Rational Co‐Design of Polymer Dielectrics for Energy Storage

Mannodi-Kanakkithodi, Arun; Treich, Gregory M.; Huan, Tran Doan; Ma, Rui; Tefferi, Mattewos; Cao, Yang; Sotzing, Gregory A.; Ramprasad, Rampi

doi:10.1002/adma.201600377

Cited by 152 publications

(138 citation statements)

References 67 publications

(105 reference statements)

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“…A limit of the form

є elec ~ 1/ E_{normalg}^{normalHSE06}

shown in Fig. 5(d) has also been demonstrated for other classes of materials in the literature 13,35,36,51–62 .…”

Section: Data Recordssupporting

confidence: 58%

“…Moreover, the introduction of an organic cation A into the perovskite structure can give raise of many different structural motifs 6,10–12 , making the class of halide-based HOIPs highly diverse. Rapidly and thoroughly screening this un-explored domain of the chemical space, for instance, with the emerging data-driven approaches 13–25 , may reveal new promising compounds potentially meeting the pressing need for lead-free perovskite solar cell materials 26 .…”

Section: Background and Summarymentioning

confidence: 99%

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A hybrid organic-inorganic perovskite dataset

2017

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Hybrid organic-inorganic perovskites (HOIPs) have been attracting a great deal of attention due to their versatility of electronic properties and fabrication methods. We prepare a dataset of 1,346 HOIPs, which features 16 organic cations, 3 group-IV cations and 4 halide anions. Using a combination of an atomic structure search method and density functional theory calculations, the optimized structures, the bandgap, the dielectric constant, and the relative energies of the HOIPs are uniformly prepared and validated by comparing with relevant experimental and/or theoretical data. We make the dataset available at Dryad Digital Repository, NoMaD Repository, and Khazana Repository (http://khazana.uconn.edu/), hoping that it could be useful for future data-mining efforts that can explore possible structure-property relationships and phenomenological models. Progressive extension of the dataset is expected as new organic cations become appropriate within the HOIP framework, and as additional properties are calculated for the new compounds found.

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“…A limit of the form

є elec ~ 1/ E_{normalg}^{normalHSE06}

shown in Fig. 5(d) has also been demonstrated for other classes of materials in the literature 13,35,36,51–62 .…”

Section: Data Recordssupporting

confidence: 58%

Section: Background and Summarymentioning

confidence: 99%

A hybrid organic-inorganic perovskite dataset

2017

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“…Polymers are widely used in electric and electronic devices, e.g., capacitors 1–8 , transistors 9, 10 , fuel cell membranes 11, 12 and high-voltage cables 13, 14 . The insulating behavior of polymers—or any material for that matter—becomes progressively (and in many cases, irreversibly) degraded over time, especially when they are exposed to heat, light, oxygen, moisture, mechanical stress, and the high electric fields encountered during operation 14–17 .…”

Section: Introductionmentioning

confidence: 99%

“…Typically, polymer degradation involves a wide variety of physical and chemical processes, spanning over several length and time scales. The highly complicated and coupled nature of these processes render detailed mechanistic studies far from being tractable, both computationally 18–24 and experimentally 14, 17, 24–28 , despite extensive recent efforts aimed at the rational design of polymer dielectrics 3, 6, 8, 29–32 .…”

Section: Introductionmentioning

confidence: 99%

Electronic Structure of Polyethylene: Role of Chemical, Morphological and Interfacial Complexity

Chen

Huan

Ramprasad

2017

Sci Rep

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The electronic structure of an insulator encodes essential signatures of its short-term electrical performance and long-term reliability. A critical long-standing challenge though is that key features of the electronic structure of an insulator (and its evolution) under realistic conditions have not been entirely accessible, either via experimental or computational approaches, due to the inherent complexities involved. In this comprehensive study, we reveal the role of chemical and morphological imperfections that inevitably exist within the technologically important prototypical and pervasive insulator, polyethylene (PE), and at electrode/PE interfaces. Large-scale density functional theory computations and long-time molecular dynamics simulations were employed to accurately recover, explain and unravel a wide variety of experimental data obtained during the electrical degradation of PE. This scheme has allowed us to directly and realistically address the role of chemical, morphological and interfacial complexity in determining electronic structure. These efforts take us a step closer to understanding and potentially controlling dielectric degradation and breakdown.

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“…[1][2][3] Nevertheless, DFT-based MD simulations are not practical and routine at the present time, especially to track chemical processes with long time scales (≳1 nanosecond) and large length scales (≳10 nanometers). The repetitive and expensive DFT force computations during MD and the necessary small MD time steps (of the order of femtoseconds), lead to the primary bottlenecks of DFTbased MD simulations.…”

Section: Introductionmentioning

confidence: 99%

A universal strategy for the creation of machine learning-based atomistic force fields

et al. 2017

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Emerging machine learning (ML)-based approaches provide powerful and novel tools to study a variety of physical and chemical problems. In this contribution, we outline a universal strategy to create ML-based atomistic force fields, which can be used to perform high-fidelity molecular dynamics simulations. This scheme involves (1) preparing a big reference dataset of atomic environments and forces with sufficiently low noise, e.g., using density functional theory or higher-level methods, (2) utilizing a generalizable class of structural fingerprints for representing atomic environments, (3) optimally selecting diverse and non-redundant training datasets from the reference data, and (4) proposing various learning approaches to predict atomic forces directly (and rapidly) from atomic configurations. From the atomistic forces, accurate potential energies can then be obtained by appropriate integration along a reaction coordinate or along a molecular dynamics trajectory. Based on this strategy, we have created model ML force fields for six elemental bulk solids, including Al, Cu, Ti, W, Si, and C, and show that all of them can reach chemical accuracy. The proposed procedure is general and universal, in that it can potentially be used to generate ML force fields for any material using the same unified workflow with little human intervention. Moreover, the force fields can be systematically improved by adding new training data progressively to represent atomic environments not encountered previously.

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Rational Co‐Design of Polymer Dielectrics for Energy Storage

Cited by 152 publications

References 67 publications

A hybrid organic-inorganic perovskite dataset

A hybrid organic-inorganic perovskite dataset

Electronic Structure of Polyethylene: Role of Chemical, Morphological and Interfacial Complexity

A universal strategy for the creation of machine learning-based atomistic force fields

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