Molecular Modeling of Crystalline Alkylthiophene Oligomers and Polymers

Moreno, Margherita; Casalegno, Mosé; Raos, Guido; Meille, Stefano Valdo; Pò, Riccardo

doi:10.1021/jp9106124

Cited by 93 publications

(146 citation statements)

References 88 publications

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“…Finally, these structures were subjected to further molecular mechanics and molecular dynamics simulations using our own force field, which had been developed and thoroughly tested on several thiophene oligomers. [12] This allowed us to rule out some candidate structures, whose computed X-ray spectra were compatible with the experimental ones, but which were not viable from an energetic point of view. The final results are given in Figures 2 and 3, respectively for form I' [9] and form II [10].…”

Section: Organic Photovoltaic Materialsmentioning

confidence: 99%

“…The latter includes both ab initio electronic structure calculations and molecular dynamics (MD) simulations. [12] 3 Structure and modelling of P3BT…”

Section: Organic Photovoltaic Materialsmentioning

confidence: 99%

“…[21] Film discontinuity, related to spherulitic morphology, poor stacking and small crystallite dimensions along the chain direction all suggest that crystallization of P3AT's in form II will not be beneficial for OPV applications. The MD simulations of the polymers and the oligomers [12] demonstrate that, even in the absence of chain folding, thermal motions can produce significant disordering of the side chains. This is evident in the non-interdigitated form I' (Figure 2), and will certainly be even greater in the more common form I.…”

Section: Organic Photovoltaic Materialsmentioning

confidence: 99%

“…We will then review our studies of poly(3-butylthiophene) (P3BT) and of [6,6]phenyl-C 61 -butyric acid methyl ester (PCBM). [9][10][11][12] Their molecular structures are displayed in Figure 1, together with a simplified scheme of an organic solar cell (see below). Our aim will be to demonstrate the synergistic roles played by experimental and computational methods in this field.…”

Section: Introductionmentioning

confidence: 99%

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Materials for organic photovoltaics: insights from detailed structural models and molecular simulations

Casalegno

Baggioli

Famulari

et al. 2012

EPJ Web of Conferences

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Abstract. This paper contains a brief discussion of the role of detailed structural and computational studies, within the general field of organic photovoltaics. We review some of our recent work on poly(3-butylthiophene) (P3BT) and on [6,6]phenyl-C 61 -butyric acid methyl ester (PCBM). The first is a prototypical hole-transporting material, whose crystal forms I' and II were solved by us through the combined use of powder Xray diffraction, electron diffraction and molecular modelling. PCBM is a widely used fullerene derivative with electron-transporting properties. It has a rich polymorphism, which to date remains largely unexplored. Our molecular dynamics simulations have revealed interesting features of its solid-state organization, including that in the amorphous phase.

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Section: Organic Photovoltaic Materialsmentioning

confidence: 99%

“…The latter includes both ab initio electronic structure calculations and molecular dynamics (MD) simulations. [12] 3 Structure and modelling of P3BT…”

Section: Organic Photovoltaic Materialsmentioning

confidence: 99%

Section: Organic Photovoltaic Materialsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Materials for organic photovoltaics: insights from detailed structural models and molecular simulations

Casalegno

Baggioli

Famulari

et al. 2012

EPJ Web of Conferences

Self Cite

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“…From a computational viewpoint, the challenges are different, but equally difficult. For computation, intermolecular and intramolecular interactions govern the eventual outcome, but expressing these forces is an ongoing challenge [45]. A second major challenge is to leverage and scale this knowledge to move from the electronic structure or molecular level simulations to experimentally relevant length-scale and timescale.…”

Section: The Role For Theory: Rational Design Of Heterojunction Compomentioning

confidence: 99%

Chemical engineering in the electronics industry: progress towards the rational design of organic semiconductor heterojunctions

Clancy

2012

Current Opinion in Chemical Engineering

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We review the current status of heterojunction design for combinations of organic semiconductor materials, given its central role in affecting the device performance for electronic devices and solar cell applications. We provide an emphasis on recent progress towards the rational design of heterojunctions that may lead to higher performance of charge separation and mobility. We also play particular attention to the role played by computational approaches and its potential to help define the best choice of materials for solar cell development in the future. We report the current status of the field with respect to such goals. Introduction Developments in electronic devices over the past 50 years have revolutionized the way we conduct our daily lives, including the use of organic electronics in cell phones, display technologies and sensors, and ultra-fast processors that have improved the speed of computers in ways unimaginable a generation ago. For example, cell phone subscriptions worldwide passed 5 billion customers in 2010. The electronics industry is a major contributor to the global economy, valued at more than $300 billion in 2010 [1]. Chemical engineering in the semiconductor industriesChemical Engineers have played a strong role in the development of semiconductor materials and processing. Indeed, the American Institute of Chemical Engineers reports that $15% of graduating BS chemical engineers are employed in the electronics industries each year [2]. This is typically the second or third highest percentage destination behind chemicals ($25%), similar to fuels (12-20%), and above foods and pharmaceutical employment. At the PhD level, employment of chemical engineers by the electronics industry is around 20-30%, vying for the most popular destination with chemicals. The attraction of hiring chemical engineers in the electronics industry is clear: Many fabrication processes and materials design issues require a deep understanding of the underlying chemistry, physics and mathematics, and especially of thermodynamic and kinetic processes coupled to chemical reactions and reactor design that are the hallmark of a classically trained chemical engineer. Chemical engineers are trained to understand and apply physical and chemical concepts over extensive orders of magnitude in length-scale (and often time-scale). For example, understanding the atomic-level (sub-nm) details of charge absorption and separation, the multi-nanometer concepts of phase segregation or charge diffusion, and macroscopic (meter-scale) aspects concerning highthroughput processes such as the roll-to-roll processing of organic thin film devices.The interplay between chemical engineering and nanotechnology/electronics is likely to strengthen in the years ahead. For example, the focus of many modern chemical engineering departments is increasingly at the molecular scale; hence, nanotechnology and molecular-scale processing profitably draw upon the educational training of a chemical engineer. The tradition of chemical engineers in the energy indu...

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Understanding the Microscopic Origin of the Very High Charge Mobility in PBTTT: Tolerance of Thermal Disorder

Liu

Troisi

2013

Adv Funct Materials

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The one-electron states responsible for hole transport in the high-mobility semicrystalline polymer PBTTT are investigated using a combination of large-scale electronic structure calculations (with the DFTB method) and classical molecular dynamics simulations. The validity of the structural model is established by comparison with the available data from crystallography, including the paracrystallinity parameter. The localization characteristics of the states at the edge of the valence band, their geometry, and their time evolution clearly indicate the characteristics of PBTTT that are at the origin of its improved mobility: i) the orbitals become very rapidly delocalized within few tens of eV from the valence band edge, that is, the density of trap states is low and the mobility edge is very close to the valence band edge; ii) a very large delocalization of states across chains is observed; iii) the traps, determined by local distortions of the chain, have a typical lifetime of less than 0.1 ns, that is, the conformational changes of the polymer due to its thermal fl uctuations are suffi cient to induce a detrapping of the charge carrier and the traps are "self-healing".

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Molecular Modeling of Crystalline Alkylthiophene Oligomers and Polymers

Cited by 93 publications

References 88 publications

Materials for organic photovoltaics: insights from detailed structural models and molecular simulations

Materials for organic photovoltaics: insights from detailed structural models and molecular simulations

Chemical engineering in the electronics industry: progress towards the rational design of organic semiconductor heterojunctions

Understanding the Microscopic Origin of the Very High Charge Mobility in PBTTT: Tolerance of Thermal Disorder

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