[Che-student-staff-list] Graduate Seminar Series - 03 - Dr. Gautam G. Yadav (UEP)

Wed Sep 11 10:47:41 EDT 2019

Dear All,

On behalf of Purdue University's Davidson School of Chemical Engineering, we are glad to announce our upcoming Graduate Seminar Series Lecturer Dr. Gautam G. Yadav from Urban Electric Power (UEP) in New York. He will be visiting Purdue University on 17 Septemeber, 2019. You will find further detail regarding the lecture at the end of this email.

If you have any questions, please do not hesitate to contact me.

Sincerely,

Jason Thorp
Secretary V
Office: FRNY 2043
Purdue University
Charles D. Davidson School of Chemical Engineering
480 Stadium Mall Drive
West Lafayette, IN 47907
Phone: 765-494-7134
jthorp at purdue.edu<mailto:jthorp at purdue.edu>

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Graduate Seminar Series

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Dr. Gautam G. Yadav
Director of Advanced Battery Development
Urban Electric Power (UEP) Inc.

Bio: Dr. Gautam G. Yadav is an expert materials scientist and electrochemist, working as the Director of Advanced Battery Development at Urban Electric Power (UEP) in New York. He earned his doctoral degree in chemical engineering from Purdue University, where he specialized in synthesizing 1D complex metal oxide nanowires for thermoelectric applications and lithium(Li)-ion batteries. Prior to joining UEP, Dr. Yadav worked as a Senior Scientist at the CUNY Energy Institute, where he led the advancement of highly energy dense aqueous-based batteries based on manganese dioxide (MnO2) and zinc (Zn) as a replacement for the expensive and dangerous Li-ion batteries for grid-storage applications. He is the primary inventor of the reversible second-electron MnO2 technology and the breakthrough high voltage (2.45-2.8V) MnO2|Zn battery, which are published in Nature Communications and ACS Energy Letters, respectively. He has authored 19 publications and filed over 26 patents on MnO2|Zn technology, which have been licensed by UEP. At UEP, Dr. Yadav is leading a team of engineers and scientists to bring the second-electron MnO2 and high voltage (2.45-2.8V) MnO2|Zn battery to commercialization.

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"Engineering an Aqueous Energy Dense Manganese Dioxide|Zinc Battery to Challenge Lithium-Ion's Dominance"
Tuesday, September 17, 2019
3:00 p.m. - 4:15 p.m.
FRNY G140

- Reception at 2:30 p.m. in Henson Atrium -
Abstract:
The current landscape of energy storage systems is dominated by lithium-ion batteries because of their high energy densities, and continuous improvement in performance through the last few decades for use in a number of applications. They certainly have been a boon for rapid societal development; however, they also have had major disadvantages like high cost, severe toxicity, high chances of flammability and ethical concerns about the use of cobalt. Aqueous batteries containing manganese dioxide (MnO2) and zinc (Zn) have the theoretical capacities to deliver high energy densities comparable to some variations of lithium-ion batteries, have low cost and toxicity, and high material abundance to be used as an alternative battery compared to the current status quo. However, MnO2 and Zn have been highly irreversible and accessing close to their theoretical capacities has been very challenging. The current status quo in aqueous batteries has been to intercalate Zn and H-ions into layered structures to deliver modest capacities, which also has unfortunately resulted in limited energy densities. These layered structures, although novel, face limitations like their layered counterparts in lithium (Li)-ion batteries, where the capacity is limited to the host's intercalation capacity. Low voltage of ~1.1-1.4V is another Achilles heel of aqueous Zn-anode batteries, where it is simply not comparable to the high voltage properties of Li-ion. MnO2|Zn batteries can compete with Li-ion because of its safe and abundant raw materials, nonflammable electrolyte and theoretical energy density, however, sufficient advances are required for it to be considered a true challenger.

In this talk, we will present a new strategy to enable a new generation of energy dense aqueousbased batteries, where we exploit the conversion reactions of MnO2 and Zn electrodes to extract significantly higher capacity compared to intercalation systems. Accessing the conversion reactions allows us to achieve theoretical capacities of 617 mAh/g (~30 mAh/cm2) from MnO2 and 810 mAh/g (~30 mAh/cm2) from Zn anodes, respectively. The high areal capacities help to attain unprecedented energy densities of 210 Wh/L, which is the highest of all aqueous-based batteries. We will also present our work on identifying new Mn-based conversion compounds that give higher capacities and demonstrate its application in the case of small-scale automobile. We will also present our breakthrough work on breaking the 2V barrier in aqueous Zn batteries, where we have demonstrated for the first time in the field of energy storage 2.45V and 2.8V MnO2|Zn aqueous batteries capable of accessing the theoretical capacity, which can truly challenge Li-ion's dominance. Finally, we will briefly present our commercialization experience, and how market forces and application have guided the design and research of these batteries.

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Davidson School of Chemical Engineering<https://engineering.purdue.edu/ChE>
Purdue University
West Lafayette, IN 47907
(765) 494-4050<tel:+17654944050>

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