Unlocking the Power of Photosynthesis for Clean Energy Production

Unlocking the Power of Photosynthesis for Clean Energy Production

A new grant will allow Rochester researchers to leverage bacteria and nanomaterials to mimic photosynthesis and produce clean-burning hydrogen fuel.

As the world faces an increasing demand for clean and sustainable energy sources, scientists are turning to the power of photosynthesis for inspiration. With the goal of developing new, environmentally friendly techniques to produce clean-burning hydrogen fuel, a team of researchers at the University of Rochester is embarking on a groundbreaking project to mimic the natural process of photosynthesis using bacteria to deliver electrons to a nanocrystal semiconductor photocatalyst.

By leveraging the unique properties of both microorganisms and nanomaterials, the project has the potential to replace current approaches that derive hydrogen from fossil fuels, revolutionizing the way hydrogen fuel is produced and unlocking a powerful source of renewable energy.

The Rochester team, led by Kara Bren, the Richard S. Eisenberg Professor in Chemistry, along with Todd Krauss, a professor of chemistry; Anne S. Meyer, an associate professor of biology; and Andrew White, an associate professor of chemical engineering, received a nearly $2 million, three-year grant from the US Department of Energy (DOE) to create their “living bio-nano system” to produce solar hydrogen.

“Hydrogen is definitely a fuel of high interest for the DOE right now,” Bren says. “If we can figure out a way to efficiently extract hydrogen from water, this could lead to an incredible amount of growth in clean energy.”

Why is hydrogen a promising fuel source?

Hydrogen is “an ideal fuel,” Bren says, “because it’s environmentally-friendly and a carbon-free alternative to fossil fuels.”

Hydrogen is the most abundant element in the universe and can be produced from a variety of sources, including water, natural gas, and biomass.

Unlike fossil fuels, which produce greenhouse gases and other pollutants, when hydrogen is burned, the only byproduct is water vapor. Hydrogen fuel also has a high energy density, which means it contains a lot of energy per unit of weight. It can be used in a variety of applications, including fuel cells, and can be made on both small and large scales, making it feasible for everything from home use to industrial manufacturing.

Why is hydrogen fuel difficult to produce?

Despite hydrogen’s abundance, there is virtually no pure hydrogen on Earth; it is almost always bound to other elements, such as carbon or oxygen, in compounds like hydrocarbons and water. To use hydrogen as a fuel source, it must be extracted from these compounds.

Scientists have historically extracted hydrogen either from fossil fuels, or, more recently, from water. To achieve the latter, there is a major push to employ artificial photosynthesis.

During natural photosynthesis, plants absorb sunlight, which they use to power chemical reactions to convert carbon dioxide and water into glucose and oxygen. In essence, light energy is converted into chemical energy that fuels the organism.

Similarly, artificial photosynthesis is a process of converting an abundant feedstock and sunlight into a chemical fuel, such as producing hydrogen gas from water. Systems that mimic photosynthesis require three components: a light absorber, a catalyst to make the fuel, and a source of electrons. These systems are typically submerged in water, and a light source provides energy to the light absorber. The energy allows the catalyst to combine the provided electrons together with protons from the surrounding water to produce hydrogen gas.

Most of the current systems, however, rely on fossil fuels during the production process or don’t have an efficient way to transfer electrons.

“The way hydrogen fuel is produced now effectively makes it a fossil fuel,” Bren says. “We want to get hydrogen from water in a light-driven reaction so we have a truly clean fuel—and do so in a way that we don’t use fossil fuels in the process.”

What makes the Rochester system unique?

Krauss’s group and Bren’s group have been working for about a decade to develop an efficient system that employs artificial photosynthesis and utilizes semiconductor nanocrystals for light absorbers and catalysts. Semiconductor nanocrystals are tiny crystals made of semiconducting materials. Due to their small size—they are composed of only a few hundred to a few thousand atoms—they have unique properties, which can be easily tuned. Krauss’s lab has made major advances in developing efficient quantum dots, one type of semiconductor nanocrystal.

“Our role in the project is centered on making the nanoparticles that absorb light, and then conducting measurements of the rates of charge transfer in the system,” Krauss says. “This will help us figure out how to eventually scale the system and also make it more efficient.”

Another challenge the researchers faced was figuring out a source of electrons and efficiently transferring the electrons from the electron donor to the nanocrystal. Other systems have used ascorbic acid, commonly known as vitamin C, to deliver electrons back to the system. While vitamin C might seem inexpensive, “you need a source of electrons that is almost free or the system becomes too expensive,” Krauss says.

In a paper published in PNAS, Krauss and Bren demonstrate an unlikely electron donor: bacteria. They found that Shewanella oneidensis, bacteria first gathered from Lake Oneida in upstate New York, offers an effectively free, yet efficient, way to provide electrons to their system.

While other labs have combined nanostructures and bacteria, “all of those efforts are taking electrons from the nanocrystals and putting them into the bacteria, then using the bacterial machinery to prepare fuels,” Bren says. “As far as we know, ours is the first case to go the opposite way and use the bacteria as an electron source to a nanocrystal catalyst.”

What makes bacteria an efficient electron donor?

When bacteria grow under anaerobic conditions—conditions without oxygen—they respire cellular substances as fuel, releasing electrons in the process. Shewanella oneidensis can take electrons generated by its own internal metabolism and donate them to the external catalyst.

“This technique is really promising because it can produce hydrogen energy efficiently while relying only upon sustainable sources for electrons and energy,” says Meyer, whose lab has previously worked with Shewanella oneidensis to produce materials with unique properties. In this project, her lab is designing and creating new strains of Shewanella that will have enhanced abilities to transfer electrons. They will apply their pioneering 3D printing techniques to print living material that can incorporate quantum dots.

“By combining our engineered Shewanella bacteria together with the photocatalyst developed by the Bren and Krauss labs, we will be able to create physically robust, long-lived materials that will make the hydrogen production reaction faster and more efficient,” Meyer says.

Because the system is so complex, White’s lab will use machine learning and artificial intelligence techniques to determine which factors and variables could be changed to optimize the system; for instance, predicting which 3D-printed geometries will be the most likely to produce hydrogen more efficiently.

Pursuing both basic and applied science

While the ultimate goal is to develop a better system for producing hydrogen fuel, Bren is also committed to understanding the basic science behind the project.

“For example,” she says, “how can we most effectively get the electrons from the bacteria to the quantum dots? How do nanomaterials and microorganisms work together?”

Bren envisions that, in the future, individual homes could potentially have vats and underground tanks to harness the power of the sun and produce and store small batches of hydrogen, allowing people to power their homes and cars with inexpensive, clean-burning fuel. Bren notes there are currently trains, buses, and cars powered by hydrogen fuel cells but almost all the hydrogen that is available to power these systems comes from fossil fuels.

“The technology’s out there,” she says, “but until the hydrogen’s coming from water in a light-driven reaction—without using fossil fuels—it isn’t really helping the environment.”

Read the original article on University of Rochester.