Insight into doping efficiency of organic semiconductors from the analysis of the density of states in n-doped C60 and ZnPc

Gaul, Christopher; Hutsch, Sebastian; Schwarze, Martin; Schellhammer, Karl Sebastian; Bussolotti, Fabio; Kera, Satoshi; Cuniberti, Gianaurelio; Leo, Karl; Ortmann, Frank

doi:10.1038/s41563-018-0030-8

Cited by 113 publications

(127 citation statements)

References 47 publications

Supporting

Mentioning

120

Contrasting

Order By: Relevance

“…The models successfully replicated the experimental values (Figure 1b,c). Moreover, the charge transfer modifies the density of states of C 60 so that the LUMO level of charged C 60 molecules is split into an “occupied” LUMO level (L1) that is shifted downward and an unoccupied LUMO level (L2) that is shifted upward (Figure 1d, right) 16. This downshift of the LUMO level upon charge transfer can substantially stabilize C 60 adsorbates on graphene 17…”

Section: Resultsmentioning

confidence: 99%

Charge‐Transfer‐Controlled Growth of Organic Semiconductor Crystals on Graphene

et al. 2020

View full text Add to dashboard Cite

Controlling the growth behavior of organic semiconductors (OSCs) is essential because it determines their optoelectronic properties. In order to accomplish this, graphene templates with electronic‐state tunability are used to affect the growth of OSCs by controlling the van der Waals interaction between OSC ad‐molecules and graphene. However, in many graphene‐molecule systems, the charge transfer between an ad‐molecule and a graphene template causes another important interaction. This charge‐transfer‐induced interaction is never considered in the growth scheme of OSCs. Here, the effects of charge transfer on the formation of graphene–OSC heterostructures are investigated, using fullerene (C60) as a model compound. By in situ electrical doping of a graphene template to suppress the charge transfer between C60 ad‐molecules and graphene, the layer‐by‐layer growth of a C60 film on graphene can be achieved. Under this condition, the graphene–C60 interface is free of Fermi‐level pinning; thus, barristors fabricated on the graphene–C60 interface show a nearly ideal Schottky–Mott limit with efficient modulation of the charge‐injection barrier. Moreover, the optimized C60 film exhibits a high field‐effect electron mobility of 2.5 cm2 V−1 s−1. These results provide an efficient route to engineering highly efficient optoelectronic graphene–OSC hybrid material applications.

show abstract

Section: Resultsmentioning

confidence: 99%

Charge‐Transfer‐Controlled Growth of Organic Semiconductor Crystals on Graphene

et al. 2020

View full text Add to dashboard Cite

show abstract

“…In Figure a, the higher doping concentration after addition of H 2 SO 4 to CPE‐K is obvious when comparing the ratio between the absorption bands for the N 1 and P 2 transitions, which clearly increases in CPE‐K/H 2 SO 4 . We have shown above that the concentration of doped monomers increases from 17% to 27% with the addition of acid, as also confirmed via EPR and conductivity measurements . The doping level is relatively high for both CPE‐K and CPE‐K/H 2 SO 4 films, with practically all chains containing doped sites and being close to polarons of other chains due to chain packing in the films (insets of Figure a).…”

Section: Resultsmentioning

confidence: 99%

“…Achieving high conductivity in doped organic semiconductors requires high mobility and a high yield of free charges that do not remain bound (electrostatically or by orbital hybridization) to the ionized dopant 3,5,6c. Here, via spectroscopic elucidation of the optoelectronic properties of a self‐doped system, we find characteristics of the polaron that might help its dissociation from interfacial bound states.…”

Section: Resultsmentioning

confidence: 99%

“…Significant efforts have thus been invested to understand and to improve the electrical and transport properties of doped organic semiconductors through understanding of the elementary processes associated with different levels and types of doping . Experimental and theoretical research on doped organic semiconductors has been intensified over the past few years as a consequence of recent synthetic advances that enable better control over the bulk distribution and stability of charges . One drawback in the field is that upon doping of organic semiconductors, even for systems where integer charge transfer occurs between the dopant and the host, only a small fraction (typically 5%) of the charges are mobile and contribute to the conductivity, while most of them remain bound to the ionized dopant .…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Excited State Dynamics of a Self‐Doped Conjugated Polyelectrolyte

Τσόκκου

Peterhans

Cao

et al. 2019

Adv Funct Materials

View full text Add to dashboard Cite

The growing number of applications of doped organic semiconductors drives the development of highly conductive and stable materials. Lack of understanding about the formation and properties of mobile charges limits the ability to improve material design. Thus the largely unexplored photophysics of doped systems are addressed here to gain insights about the characteristics of doping‐induced polarons and their interactions with their surroundings. The study of the ultrafast optical processes in a self‐doped conjugated polyelectrolyte reveals that polarons not only affect their environment via Coulomb effects but also strongly couple electronically to nearby neutral sites. This is unambiguously demonstrated by the simultaneous depletion of both the neutral and polaronic transitions, as well as by correlated excited state dynamics, when either transition is targeted during ultrafast experiments. The results contrast with the conventional picture of localized intragap polaron states but agree with revised models for the optical transitions in doped organic materials, which predict a common ground level for polarons and neighboring neutral sites. Such delocalization of polarons into the frontier transport levels of their surroundings could enhance the electronic connectivity between doped and undoped sites, contributing to the formation of conductive charges.

show abstract

“…Surprisingly, the η Dop is on the order of 10% for most systems. Several causes have been invoked of which clustering of dopant molecules, charge carrier traps, large dopant activation energy caused by large Coulomb interaction, or strong hybridization of dopant and matrix molecules, and impurity reserve regime . At a molecular level, two extreme situations can occur when an electron donor and an electron acceptor encounter: either a full charge transfer takes place giving rise to the formation of an ion‐pair or hybrid states are created, as shown in Figure a,b, respectively .…”

Section: Charge Transportmentioning

confidence: 99%

Molecular Semiconductors for Logic Operations: Dead‐End or Bright Future?

et al. 2020

View full text Add to dashboard Cite

The field of organic electronics has been prolific in the last couple of years, leading to the design and synthesis of several molecular semiconductors presenting a mobility in excess of 10 cm2 V−1 s−1. However, it is also started to recently falter, as a result of doubtful mobility extractions and reduced industrial interest. This critical review addresses the community of chemists and materials scientists to share with it a critical analysis of the best performing molecular semiconductors and of the inherent charge transport physics that takes place in them. The goal is to inspire chemists and materials scientists and to give them hope that the field of molecular semiconductors for logic operations is not engaged into a dead end. To the contrary, it offers plenty of research opportunities in materials chemistry.

show abstract

Insight into doping efficiency of organic semiconductors from the analysis of the density of states in n-doped C60 and ZnPc

Cited by 113 publications

References 47 publications

Charge‐Transfer‐Controlled Growth of Organic Semiconductor Crystals on Graphene

Charge‐Transfer‐Controlled Growth of Organic Semiconductor Crystals on Graphene

Excited State Dynamics of a Self‐Doped Conjugated Polyelectrolyte

Molecular Semiconductors for Logic Operations: Dead‐End or Bright Future?

Contact Info

Product

Resources

About