Navigating the Chemical Space of HCN Polymerization and Hydrolysis: Guiding Graph Grammars by Mass Spectrometry Data

Jakob Lykke Andersen; Tommy Andersen; Christoph Flamm; Martin Hanczyc; Daniel Merkle; Peter F. Stadler

doi:10.3390/e15104066

Navigating the Chemical Space of HCN Polymerization and Hydrolysis: Guiding Graph Grammars by Mass Spectrometry Data

Jakob Lykke Andersen, Tommy Andersen, Christoph Flamm, Martin Hanczyc, Daniel Merkle, Peter F. Stadler

Department of Mathematics and Computer Science

University of Southern Denmark

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

Polymers of hydrogen cyanide and their hydrolysis products constitute a plausible, but still poorly understood proposal for early prebiotic chemistry on Earth. HCN polymers are generated by the interplay of more than a dozen distinctive reaction mechanisms and form a highly complex mixture. Here we use a computational model based on graph grammars as a means of exploring the chemical spaces of HCN polymerization and hydrolysis. A fundamental issue is to understand the combinatorial explosion inherent in large, complex chemical systems. We demonstrate that experimental data, here obtained by mass spectrometry, and computationally predicted free energies together can be used to guide the exploration of the chemical space and makes it feasible to investigate likely pathways and chemical motifs even in potentially open-ended chemical systems.

Original language	English
Journal	Entropy
Volume	15
Issue number	10
Pages (from-to)	4066-4083
ISSN	1099-4300
DOIs	https://doi.org/10.3390/e15104066
Publication status	Published - 2013

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@article{84bec0d2020f45f5ab613a94177896bd,

title = "Navigating the Chemical Space of HCN Polymerization and Hydrolysis: Guiding Graph Grammars by Mass Spectrometry Data",

abstract = "Polymers of hydrogen cyanide and their hydrolysis products constitute a plausible, but still poorly understood proposal for early prebiotic chemistry on Earth. HCN polymers are generated by the interplay of more than a dozen distinctive reaction mechanisms and form a highly complex mixture. Here we use a computational model based on graph grammars as a means of exploring the chemical spaces of HCN polymerization and hydrolysis. A fundamental issue is to understand the combinatorial explosion inherent in large, complex chemical systems. We demonstrate that experimental data, here obtained by mass spectrometry, and computationally predicted free energies together can be used to guide the exploration of the chemical space and makes it feasible to investigate likely pathways and chemical motifs even in potentially open-ended chemical systems.",

author = "Andersen, {Jakob Lykke} and Tommy Andersen and Christoph Flamm and Martin Hanczyc and Daniel Merkle and Stadler, {Peter F.}",

year = "2013",

doi = "10.3390/e15104066",

language = "English",

volume = "15",

pages = "4066--4083",

journal = "Entropy",

issn = "1099-4300",

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TY - JOUR

T1 - Navigating the Chemical Space of HCN Polymerization and Hydrolysis: Guiding Graph Grammars by Mass Spectrometry Data

AU - Andersen, Jakob Lykke

AU - Andersen, Tommy

AU - Flamm, Christoph

AU - Hanczyc, Martin

AU - Merkle, Daniel

AU - Stadler, Peter F.

PY - 2013

Y1 - 2013

N2 - Polymers of hydrogen cyanide and their hydrolysis products constitute a plausible, but still poorly understood proposal for early prebiotic chemistry on Earth. HCN polymers are generated by the interplay of more than a dozen distinctive reaction mechanisms and form a highly complex mixture. Here we use a computational model based on graph grammars as a means of exploring the chemical spaces of HCN polymerization and hydrolysis. A fundamental issue is to understand the combinatorial explosion inherent in large, complex chemical systems. We demonstrate that experimental data, here obtained by mass spectrometry, and computationally predicted free energies together can be used to guide the exploration of the chemical space and makes it feasible to investigate likely pathways and chemical motifs even in potentially open-ended chemical systems.

AB - Polymers of hydrogen cyanide and their hydrolysis products constitute a plausible, but still poorly understood proposal for early prebiotic chemistry on Earth. HCN polymers are generated by the interplay of more than a dozen distinctive reaction mechanisms and form a highly complex mixture. Here we use a computational model based on graph grammars as a means of exploring the chemical spaces of HCN polymerization and hydrolysis. A fundamental issue is to understand the combinatorial explosion inherent in large, complex chemical systems. We demonstrate that experimental data, here obtained by mass spectrometry, and computationally predicted free energies together can be used to guide the exploration of the chemical space and makes it feasible to investigate likely pathways and chemical motifs even in potentially open-ended chemical systems.

U2 - 10.3390/e15104066

DO - 10.3390/e15104066

M3 - Journal article

SN - 1099-4300

VL - 15

SP - 4066

EP - 4083

JO - Entropy

JF - Entropy

IS - 10

ER -

Navigating the Chemical Space of HCN Polymerization and Hydrolysis: Guiding Graph Grammars by Mass Spectrometry Data

Abstract

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