Different Agglomeration Properties of PCBM and PCBM in Photovoltaic Inks - a Spin-echo SANS Study

Overview

Journal RSC Adv

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2022 May 2

PMID 35495220

Authors

Gabriel Bernardo

Manuel Melle-Franco

Adam L Washington

Robert M Dalgliesh

Fankang Li

Adelio Mendes

Steven R Parnell

Affiliations

Soon will be listed here.

Abstract

Fullerene derivatives are used in a wide range of applications including as electron acceptors in solution-processable organic photovoltaics. We report agglomeration of fullerene derivatives in optically opaque solutions of PCBM and PCBM, with concentrations ranging from 30 mg mL up to 90 mg mL, in different solvents with relevance to organic photovoltaics, using a novel neutron scattering technique, Spin-Echo Small Angle Neutron Scattering (SESANS). From SESANS, agglomerates with correlation lengths larger than 1 μm are found in some PCBM solutions, in contrast no agglomerates are seen in PCBM solutions. These results clearly show that PCBM is fundamentally more soluble than PCBM in the solvents commonly used in photovoltaic inks and corroborating similar observations previously achieved using other experimental techniques. Computer models are presented to study the energetics of solution and agglomeration of both species, ascribing the difference to a kinetic effect probably related to the larger anisotropy of PCBM. Also, this work showcases the power of SESANS to probe agglomerates of fullerene derivatives in completely opaque solutions for agglomerates of the order of one to several microns.

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