A systematic method to estimate and validate enthalpies of formation using error-cancelling balanced reactions

A systematic method to estimate and validate enthalpies of formation using error-cancelling balanced reactions

This paper presents an automated framework that uses overlapping subsets of reference data to systematically derive an informed estimate of the standard enthalpy of formation of chemical species and assess the consistency of the reference data. The theory of error-cancelling balanced reactions (EBRs...

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Bibliographic Details
Main Authors: Buerger, Philipp, Akroyd, Jethro, Mosbach, Sebastian, Kraft, Markus
Other Authors: School of Chemical and Biomedical Engineering
Format: Article
Language:English
Published: 2018
Subjects:
Enthalpy of Formation
Heat of Formation
Online Access:https://hdl.handle.net/10356/87228
http://hdl.handle.net/10220/45351
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Institution: Nanyang Technological University
Language: English
Description
Summary:This paper presents an automated framework that uses overlapping subsets of reference data to systematically derive an informed estimate of the standard enthalpy of formation of chemical species and assess the consistency of the reference data. The theory of error-cancelling balanced reactions (EBRs) is used to calculate estimates of the standard enthalpy of formation. Individual EBRs are identi ed using linear programming. The rst part of the framework recursively identi es multiple EBRs for speci ed target species. A distribution of estimates can then be determined for each species from which an informed estimate of the enthalpy is derived. The second part of the framework iteratively isolates inconsistent reference data and improves the prediction accuracy by excluding such data. The application of the framework is demonstrated for test cases from organic and inorganic chemistry, including transition metal complexes. Its application to a set of 920 carbon, hydrogen and oxygen containing species resulted in a rapid decrease of the mean absolute error for estimates of the enthalpy of formation of each species due to the identi cation and exclusion of inconsistent reference data. Its application to titanium-containing species identi ed that the available reference values of TiOCl and TiO(OH)2.

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