All-organic sulfonium salts acting as efficient solution processed electron injection layer for PLEDs

Georgiadou D.G.; Vasilopoulou M.; Palilis L.C.; Petsalakis, Ioannis D.; Theodorakopoulos, Giannoula; Constantoudis V.; Kennou S.; Karantonis A.; Dimotikali D.; Argitis P.

Παρακαλώ χρησιμοποιήστε αυτό το αναγνωριστικό για να παραπέμψετε ή να δημιουργήσετε σύνδεσμο προς αυτό το τεκμήριο: https://hdl.handle.net/10442/17203

Export to: BibTeX | EndNote | RIS

Εξειδίκευση τύπου :	Άρθρο σε επιστημονικό περιοδικό
Τίτλος:	All-organic sulfonium salts acting as efficient solution processed electron injection layer for PLEDs
Δημιουργός/Συγγραφέας:	Georgiadou D.G. Vasilopoulou M. Palilis L.C. [EL] Πετσαλάκης, Ιωάννης Δ.[EN] Petsalakis, Ioannis D. [EL] Θεοδωρακοπούλου, Γιαννούλα[EN] Theodorakopoulos, Giannoula Constantoudis V. Kennou S. Karantonis A. Dimotikali D. Argitis P.
Ημερομηνία:	2013
Γλώσσα:	Αγγλικά
ISSN:	1944-8244
DOI:	10.1021/am402991b
Περίληψη:	Herein we introduce the all-organic triphenylsulfonium (TPS) salts cathode interfacial layers (CILs), deposited from their methanolic solution, as a new simple strategy for circumventing the use of unstable low work function metals and obtaining charge balance and high electroluminescence efficiency in polymer light-emitting diodes (PLEDs). In particular, we show that the incorporation of TPS-triflate or TPS-nonaflate at the polymer/Al interface improved substantially the luminous efficiency of the device (from 2.4 to 7.9 cd/A) and reduced the turn-on and operating voltage, whereas an up to 4-fold increase in brightness (∼11 250 cd/m2 for TPS-triflate and ∼14 682 cd/m2 for TPS-nonaflate compared to ∼3221 cd/m2 for the reference device) was observed in poly[(9,9-dioctylfluorenyl-2,7-diyl)-co-(1,4-benzo-2, 1′,3-thiadiazole)] (F8BT)-based PLEDs. This was mainly attributed to the favorable decrease of the electron injection barrier, as derived from the open-circuit voltage (Voc) measurements, which was also assisted by the conduction of electrons through the triphenylsulfonium salt sites. Density functional theory calculations indicated that the total energy of the anionic (reduced) form of the salt, that is, upon placing an electron to its lowest unoccupied molecular orbital, is lower than its neutral state, rendering the TPS-salts stable upon electron transfer in the solid state. Finally, the morphology optimization of the TPS-salt interlayer through controlling the processing parameters was found to be critical for achieving efficient electron injection and transport at the respective interfaces.
Τίτλος πηγής δημοσίευσης:	ACS Applied Materials and Interfaces
Τόμος/Κεφάλαιο:	5
Τεύχος:	23
Σελίδες:	12346-12354
Θεματική Κατηγορία:	[EL] Φυσική και θεωρητική χημεία[EN] Physical and theoretical chemistry
Λέξεις-Κλειδιά:	cathode interfacial layer counterions electron transport nonaflate OLEDs triflate
Αξιολόγηση από ομότιμους (peer reviewed):	Ναι
Κάτοχος πνευματικών δικαιωμάτων:	© 2013 American Chemical Society.
Εμφανίζεται στις συλλογές:	Ινστιτούτο Θεωρητικής και Φυσικής Χημείας (ΙΘΦΧ) - Επιστημονικό έργο

Αρχεία σε αυτό το τεκμήριο:

Το πλήρες κείμενο αυτού του τεκμηρίου δεν διατίθεται προς το παρόν από τον ΗΛΙΟ.