NGenE selects up to 40 advanced graduate students and postdocs from around the country to partake in what is an intense week-long summer workshop that explores advanced topics in electrochemistry. They spend five days with ten distinguished researchers and lecturers to identify and elaborate on the most important unsolved electrochemical research challenges. They approach these questions through lectures and discussions, research project planning, mentoring, site visits, and demonstrations. The program takes place at the University of Illinois at Chicago, with a day trip to Argonne National Laboratory for lectures and demonstrations of the Advanced Photon Source and the Joint Center for Energy Storage Research's Electrochemical Discovery Laboratory.
The program prioritizes 1) the discussion of unsolved challenges in electrochemistry that the coming generations will need to address, and 2) the identification of representative innovative, forward-looking multi-modal experiments, theory, and simulation to solve them.
Student Research Projects
Participants are active players during NGenE. Working in teams, they choose one of the top unsolved challenges in electrochemistry and then develop a scientific program to solve the problem through innovative experiments and theory. On the final day of the program, each team presents its findings before their peers and a set of expert judges.
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Electrochemistry – the manipulation of electrical charge to drive chemical change – is central to applications and devices in fields as varied as medicine, environmental remediation and energy, and integrates concepts spanning chemistry, physics and engineering. Despite its reach and importance, electrochemistry has advanced more slowly over the last two decades than many companion fields such as nanoscience or semiconductors. Next Generation Electrochemistry (NGenE) will focus on the existing and emerging challenges in electrochemistry, and the application of innovative strategies in synthesis, characterization, theory and simulation to address these challenges.
NGenE is an annual event with content rotating among the unsolved fundamental electrochemical challenges and applications. Students and lecturers spend significant time talking and developing relationships that – we hope! – may become long term mentor-protégé bonds. The most talented students may return for subsequent institutes. With over 30 students per year, NGenE aims to influence the strategic directions of electrochemical science in the United States in the decades to come.
Because the focus is on the frontiers of research and not the intricacies of what is known, NGenE graduate students and postdocs are among the brightest in their fields. The program challenges lecturers and participants to identify the most important questions for next generation research and to design innovative experimental and theoretical approaches to answer these questions. Therefore, participants are expected to absorb and exchange information at a high level. Relevant questions include:
- What are the most important unsolved issues in a given area of electrochemistry?
- What do we know for each part and how do we know it?
- What do we want to know but do not know, and how we would go about finding it out?
- What intuition or experience guides our speculation about what could happen?
Friends of NGenE
NGenE 2021: Inescapable
In recent years we have witnessed a boom in research areas leveraging electrochemistry for diverse uses and applications. NGenE 2021 seeks to showcase the stunning breadth of topics that now depend on advances in electrochemical knowledge. Simultaneously, NGenE 2021 will highlight how many unresolved questions cut across possible applications, meaning that progress at a fundamental level can have a widespread technological and social impact.
The 2021 program will stream live on YouTube June 14-16, 2021. Doctoral students and postdocs interested in being “in” the room with the panel, please contact Thomas at email@example.com
June 14, 2021
Can electrochemistry replace thermochemistry in industry? // 10:00-11:30 AM CST
- Marta Hatzell (Georgia Tech)
- Khartish Mathiram (MIT)
- Dan Steingart (Columbia U.)
- Iryna Zenyuk (UC Irvine)
Frontiers in electrocatalysis // 1:00-2:30PM CST
Frontiers in solvation science applied to electrochemistry // 3:00-4:30PM CST
June 15, 2021
Frontiers in neuroelectrochemistry // 10:00-11:30AM CST
- Christy Haynes (U. Minnesota)
- Janine Mauzeroll (McGill U.)
- Mei Shen (U. Illinois Urbana-Champaign)
- Jill Venton (U. Virginia)
Frontiers in our understanding of local effects in electrochemistry // 1:00-2:30PM CST
Ask me anything about batteries // 3:00-4:30PM CST
- Venkat Srinivasan (ANL)
June 16, 2021
Frontiers in corrosion // 10:00-11:30AM CST
- Santanu Chaudhuri (U. Illinois at Chicago/Argonne)
- Adrien Couet (U. Wisconsin-Madison)
- Jason Hattrick-Simpers (NIST)
Publishing electrochemical research // 1:00-2:30PM CST
Career Panel // 3:00-4:30PM CST
NGenE 2020: All Livestream Panels
Due to the Coronavirus, NGenE 2020 went all digital. Check out the panels on this playlist:
I. NGenE 2020 Announcement
II. Frontiers in Energy Storage: Batteries are now an innovation worthy of a Nobel Prize. But, are we done making them better? What fundamental questions remain in electrochemistry that impede further meaningful advances? What are the limits that can be reached with electrochemical energy storage?
With Stan Whittingham (Binghamton University), Héctor D. Abruña (Cornell University), George Crabtree (Argonne National Laboratory, University of Illinois at Chicago), and Clare Grey (Cambridge University).
III. Integrating computational and experimental approaches at the electrochemical frontiers: Many frontier challenges in electrochemical research are becoming too large for a single approach to solve them. It is increasingly important to create feedback loops between computational and experimental methods, and integrate their power wherever possible. But this goal is easier said than done. This panel will promote a dialog between disciplines that are very often walled off. What kind of experimental inputs would models benefit from? How could experiments and characterization be best guided by computations? Can computational analysis directly be integrated into data analysis of experiments?
IV. Frontiers in electrochemistry at the water/energy nexus: Access to clean water is a vital tenet of a healthy society. Yet climate change and increases in consumption of energy place severe pressures on the water supply. How can emerging technologies based on electrochemistry contribute to producing clean water that is safe to drink? What fundamental barriers in electrochemistry must be addressed for these technologies to have a meaningful impact?
With Jelena Radjenovic (Institut Català de Recerca de l’Aigua, Spain), David Jassby (University of California, Los Angeles), Brian Chaplin (University of Illinois at Chicago), and Douglas Call (North Carolina State University).
V. Frontiers in organic electrochemistry: Electrochemical driving forces are a powerful means to reach chemical states extremely far from equilibrium. They have opened up new routes toward sophisticated modifications of organic compounds. What are the opportunities in the area of organic electrochemistry? How far are we in our ability to control carbon bonds with electrochemistry? What new knowledge is urgently needed for leaps in our current ability?