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        <dc:title>A computationally efficient and accurate method for predicting conductance of single-molecule junctions</dc:title>
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        <bibo:abstract>Despite significant progress in the field of molecular electronics over the last two decades, the quantitative prediction of metal-molecule-metal junction conductance remains a challenge. The standard computational framework combines density functional theory (DFT) with nonequilibrium Green’s functions (NEGF) using low-rung exchange-correlation functionals such as PBE, which overestimate the conductances. More advanced correction methods exist but require complex workflows and high computational cost, limiting their accessibility. Here, we introduce a physically motivated approach that approximates results obtained with high-rung functionals. Our method fits the PBE-calculated transmission to a Breit-Wigner form and subsequently refines the fit parameters using molecular orbital energies and metal densities of states computed for the isolated subsystems with high-rung functionals. This approach is applicable to a broad range of molecular junctions yielding conductance values in quantitative agreement with experiments. Our approach is simple, low-cost, and accurate, making it well-suited for routine and large-scale prediction of single-molecule junction conductance.</bibo:abstract>
        <bibo:volume>26</bibo:volume>
        <bibo:issue>22</bibo:issue>
        <bibo:startPage>7429–7434</bibo:startPage>
        <bibo:endPage>7429–7434</bibo:endPage>
        <dc:publisher>American Chemical Society</dc:publisher>
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