Unveiling the Interplay among End Group, Molecular Packing, Doping Level, and Charge Transport in N‐Doped Small‐Molecule Organic Semiconductors

Abstract: Doped small molecules with high electrical conductivity are desired because they typically show a larger Seebeck coefficient and lower thermal conductivity than their polymer counterparts. However, compared with conjugated polymers, only a few small molecules can show high electrical conductivities. In this study, three n-type small-molecule organic semiconductors with different end functional groups are synthesized to explore the reasons for the low electrical conductivity issue in n-doped small-molecule semi… Show more

“…The MPW1PW91/6-13G(d,p) method provided an absorption maximum at 739 nm that was in close correlation with the experimental value (710 nm in chlorobenzene) as mentioned in the literature. 33 Therefore, this approach was chosen as the optimum method for further research of all the formulated compounds. In Fig.…”

“…Spectral depiction of λ max was achieved through Origin 6.0 software. 30 UV-visible absorption 31,32 of TMR was contrasted with the cited (710 nm in chlorobenzene) 33 value to determine the best functional. Closeness to the experimentally determined maximum absorption of TMR was achieved by MPW1PW91/6-31G(d,p).…”

Novel A-π-D-π-A type non-fullerene acceptors of dithienyl diketopyrropopyrrole derivatives to enhance organic photovoltaic applications: a DFT study

“…The MPW1PW91/6-13G(d,p) method provided an absorption maximum at 739 nm that was in close correlation with the experimental value (710 nm in chlorobenzene) as mentioned in the literature. 33 Therefore, this approach was chosen as the optimum method for further research of all the formulated compounds. In Fig.…”

“…Spectral depiction of λ max was achieved through Origin 6.0 software. 30 UV-visible absorption 31,32 of TMR was contrasted with the cited (710 nm in chlorobenzene) 33 value to determine the best functional. Closeness to the experimentally determined maximum absorption of TMR was achieved by MPW1PW91/6-31G(d,p).…”

Novel A-π-D-π-A type non-fullerene acceptors of dithienyl diketopyrropopyrrole derivatives to enhance organic photovoltaic applications: a DFT study

“…[8][9][10][11][12][13] In particular, n-type organic semiconductor (n-OS) based small acceptor molecules [14][15][16][17] with a low bandgap (E gap ), when combined with a p-type donor polymer having a medium E gap , have shown remarkable optoelectronic performance. [18][19][20] The PCE of polymer based solar cells having an n-OS as an accepting moiety has increased to a 14%, surpassing the limit for PSCs to be used in practical settings. [21][22][23] The majority of highly efficient donor and acceptor optoelectronic materials, though, currently contain complex chemical geometries.…”

Quantum modeling of dimethoxyl-indaceno dithiophene based acceptors for the development of semiconducting acceptors with outstanding photovoltaic potential

“…29,30 Moreover, the extended p-conjugation with intense absorption parameters of fullerene-free chromophores have been enhanced via attachment of electron-decient terminal groups (cyano, nitro and halogens groups) over the skeleton of the nonfullerene acceptors (NFAs). 31,32 Furthermore, the nature and conjugated length of donor and acceptor parts are also important to design interesting NLO materials. 33 The synthesized compound (ICIF2F) is reported in the literature 34 and according to our best insights, its NLO study has not yet been published.…”

Enriching NLO efficacy via designing non-fullerene molecules with the modification of acceptor moieties into ICIF2F: an emerging theoretical approach