TY - JOUR
T1 - On the Importance of Chemical Precision in Organic Electronics
T2 - Fullerene Intercalation in Perfectly Alternating Conjugated Polymers
AU - Vanderspikken, Jochen
AU - Liu, Zhen
AU - Wu, Xiaocui
AU - Beckers, Omar
AU - Moro, Stefania
AU - Quill, Tyler James
AU - Liu, Quan
AU - Goossens, Arwin
AU - Marks, Adam
AU - Weaver, Karrie
AU - Hamid, Mouna
AU - Goderis, Bart
AU - Nies, Erik
AU - Lemaur, Vincent
AU - Beljonne, David
AU - Salleo, Alberto
AU - Lutsen, Laurence
AU - Vandewal, Koen
AU - Van Mele, Bruno
AU - Costantini, Giovanni
AU - Van den Brande, Niko
AU - Maes, Wouter
PY - 2023/9/10
Y1 - 2023/9/10
N2 - The true structure of alternating conjugated polymers—the state‐of‐the‐art materials for many organic electronics—often deviates from the idealized picture. Homocoupling defects are in fact inherent to the widely used cross‐coupling polymerization methods. Nevertheless, many polymers still perform excellently in the envisaged applications, which raises the question if one should really care about these imperfections. This article looks at the relevance of chemical precision (and lack thereof) in conjugated polymers covering the entire spectrum from the molecular scale, to the micro and mesostructure, up to the device level. The different types of polymerization errors for the alkoxylated variant of the benchmark (semi)crystalline polymer poly[2,5‐bis(3‐tetradecylthiophen‐2‐yl)thieno[3,2‐b]thiophene (PBTTT) are identified, visualized, and quantified and a general strategy to avoid homocoupling is introduced. Through a combination of experiments and supported by simulations, it is shown that these coupling defects hinder fullerene intercalation and limit device performance as compared to the homocoupling‐free analog. This clearly demonstrates that structural defects do matter and should be generally avoided, in particular when the geometrical regularity of the polymer is essential. These insights likely go beyond the specific PBTTT derivatives studied here and are of general relevance for the wider organic electronics field.
AB - The true structure of alternating conjugated polymers—the state‐of‐the‐art materials for many organic electronics—often deviates from the idealized picture. Homocoupling defects are in fact inherent to the widely used cross‐coupling polymerization methods. Nevertheless, many polymers still perform excellently in the envisaged applications, which raises the question if one should really care about these imperfections. This article looks at the relevance of chemical precision (and lack thereof) in conjugated polymers covering the entire spectrum from the molecular scale, to the micro and mesostructure, up to the device level. The different types of polymerization errors for the alkoxylated variant of the benchmark (semi)crystalline polymer poly[2,5‐bis(3‐tetradecylthiophen‐2‐yl)thieno[3,2‐b]thiophene (PBTTT) are identified, visualized, and quantified and a general strategy to avoid homocoupling is introduced. Through a combination of experiments and supported by simulations, it is shown that these coupling defects hinder fullerene intercalation and limit device performance as compared to the homocoupling‐free analog. This clearly demonstrates that structural defects do matter and should be generally avoided, in particular when the geometrical regularity of the polymer is essential. These insights likely go beyond the specific PBTTT derivatives studied here and are of general relevance for the wider organic electronics field.
KW - Stille cross‐coupling
KW - homocoupling
KW - intermolecular charge‐transfer absorption
KW - structural defect quantification
KW - polymer:fullerene co‐crystals
U2 - 10.1002/adfm.202309403
DO - 10.1002/adfm.202309403
M3 - Article
SN - 1616-301X
JO - Advanced Functional Materials
JF - Advanced Functional Materials
M1 - 2309403
ER -