(* = corresponding author, † = equal contribution)

Under Review

33.    The Materials Project: A Decade of Materials Discovery

M.K. Horton, P. Huck, R.X. Yang, J. M. Munro, S. Dwaraknath, A.M. Ganose, R.S. Kingsbury, M. Wen, J.-X. Shen, T.S. Mathis, A.D. Kaplan, K. Berket, J. Riebesell, J. George, A.S. Rosen, E.W.C. Spotte-Smith, M.J. McDermott, O.A. Cohen, A. Dunn, M. Kuner,  G.M. Rignanese, G. Hautier, G. Petretto, D. Waroquiers, S.M. Griffin, J.B. Neaton, D.C. Chrzan, M. Asta, S. Cholia, G. Ceder, S.P. Ong, A. Jain, and K.A. Persson* (under review).

32.    cclib 2.0: An Updated Architecture for Interoperable Computational Chemistry

E. Berquist^†, A. Dumi^†, S. Upadhyay^†, O.D. Abarbanel, M. Cho, S. Gaur, V. Hugo Cano Gil, G.R. Hutchinson, O.S. Lee, A.S. Rosen, S. Schamnad, F.S.S. Schneider, C. Steinmann, M. Stolyarchuk, J.E. Vanderzande, W. Zak, K.M. Langner (under review).

31.    Deep Learning of Ab Initio Hessians for Transition State Optimization
E.C.-Y. Yuan, A. Kumar, X. Guan, E.D. Hermes, A.S. Rosen, J. Zádor, T. Head-Gordon*, S.M. Blau*, arXiv:2405.02247 (2024).

30.    A Foundation Model for Atomistic Materials Chemistry
I. Batatia^†, P. Benner^†, Y. Chiang^†, A.M. Elena^†, D.P. Kovács^†, J. Riebesell^†, X.R. Advincula, M. Asta, M. Avaylon, W.J. Baldwin, F. Berger, N. Bernstein, A. Bhowmik, S.M. Blau, V. Cărare, J.P. Darby, S. De, F. Della Pia, V.L. Deringer, R. Elijošius, Z. El‑Machachi, F. Falcioni, E. Fako, A.C. Ferrari, A. Genreith‑Schriever, J. George, R.E.A. Goodall, C.P. Grey, S. Han, W. Handley, H.H. Heenen, K. Hermansson, C. Holm, S. Hofmann, J. Jaafar, S. Hofmann, K.S. Jakob, H. Jung, V. Kapil, A.D. Kaplan, N. Karimitari, J.R. Kermode, N. Kroupa, J. Kullgren, M.C. Kuner, D. Kuryla, G. Liepuoniute, J.T. Margraf, I.‑B. Magdău, A. Michaelides, J.H. Moore, A.A. Naik, S.P. Niblett, S.W. Norwood, N. O’Neill, C. Ortner, K.A. Persson, K. Reuter, A.S. Rosen, L.L. Schaaf, C. Schran, B.X. Shi, E. Sivonxay, T.K. Stenczel, V. Svahn, C. Sutton, T.D. Winburne, J. Tilly, C. van der Oord, S. Vargas, E. Varga‑Umbrich, T. Vegge, M. Vondrák, Y. Wang, W.C. Witt, F. Zills, G. Csányi*, arXiv:2401.00096 (2024).

29.     Investigating the Behavior of Diffusion Models for Accelerating Electronic Structure Calculations
D. Rothchild, A.S. Rosen, E. Taw, C. Robinson, J.E. Gonzalez*, A.S. Krishnapriyan*, arXiv:2311.01491 (2023).
 

Published

28.     MOFDiff: Coarse‑Grained Diffusion for Metal–Organic Framework Design
X. Fu, T. Xie, A.S. Rosen, T.S. Jaakkola, J.A. Smith*, International Conference on Learning Representations (2024).

27.     Structured Information Extraction from Scientific Text with Large Language Models
J. Dagdelen, A. Dunn, S. Lee, N. Walker, A.S. Rosen, G. Ceder, K.A. Persson, A. Jain*, Nature Communications, 15, 1418 (2024).

26.    Jobflow: Computational Workflows Made Simple

A.S. Rosen, M. Gallant, J. George, J. Riebesell, H. Sahasrabuddhe, J.X. Shen, M. Wen, M.L. Evans, G. Petretto, D. Waroquiers, G.‑M. Rignanese, K.A. Persson, A. Jain, A.M. Ganose*, Journal of Open Source Software, 9, 5995 (2024).

25.    Vinyl Tetrazine‑Linked Covalent Organic Frameworks with Acid Sensing and Photocatalytic Activity
A. Zadehnazari, A. Khosropour, A.A. Altaf, A.S. Rosen, A. Abbaspourrad*, Advanced Materials, 2311042 (2024).

24.     Formation of an Unprecedented Uranium Paddlewheel in a Catecholate‑Based Metal–Organic Framework
J.G. Knapp, X. Wang, A.S. Rosen, X. Wang, X. Gong, M. Schneider, T. Elkin, K.O. Kirlikovali, M. Fairley, M.D. Krzyaniak, M.R. Wasielewski, N.C. Gianneschi, R.Q. Snurr, O.K. Farha*, Angewandte Chemie International Edition, 62, e202305526 (2023).

23.     An Ecosystem for Digital Reticular Chemistry

K.M. Jablonka, A.S. Rosen, A.S. Krishnapriyan, B. Smit*, ACS Central Science, 9, 563–581 (2023).

22.     Free‑Atom‑Like d States Beyond the Dilute Limit of Single‑Atom Alloys
A.S. Rosen, S. Vijay, K.A. Persson*, Chemical Science, 14, 1503–1511 (2023).

21.     Effect of Composition and Local Environment on CO₂ Adsorption on Nickel and Magnesium Oxide Solid Solutions
A. Peng, A.S. Rosen, R.Q. Snurr*, H. Kung*, Journal of Physical Chemistry C, 126, 19705–19714 (2022).

20.     A Flexible and Scalable Scheme for Mixing Computed Formation Energies from Different Levels of Theory
R. Kingsbury, A.S. Rosen, A. Gupta, J. Munro, S.P. Ong, A. Jain, S. Dwaraknath, M.K. Horton, K.A. Persson*, npj Computational Materials, 8, 195 (2022).

19.     High‑Throughput Predictions of Metal–Organic Framework Electronic Properties: Theoretical Challenges, Graph Neural Networks, and Data Exploration
A.S. Rosen*, V. Fung, P. Huck, C.T. O’Donnell, M.K. Horton, D.T. Truhlar, K.A. Persson, J.M. Notestein, R.Q. Snurr, npj Computational Materials, 8, 112 (2022).
— Highlighted in MRS Bulletin, 47, 886 (2022).

18.    Exploring Mechanistic Routes for Light Alkane Oxidation with an Iron‑Triazolate Metal–Organic Framework
A.S. Rosen, J.M. Notestein*, R.Q. Snurr*, Physical Chemistry Chemical Physics, 24, 8129–8141 (2022).
— Selected by the editors as a 2022 HOT PCCP article.

17.    Realizing the Data‑Driven, Computational Discovery of Metal–Organic Framework Catalysts
A.S. Rosen, J.M. Notestein*, R.Q. Snurr*.  Current Opinion in Chemical Engineering, 35, 100760 (2022).

16.    Fine‑Tuning A Robust Metal–Organic Framework Towards Enhanced Clean Energy Gas Storage
Z. Chen, M.R. Mian, S.‑J. Lee, H. Chen, X. Zhang, K.O. Kirlikovali, S. Shulda, P. Melix, A.S. Rosen, P.A. Parilla, T. Gennett, R.Q. Snurr, T. Islamoglu*, T. Yildrim*, O.K. Farha*, Journal of the American Chemical Society, 143, 18838–18843 (2021).

15.    Machine Learning the Quantum‑Chemical Properties of Metal–Organic Frameworks for Accelerated Materials Discovery
A.S. Rosen*, S.M. Iyer, D. Ray, Z. Yao, A. Aspuru‑Guzik, L. Gagliardi, J.M. Notestein, R.Q. Snurr, Matter, 4, 1578–1597 (2021).
— Featured on the cover of Matter and previewed in Patterns, 2, 100239 (2021).

14.    Zr₆O₈ Node‑Catalyzed Butene Hydrogenation and Isomerization in the Metal–Organic Framework NU‑1000
K.E. Hicks, A.S. Rosen, Z.H. Syed, R.Q. Snurr, O.K. Farha*, J.M. Notestein*, ACS Catalysis, 10, 14959–14970 (2020).

13.     Supramolecular Porous Assemblies of Atomically Precise Catalytically Active Cerium‑Based Clusters
M.C. Wasson, X. Zhang, K. Otake, A.S. Rosen, S. Alayoglu, M.D. Krzyaniak, Z. Chen, L.R. Redfern, L. Robison, F.A. Son, Y. Chen, T. Islamoglu, J.M. Notestein, R.Q. Snurr, M.R. Wasielewski, O.K. Farha*, Chemistry of Materials, 32, 8522– 8529 (2020).

12.    Comparing GGA, GGA+U, and Meta‑GGA Functionals for Redox‑Dependent Binding at Open Metal Sites in Metal–Organic Frameworks 
A.S. Rosen, J.M. Notestein*, R.Q. Snurr*, Journal of Chemical Physics, 152, 24101 (2020).

11.    Topological Effects on Separation of Alkane Isomers in Metal–Organic Frameworks
N.S. Bobbitt, A.S. Rosen, R.Q. Snurr*, Fluid Phase Equilibria, 519, 112642 (2020).

10.    High‑Valent Metal‑Oxo Species at the Nodes of Metal–Triazolate Frameworks: The Effects of Ligand Exchange and Two‑State Reactivity for C–H Bond Activation
A.S. Rosen, J.M. Notestein*, R.Q. Snurr*, Angewandte Chemie International Edition, 59, 19494–19502 (2020).

9.     Tuning the Redox Activity of Metal−Organic Frameworks for Enhanced, Selective O₂ Binding: Design Rules and Ambient Temperature O₂ Chemisorption in a Cobalt−Triazolate Framework
A.S. Rosen, M.R. Mian, T. Islamoglu, O.K. Farha, J.M. Notestein, R.Q. Snurr*, Journal of the American Chemical Society, 142, 4317–4328 (2020).

8.     Identification Schemes for Metal–Organic Frameworks to Enable Rapid Search and Cheminformatics Analysis
B.J. Bucior, A.S. Rosen, M. Haranczyk, Z. Yao, M.E. Ziebel, O.K. Farha, J.T. Hupp, J.I. Siepmann, A. Aspuru‑Guzik, R.Q. Snurr*, Crystal Growth and Design, 19, 6682–6697 (2019).

7.     Structure–Activity Relationships that Identify Metal–Organic Framework Catalysts for Methane Activation
A.S. Rosen, J.M. Notestein*, R.Q. Snurr*, ACS Catalysis, 9, 3576–3587 (2019).
— Featured in C&EN

6.     Identifying Promising Metal–Organic Frameworks for Heterogeneous Catalysis via High‑Throughput Periodic Density Functional Theory
A.S. Rosen, J.M. Notestein*, R.Q. Snurr*, Journal of Computational Chemistry, 40, 1305–1318 (2019).

5.     Evidence for Copper Dimers in Low‑Loaded CuO𝑥/SiO₂ Catalysts for Cyclohexane Oxidative Dehydrogenation
S.L. Nauert, A.S. Rosen, H. Kim, R.Q. Snurr, P.C. Stair, J.M. Notestein*, ACS Catalysis, 8, 9775–9789 (2018).

4.     Comprehensive Phase Diagrams of MoS₂ Edge Sites Using Dispersion‑Corrected DFT Free Energy Calculations
A.S. Rosen, J.M. Notestein*, R.Q. Snurr*, Journal of Physical Chemistry C, 122, 15318–15329 (2018).

3.     Correlations, Trends and Potential Biases among Publicly Accessible Web‑Based Student Evaluations of Teaching
A.S. Rosen*, Assessment and Evaluation in Higher Education, 43, 31–44 (2018).
— Featured in Inside Higher Ed and VOA News

2.     A Detailed Combined Experimental and Theoretical Study on Dimethyl Ether/Propane Blended Oxidation 
E.E. Dames, A.S. Rosen, B.W. Weber, C.W. Gao, C‑J. Sung, W.H. Green*, Combustion and Flame, 168, 310–330 (2016).

1.    Validation of X‑ray Line Ratios for Electron Temperature Determination in Tokamak Plasmas 
A.S. Rosen, M.L. Reinke*, J.E. Rice, A.E. Hubbard, J.W. Hughes, Journal of Physics B, 47, 105701 (2014).
— Selected as an article representing “the best work published in the Journal of Physics B in 2014”
 

Editorials

1.     Reflections in Search of Faculty Positions
H. Mao, A.S. Rosen, D. Sanchez, V. Sanchez, S. Cranford*, Matter, 6, 300–307 (2023).