Amid the constant drumbeat of campus events, much of the conversation turned toward the challenges we face in energy policy, security and transitions during Duke’s annual Energy Week, held Nov. 11-15.

On the second day, the Innovation Showcase featured not only startups making their pitches for clean energy and sustainable tech products, but students doing so as well. 

Currently in its second year, Duke Design Climate is a new initiative between the Pratt School of Engineering and the Nicholas School of the Environment. It functions as a two-course sequence, in which students form groups to prototype and promote climate solutions after conducting market research.

As I made my rounds to the teams, I met a mix of graduate students and undergraduates with academic backgrounds ranging from engineering to economics to environmental science. The ideas they have aren’t purely theoretical: all are looking for sponsors or partners to help implement their solutions into real-world use. Here were some of the highlights:    

Team ReefCycle is building from plants: Our first stop is named after the company whose product they intend to scale up. Initially, Mary Lempres founded ReefCycle to develop sustainable material for artificial reefs. Regular industrial production for cement requires intensive heating– burning of fossil fuels–releasing tons of carbon dioxide. ReefCycle sought to reduce this climate impact with a different method: their cement is plant-based and enzymatic, meaning its essentially grown using enzymes from beans. Testing in the New York Harbor yielded some promise: the cement appeared to resist corrosion, while becoming home for some oysters. The Design Climate team is now trying to bring it to more widespread use on land, while targeting up to a 90% reduction in carbon emissions across all scopes.

Team Enfield is uplifting a local community: Design Climate, evidently, is by no means limited to science. Instead, these team members intend to address an environmental justice issue close to home: energy inequality. Around 30-35% of Enfield residents live below the poverty line, and yet suffer from some of the highest energy bills in the larger area. Located a ninety minute drive east of Durham, this rural town is one of the poorest in North Carolina. Historic redlining and unfavorable urban planning are responsible for its lack of development, but now this team aims to bring back commerce to the area through microfinance. Once enough funding is gathered from investors and grants, the team hopes to provide microloans and financial literacy to spur and empower businesses. 

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Team Methamatic promotes a pragmatic e-methane solution: This team is harnessing the power of sunlight to drive fuel production. Synthetic methane, commonly referred to as e-methane, is produced by reacting green hydrogen and carbon dioxide. “Currently, the power-to-gas process can be carbon neutral,” said team member Eesha Yaqub, a senior. “Sourcing the recycled carbon dioxide from a carbon capture facility essentially cancels out the emissions from burning methane.” However, this power-to-gas (P2G) process is an intensive one requiring high heat, energy, and pressure–hoops that might not have to be jumped through if an alternative process could break through the market. Professor Jie Liu and the Department of Chemistry have been working on developing a reactor that would conduct this same reaction without those obstacles. “[Utilizing] the energy from ultraviolet light, which is absorbed by a catalyst …makes the process less energy intensive,” Yaqub said.

Right now, the team has a small prototype, but one used for commercial generation would appear much larger and cost between $15,000 to $20,000. Their intended customers? Oil and gas companies under pressure to shift away from fossil fuels. If successfully scaled up, they predict this process would produce e-methane at a price of $5 per kilogram. 

Analyzing living shorelines through Team Coastal Connect: If “Coastal Connect” sounds more like an app than a project name, that’s because it is one. This group is designing what one member dubbed a “fitbit for shorelines”: a monitoring system that brings data from ocean buoys to the phones of local landowners. While measurements in salinity and water level aren’t always telling for the average person, the app would contextualize these into more useful phrases. Is it currently safe to swim? It’ll let you know.

Moreover, it would also allow for the long-term monitoring of living shorelines. While we know this nature-based solution offers resilience to natural disasters and presents erosion, short-term fixes like seawalls are often built instead to continue allowing development up to the edge of beaches. The team hopes that ideally, providing concrete data on living shorelines would allow us to demonstrate their benefits and promote their implementation. 

By Crystal Han, Class of 2028