase ligand exchange strategy. [412] In a solid-state ligand exchange, the new ligand is dispersed in an antisolvent, which is then dropped onto the surface of a NC film (Figure 12H).…”
Section: Ligand Modification In Nc Films For Led Device Improvementmentioning
confidence: 99%
“…[412] In a solid-state ligand exchange, the new ligand is dispersed in an antisolvent, which is then dropped onto the surface of a NC film (Figure 12H). [412,414,415] However, due to the sensitivity of LHP NCs to nonpolar solvents, careful solvent choice is required to accomplish the ligand exchange process. [412] In one example of a solid-state ligand exchange performed on a LHP NC film, short chain ligands such as benzoic acid and 4-phenylbutylamine in a mixture of octane and benzene were used to replace native OA and OAm ligands (Figure 12H).…”
Section: Ligand Modification In Nc Films For Led Device Improvementmentioning
confidence: 99%
“…For instance, in 5.6 nm QDs, the ASE spectra of PbS/ZnO blend samples having 15%, 20%, and 25% ZnO loading is correspondingly blue-shifted by ≈17, 24, 30 nm with respect to their bare-PbS counterpart (light-orange colored spectra in Figure 3c, A similar blue-shift is observed in the absorption spectra (See Figure S9 in the Supporting Information). We ascribe the blue-shifting of ASE and absorption spectra due to increasing inter-dot spacing of PbS-emitter CQDs, [28,29] Figure 3d provides a summary of the measured ASE in different sizes of PbS-emitter QDs as a function of ZnO content. As shown in Figure 3d, in all sizes of QDs, the ASE thresholds are clearly reduced by increasing the amount of ZnO loading in binary blend.…”
Section: Ase and Lasing Characterizationsmentioning
confidence: 99%
“…For instance, in 5.6 nm QDs, the ASE spectra of PbS/ZnO blend samples having 15%, 20% and 25% ZnO loading is correspondingly blue-shifted by ~17, 24, 30 nm with respect to their bare-PbS counterpart (light-orange coloured spectra in Figure 3c, A similar blue-shift is observed in the absorption spectra (See Supplementary Figure S9). We ascribe the blueshifting of ASE and absorption spectra due to increasing inter-dot spacing of PbS-emitter CQDs [28,29] , Figure 3d Finally, we combined the PbS/ZnO binary blend with 30% ZnO loading (our best performing ASE sample) with a second-order distributed feedback (DFB) resonator which provides strong in-plane feedback and lasing emission normal to the surface. Figure 4a illustrates the schematic of the DFB laser, where the film is pumped by a stripe excitation at normal incidence while the lasing emission is emitted from the surface of the device.…”
Section: Ase and Lasing Characterizationsmentioning
confidence: 99%
“…350 nm . Finally, 2-ethanedithiol (EDT) ligand capped PbS CQDs were used to form the HTL via a solid-state ligand-exchange-enabled layer-by-layer (LbL) process …”
mentioning
confidence: 99%