On the Interface Dipole at the Pentacene−Fullerene Heterojunction: A Theoretical Study

Linares, Mathieu; Beljonne, David; Cornil, Jérôme; Lancaster, Kelly; Brédas, Jean‐Luc; Verlaak, Stijn; Mityashin, Alexander; Heremans, Paul; Fuchs, Andreas; Lennartz, Christian; Idé, Julien; Méreau, Raphaël; Aurel, Philippe; Ducasse, Laurent; Castet, Frédéric

doi:10.1021/jp910005g

Cited by 126 publications

(151 citation statements)

References 30 publications

(43 reference statements)

Supporting

Mentioning

136

Contrasting

Unclassified

Order By: Relevance

“…The development of single-crystal organic field effect transistors (SCOFETs) makes it possible to explore intrinsic properties of these materials [9][10][11]. p-Type organic semiconductors such as pentacene, rubrene and derivatives of them have been investigated widely [12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27]. The recently improved theoretical understandings of organic semiconductors have even addressed the design rule of organics with high hole mobilities [28][29][30][31].…”

Section: Introductionmentioning

confidence: 99%

BODIPY derivatives as n-type organic semiconductors: Isomer effect on carrier mobility

Zhang

Chai

Zhao

2012

Organic Electronics

View full text Add to dashboard Cite

Section: Introductionmentioning

confidence: 99%

BODIPY derivatives as n-type organic semiconductors: Isomer effect on carrier mobility

Zhang

Chai

Zhao

2012

Organic Electronics

View full text Add to dashboard Cite

“…Even though electrostatic effects in organic semiconductors have been linked to the molecular quadrupole in a variety of theoretical and experimental studies [97,99,100,104,105,140,[144][145][146]148], the routine use of an interaction range cutoff resulted in a very different and significantly more local interpretation of electrostatic effects, as will be illustrated in the following section.…”

Section: The Acceptor-donor-acceptor Puzzlementioning

confidence: 99%

The (Non-)Local Density of States of Electronic Excitations in Organic Semiconductors

Poelking

2018

Springer Theses

View full text Add to dashboard Cite

The (Non-)Local Density of States of Electronic Excitations in Organic Semiconductors The rational design of organic semiconductors for optoelectronic devices relies on a detailed understanding of how their molecular and morphological structure condition the energetics and dynamics of charged and excitonic states. Investigating the role of molecular architecture, conformation, orientation and packing, this work reveals mechanisms that shape the spatially resolved densities of states in organic, small-molecular and polymeric heterostructures and mesophases. The underlying computational framework combines multiscale simulations of the material morphology at atomistic and coarse-grained resolution with a long-range-polarized embedding technique to resolve the electronic structure of the molecular solid. We show that longrange electrostatic interactions tie the energetics of microscopic states to the mesoscopic structure, with a qualitative and quantitative impact on charge-carrier level profiles across organic interfaces. The computational approach provides quantitative access to the charge-density-dependent opencircuit voltage of planar heterojunctions. The derived and experimentally verified relationships between molecular orientation, architecture, level profiles and open-circuit voltage rationalize the acceptor-donor-acceptor pattern for donor materials in high-performing solar cells. Proposing a pathway for barrier-less dissociation of charge transfer states, we highlight how mesoscale fields generate charge splitting and detrapping forces in systems with finite interface roughness. The associated design rules reflect the dominant role played by lowest-energy configurations at the interface. Acknowledgements 121 Die (nicht-)lokale Zustandsdichte elektronischer Anregungen in organischen Halbleitern List of Publications 123Bibliography 125 Chapter 1 Organic Electronics in a NutshellThe discovery of conductive polymers in the 1970s [1,2] -rewarded with the Nobel prize in chemistry in the year 2000 -and subsequent development of the first polymeric electronic devices in the 1980s [3-5] have marked the beginnings of a vast interdisciplinary research field referred to as organic electronics. Drawing from both polymeric and small-molecular semiconductors, organic thin-film transistors, solar cells, light-emitting diodes, photodetectors and sensors name just a few out of many applications that make use of the supreme chemical versatility and mechanical flexibility of the underlying "soft" molecular materials. Furthermore enabling low-temperature solution-based processing, printing and spray coating, organic electronics is set to complement the conventional silicon-based electronics in diverse waysadding functionality and improving sustainability. This introductory chapter will provide a short review of the materials and device physics, as well as of new trends and challenges that emerged in the field over the past decade. MaterialsOrganic semiconductors are molecular materials that exist at the interface between orga...

show abstract

“…106 As we discussed in the Section 2.4, the locations of the fullerene molecules over the conjugated polymer backbones depend on the nature and position of the alkyl side-chains. 162 Furthermore, intermolecular interactions between polymer chains and fullerene molecules are known to play crucial roles on the electron-transfer rates, 163 exciton binding energies, 164 and processes of charge separation and charge recombination. 163 Hence, the performance of OPV devices does depend on the intermolecular arrangements and resulting energy landscapes at the interfaces between the polymer and fullerene phases.…”

Section: Noncovalent Interactions In Fullerenes Andmentioning

confidence: 99%

Noncovalent Interactions in Organic Electronic Materials

Ravva

Risko

Brédas

2017

Non-Covalent Interactions in Quantum Chemistry and Physics

Self Cite

View full text Add to dashboard Cite

In this Chapter, we provide an overview of how noncovalent interactions, determined by the chemical structure of π-conjugated molecules and polymers, govern essential aspects of the electronic, optical, and mechanical characteristics of organic semiconductors. We begin by describing general aspects of materials design, including the wide variety of chemistries exploited to control the electronic and optical properties of these materials. We then discuss explicit examples of how the study of noncovalent interactions can provide deeper chemical insights that can improve the design of new generations of organic electronic materials.2

show abstract

On the Interface Dipole at the Pentacene−Fullerene Heterojunction: A Theoretical Study

Cited by 126 publications

References 30 publications

BODIPY derivatives as n-type organic semiconductors: Isomer effect on carrier mobility

BODIPY derivatives as n-type organic semiconductors: Isomer effect on carrier mobility

The (Non-)Local Density of States of Electronic Excitations in Organic Semiconductors

Noncovalent Interactions in Organic Electronic Materials

Contact Info

Product

Resources

About