| A genome‐scale metabolic reconstruction for Escherichia coli K‐12 MG1655 that accounts for 1260 ORFs and thermodynamic information AM Feist, CS Henry, JL Reed, M Krummenacker, AR Joyce, PD Karp, ... Molecular systems biology 3 (1), 121, 2007 | 1758 | 2007 |
| Structural relaxation of polymer glasses at surfaces, interfaces, and in between RD Priestley, CJ Ellison, LJ Broadbelt, JM Torkelson Science 309 (5733), 456-459, 2005 | 860 | 2005 |
| Model polymer nanocomposites provide an understanding of confinement effects in real nanocomposites P Rittigstein, RD Priestley, LJ Broadbelt, JM Torkelson Nature materials 6 (4), 278-282, 2007 | 795 | 2007 |
| Thermodynamics-based metabolic flux analysis CS Henry, LJ Broadbelt, V Hatzimanikatis Biophysical journal 92 (5), 1792-1805, 2007 | 765 | 2007 |
| Separation of CO2 from CH4 Using Mixed-Ligand Metal−Organic Frameworks YS Bae, KL Mulfort, H Frost, P Ryan, S Punnathanam, LJ Broadbelt, ... Langmuir 24 (16), 8592-8598, 2008 | 688 | 2008 |
| Group contribution method for thermodynamic analysis of complex metabolic networks MD Jankowski, CS Henry, LJ Broadbelt, V Hatzimanikatis Biophysical journal 95 (3), 1487-1499, 2008 | 499 | 2008 |
| Exploring the diversity of complex metabolic networks V Hatzimanikatis, C Li, JA Ionita, CS Henry, MD Jankowski, LJ Broadbelt Bioinformatics 21 (8), 1603-1609, 2005 | 438 | 2005 |
| A critical review on hemicellulose pyrolysis X Zhou, W Li, R Mabon, LJ Broadbelt Energy Technology 5 (1), 52-79, 2017 | 408 | 2017 |
| A mechanistic model of fast pyrolysis of glucose-based carbohydrates to predict bio-oil composition R Vinu, LJ Broadbelt Energy & Environmental Science 5 (12), 9808-9826, 2012 | 404 | 2012 |
| Computer generated pyrolysis modeling: on-the-fly generation of species, reactions, and rates LJ Broadbelt, SM Stark, MT Klein Industrial & Engineering Chemistry Research 33 (4), 790-799, 1994 | 365 | 1994 |
| Rate-based construction of kinetic models for complex systems RG Susnow, AM Dean, WH Green, P Peczak, LJ Broadbelt The Journal of Physical Chemistry A 101 (20), 3731-3740, 1997 | 307 | 1997 |
| Genome-scale thermodynamic analysis of Escherichia coli metabolism CS Henry, MD Jankowski, LJ Broadbelt, V Hatzimanikatis Biophysical journal 90 (4), 1453-1461, 2006 | 286 | 2006 |
| Unraveling the reactions that unravel cellulose HB Mayes, LJ Broadbelt The Journal of Physical Chemistry A 116 (26), 7098-7106, 2012 | 248 | 2012 |
| MINEs: open access databases of computationally predicted enzyme promiscuity products for untargeted metabolomics JG Jeffryes, RL Colastani, M Elbadawi-Sidhu, T Kind, TD Niehaus, ... Journal of cheminformatics 7, 1-8, 2015 | 239 | 2015 |
| The 1-D hindered rotor approximation J Pfaendtner, X Yu, LJ Broadbelt Theoretical Chemistry Accounts 118, 881-898, 2007 | 228 | 2007 |
| Experimental and mechanistic modeling of fast pyrolysis of neat glucose-based carbohydrates. 1. Experiments and development of a detailed mechanistic model X Zhou, MW Nolte, HB Mayes, BH Shanks, LJ Broadbelt Industrial & Engineering Chemistry Research 53 (34), 13274-13289, 2014 | 215 | 2014 |
| A mechanistic model of fast pyrolysis of hemicellulose X Zhou, W Li, R Mabon, LJ Broadbelt Energy & environmental science 11 (5), 1240-1260, 2018 | 199 | 2018 |
| Mechanistic modeling of polymer pyrolysis: polypropylene TM Kruse, HW Wong, LJ Broadbelt Macromolecules 36 (25), 9594-9607, 2003 | 196 | 2003 |
| Discovery and analysis of novel metabolic pathways for the biosynthesis of industrial chemicals: 3‐hydroxypropanoate CS Henry, LJ Broadbelt, V Hatzimanikatis Biotechnology and bioengineering 106 (3), 462-473, 2010 | 195 | 2010 |
| Detailed mechanistic modeling of high-density polyethylene pyrolysis: Low molecular weight product evolution SE Levine, LJ Broadbelt Polymer Degradation and Stability 94 (5), 810-822, 2009 | 188 | 2009 |