2020
DOI: 10.1002/aenm.202002649
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Altering the Positions of Chlorine and Bromine Substitution on the End Group Enables High‐Performance Acceptor and Efficient Organic Solar Cells

Abstract: Molecular design of organic semiconductors plays an important role in development of organic solar cell (OSC) materials and devices. [1-6] It is generally believed that subtle structural changes could lead to significant variations in the optoelectronic properties and photovoltaic performance of organic semiconductors. In particular, many of such examples have been demonstrated in the area of nonfullerene small-molecule acceptors (SMAs), [7-16] which has been a major revolution of the OSC field in the past few… Show more

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Cited by 113 publications
(87 citation statements)
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“…The obvious (010) diffraction peak at 1.77 Å −1 in OOP indirection and (100) diffraction peak at 0.28 Å −1 in IP direction can be observed from the 2D‐GIWAXS patterns of PM6:BTP‐BO‐4F blend films, suggesting the efficient charge transport along the normal direction of substrate due to the preferential face‐on orientation molecular arrangement of PM6 and BTP‐BO‐4F. [ 49–52 ] The preferential face‐on orientation molecular arrange of PM6 and BTP‐BO‐4F can be further confirmed from the occurrence of IP (200) diffraction in blend films in comparison with the neat films. The diffraction intensity of OOP (010) and IP (100) peaks in PM6:Y6‐1O blend films is slightly stronger than that in PM6:BTP‐BO‐4F blend films, indicating the more ordered molecular arrangement in PM6:Y6‐1O blend films.…”
Section: Resultsmentioning
confidence: 99%
“…The obvious (010) diffraction peak at 1.77 Å −1 in OOP indirection and (100) diffraction peak at 0.28 Å −1 in IP direction can be observed from the 2D‐GIWAXS patterns of PM6:BTP‐BO‐4F blend films, suggesting the efficient charge transport along the normal direction of substrate due to the preferential face‐on orientation molecular arrangement of PM6 and BTP‐BO‐4F. [ 49–52 ] The preferential face‐on orientation molecular arrange of PM6 and BTP‐BO‐4F can be further confirmed from the occurrence of IP (200) diffraction in blend films in comparison with the neat films. The diffraction intensity of OOP (010) and IP (100) peaks in PM6:Y6‐1O blend films is slightly stronger than that in PM6:BTP‐BO‐4F blend films, indicating the more ordered molecular arrangement in PM6:Y6‐1O blend films.…”
Section: Resultsmentioning
confidence: 99%
“…Therefore,w ei ntuitively design synthetic routes that can yield only one regiospecific product of dihalogenated terminal groups.T he synthetic routes to IC-FBr-o and IC-FBr-m are illustrated in Scheme 1. [50,51] By introducing the fluorine atom adjacent to one of the carbonyl groups of the precursor, the following condensation reaction will only occur at the other carbonyl group with less steric hindrance,r esulting in configuration-unique terminal group moieties and the corresponding SMA comonomers (Y-OD-FBr-o and Y-OD-FBrm). Notably,t he synthetic routes of these two regiospecific terminal groups are even easier and more efficient compared to that of the previous IC-FBr containing regio-isomers.…”
Section: Resultsmentioning
confidence: 99%
“…[30][31][32] All the three parts can be reasonably designed and regulated to fine-tune the molecular properties of Y-series acceptors. [33][34][35][36][37][38][39][40][41] For example, if the chlorine atoms are used to replace the fluorine atoms in one of the famous Y-series acceptors named Y6, [42] the resulting molecule BTP-4Cl not only exhibits red-shifted absorption but also reduced voltage loss, leading to the BTP-4Cl-based devices showing an increased power conversion efficiency (PCE) of 16.5% with enhanced open-circuit voltage (V OC ) and short-circuit current density (J SC ) compared to those of the Y6-based devices. [43] It is also promising to modify the inner branched side chains which determine the solubility and crystallinity of Y-series acceptors.…”
Section: Chemical Modifications Of Non-fullerene Acceptors (Nfas) Plamentioning
confidence: 99%