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40. Disparate Redox Potentials in Mixed Isomer Electrolytes Reduce Voltage Efficiency of Energy Dense Flow Batteries
Davis, C.M.; Waters, S.E.; Robb, B.H.; Thurston, J.R.; Reber, D.; Marshak, M.P.
Batteries 2023, 9, 573. DOI:

39. Beyond energy density: flow battery design driven by safety and location
Reber, D.; Jarvis, S. R.; Marshak, M. P.
Energy Adv., 2023, 2, 1357–1365. DOI: 

38. Sulfonated Diels-Alder Poly(phenylene) Membrane for Efficient Ion-Selective Transport in Aqueous Metalorganic and Organic Redox Flow Batteries
Robb, B. H.; George, T. Y.; Davis, C. M.; Tang Z.; Fujimoto, Cy.; Aziz, M. J.; Marshak, M. P.
J. Electrochem. Soc.  2023, 170, 030515. DOI: 

37. Stability of highly soluble ferrocyanides at neutral pH for energy-dense flow batteries
Reber, D.; Thurston, J. R.; Beker, M.; Marshak, M. P.
Cell Reports Phys. Sci. 2023, 4, 101215. DOI: 

36. The role of energy density for grid-scale batteries
Reber, D.; Jarvis, S. R.; Marshak, M. P.
ChemRxiv. 2022. DOI: 

35. Realized potential as neutral pH flow batteries achieve high power densities
Robb, B. H.; Waters, S. E.; Saraidaridis, J. D.; Marshak, M. P.
Cell Reports Phys. Sci. 2022, 3, 101118. DOI: 

34. Monitoring Ion Exchange Chromatography with Affordable Flame Emission Spectroscopy
Thurston, J. E.; Marshak, M. P.; Reber, D.
J. Chem. Educ. 2022, 99, 4051–4056. DOI: 

33. Maximizing Vanadium Deployment in Redox Flow Batteries Through Chelation
Waters, S. E.; Davis, C. M.; Thurston, J. E.; Marshak, M. P. 
J. Am. Chem. Soc. 2022, 144, 17753–17757. DOI: 

32. High Energy Density Chelated Chromium Flow Battery Electrolyte at Neutral pH
Robb, B. H.; Waters, S. E.; Marshak, M. P. 
Chem Asian J. 2022, 17, e202200700. DOI: 

31. Transport of Ligand Coordinated Iron and Chromium through Cation-Exchange Membranes
Saraidaridis, J. D.; Darling, R. M.; Yang, Z.; Fortin, M. E.; Shovlin, C.; Robb, B. H.; Waters, S. E.; Marshak, M. P.
J. Electrochem. Soc. 2022, 169, 060532. DOI: 

30. Isolation and characterization of a highly reducing aqueous chromium (II) complex
Waters, S. E.; Robb, B. H.; Scappaticci, S. J.; Saraidaridis, J. D.; Marshak, M. P.
Inorg. Chem. 2022, 61, 8752–8759. DOI: 

29. Mediating anion-cation interactions to improve aqueous flow battery electrolytes
Reber, D.; Thurston, J. R.; Becker, M.; Pache, G. F.; Wagoner, M. E.; Robb, B. H.; Waters, S. E.; Marshak, M. P.
Appl. Mater. Today 2022, 28, 101512. DOI: 

28. Bismuth Electrocatalyst Enabling Reversible Redox Kinetics of a Chelated Chromium Flow Battery Anolyte
Proctor, A. D.; Robb, B. H.; Saraidaridis, J. D.; Marshak, M. P.
J. Electrochem. Soc. 2022, 169, 030506. DOI: 

27. Holistic design principles for flow batteries: Cation dependent membrane resistance and active species solubility
Waters, S. E.; Thurston, J. R.; Armstrong, R. W.; Robb, B. H.; Marshak, M. P.; Reber, D. 
J. Power Sources 2022, 520, 230877. DOI: 

26. Iron Flies Higher
Marshak, M. P.
Nature Energy2021, 6, 854–855. DOI: 

25. Synthesis, reactivity, and crystallography of a sterically hindered acyl triflate
Crossman, A. S.; Shi, J. X.; Krajewski, S. M.; Maurer, L. M.; Marshak, M.P.
Tetrahedron2021. 94, 132308. DOI: 
*2021 Editors’ Choice Collection

24. Open for bismuth: main group metal-to-ligand charge transfer
Maurer, L. M.; Pearce, O. M.; Maharaj, F. D. R; Brown, N. L.; Amador, C. A.; Damrauer, N. H.; Marshak, M. P.
Inorg. Chem. 2021. 60, 10137–10146 DOI: 

23. Organic and Metal-Organic RFBs
Thurston, J. R.; Waters, S. E.; Robb, B. H.; Marshak, M.P 
Encyclopedia of Energy Storage 2021. DOI: 

22. β-Diketones: Coordination and Application
Crossman, A. S. and Marshak, M. P.
Comprehensive Coordination Chemistry III. 2021, DOI: 

21. Evaluating Aqueous Flow Battery Electrolytes: A Coordinated Approach
Robb, B. H.; Waters, S. E.; Marshak, M. P.
Dalton Trans., 2020, 49, 16047–16053. DOI: 

20. Minimizing Oxygen Permeation in Metal-Chelate Flow Batteries
Robb, B. H.; Waters, S. E.; Marshak, M. P.
ECS Trans. 2020, 97, 237–245. DOI: 

19. Effect of Chelation on Iron-Chromium Redox Flow Batteries
Waters, S. E.; Robb, B. H.; Marshak, M. P.
ACS Energy Lett. 2020, 6, 1758–1762. DOI: 

18. Group 4 Organometallics Supported by Sterically Hindered β‐Diketonates
Hopkins, E. J.; Krajewski, S. M.; Crossman, A. S.; Maharaj, F. D. R.; Schwanz, L. T.; Marshak, M. P.
Eur. J. Inorg. Chem. 2020, 20, 1951–1959. DOI: 

17. Titanium-Anthraquinone Material as a New Design Approach for Electrodes in Aqueous Rechargeable Batteries
Maharaj, F. D. R.; Marhsak, M. P.
Energies, 2020, 13, 1722. DOI: 

16. Copper(II) as a Platform for Probing the Steric Demand of Bulky β-Diketonates
Larson, A. T.; Crossman, A. S.; Krajewski, S. M.; Marshak, M. P.
Inorg. Chem. 2020, 59, 423–432. DOI: 

15. Chelated Chromium Electrolyte Enabling High-Voltage Aqueous Flow Batteries
Robb, B. H.; Farrell, J. M.; Marshak, M. P. 
Joule, 2019. 3, 2503–2512. DOI: 

14. Sterically encumbered β-diketonates and base metal catalysis
Krajewski, S. M.; Crossman, A. S.; Akturk, E. S.; Suhrbier, T.; Scappaticci, S. J.; Staab, M. W.; Marshak, M. P.
Dalton Trans. 2019. 48, 10714–10722. DOI: 

13. Exploring Real-World Applications of Electrochemistry by Constructing a Rechargeable Lithium Ion Battery
Maharaj, F. D. R.; Wu, W.; Zhou, Y,; Schwanz, L. T.; Marshak, M. P.
J. Chem. Educ. 2019, 96, 3014–3017. DOI: 

12. Synthesis of Sterically Hindered β-Diketones via Condensation of Acid Chlorides with Enolates
Crossman, A. S.; Larson, A. T.; Shi, J. X.; Krajewski, S. M.; Akturk, E. S.; Marshak, M. P.
J. Org. Chem. 2019. 84, 7434–7442. DOI: 

11. Bulky β-Diketones Enabling New Lewis Acidic Ligand Platforms
Akturk, E. S.; Scappaticci, S. J.; Seals, R. N.; Marshak, M. P.
Inorg. Chem.2017. 56, 11466–11469. DOI: 

10. My trek back to science
Marshak, M. P.
Science 2015, 349, 1406. DOI: 

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9. Anthraquinone Derivatives in Aqueous Flow Batteries
Gerhardt, M. R.; Tong, L.; Gómez‐Bombarelli, R.; Chen, Q.; Marshak, M. P.; Galvin, C. J.; Aspuru-Guzik, A.; Gordon, R. G.; Aziz, M. J.
Adv. Energy Mater. 2017. 7, 1601488. DOI: 

8. Alkaline quinone flow battery
Lin, K.; Chen, Q.; Gerhardt, M. R.; Tong, L.; Kim, S. B.; Eisenach, L.; Valle, A. W.; Hardee, D.; Gordon, R. G.; Aziz, M. J.; Marshak, M. P.
Science2015, 349, 1529–1532. DOI: 

7. Computational design of molecules for an all-quinone redox flow battery
Er, S.; Suh, C.; Marshak, M. P.; Aspuru-Guzik, A.
Chem. Sci. 2015, 6, 885–893. ​DOI: 

6. Cycling of a Quinone-Bromide Flow Battery for Large-Scale Electrochemical Energy Storage
Huskinson, B.; Marshak, M. P.; Gerhardt, M. R.; Aziz, M. J.
ECS Trans. 2014, 61, 27–30. DOI: 

5. A metal-free organic-inorganic aqueous flow battery
Huskinson, B.; Marshak, M. P.; Suh, C.; Er, S.; Gerhardt, M. R.; Galvin, C. J.; Chen, X.; Aspuru-Guzik, A.; Gordon, R. G.; Aziz, M. J.
Nature 2014, 505, 195–198. DOI: 

4. Lewis Bases Trigger Intramolecular CH–Bond Activation: (tBu3SiO)2W=NtBu [rlhar2] (tBu3SiO)(κO,κC-tBu2SiOCMe2CH2)HW=NtBu
Marshak, M. P.; Rosenfeld, D. C.; Morris, W. D.; Wolczanski, P. T.; Lobkovsky, E. B.; Cundari, T. R.
Eur. J. Inorg. Chem. 2013,&�Բ�����;4056–4067.&�Բ�����;�ٰ���:&�Բ�����;

3. Chromium(IV) Siloxide
Marshak, M. P.; Nocera, D. G.
Inorg. Chem. 2013, 52, 1173–1175. DOI: 

2. Cobalt in a Bis-β-diketiminate Environment
Marshak, M. P.; Chambers, M. B.; Nocera, D. G.
Inorg. Chem. 2012, 51, 11190–11197. DOI: 

1. Thermodynamics, Kinetics, and Mechanism of (silox)3M(olefin) to (silox)3M(alkylidene) Rearrangements (silox = tBu3SiO; M = Nb, Ta)
Hirsekorn, K. F.; Veige, A. S.; Marshak, M. P.; Koldobskaya, Y.; Wolczanski, P. T.; Cundari, T. R.; Lobkovsky, E. B.
J. Am. Chem. Soc. 2005, 127, 4809–4830. DOI: