New Innovation captures carbon from treated wastewater before release.

Scientific Tests had revealed that, when waster water flowing out of the toilets & drains, are treated, raises the Carbon Dioxide Levels in the adjoining water ways.

But recently Two Johns Hopkins University scientists, namely Ruggero Rossi, and Nakyeong Yun have found an innovative way to reduce levels of this common greenhouse gas by running wastewater effluent through a process that uses an electrical current to trigger chemical reactions.

American Chemical Society ES&T Engineering has received the honour of publishing this pathbreaking innovation. This electrochemical CO2 removal from treated wastewater, marks a major step forward in decarbonising water infrastructure.

The United States facilitates more than 16,000 plants treating 22.5 billion gallons of sewage daily. With this innovation in implementation, would prevent up to 12 million metric tons of CO2 emissions per year—about 28% of the sector’s total emissions.

“We need to remove greenhouse gases from the atmosphere, and the easiest one to remove is CO2 because it’s most concentrated“, says Ruggero Rossi, assistant professor in the Department of Environmental Health and Engineering. “People say, ‘Let’s build a plant that captures CO2 from the air. Let’s build plants that capture CO2 from the ocean.’ But there’s no infrastructure for that right now. Before you see any of those plants chipping down the CO2 concentration in the atmosphere, it’s going to be a long time, and a lot of money. This is a way to leverage what we already have”.

Capturing carbon with electricity –

To tackle this problem, Rossi and Nakyeong Yun, a graduate student in geography and environmental engineering, developed and tested an electrochemical cell—essentially a device that uses electricity to change the acidity, or pH levels, of water. The cell was strategically positioned at the end of the water treatment cycle, at the point where the water was released into the environment. The goal was to capture carbon before it escaped into the atmosphere.

The cell works by creating a pH gradient within the water as it flows through. This chemical shift transforms bicarbonate ions—a form of dissolved carbon naturally present in water—into two capturable forms: CO2 gas and solid carbonates like calcium carbonate, a stable, chalky compound. Both forms can then be removed and sequestered. Following the claim, researchers have tested this method using wastewater samples from four treatment plants across the U.S., each with different water chemistry compositions.

A first-of-its-kind strategy –

The 02 member team identified key factors such as conductivity and dissolved carbon content that affect performance and optimised the system to work with real-world wastewater. They also showed that with just a few adjustments—like tweaking the flow rate or electrode spacing—performance could be improved while keeping energy use low.

Over 50 hours of continuous operation proved the system was stable, though it did require occasional cleaning to avoid solid build up inside the cell. “By fine-tuning the system, we were able to capture more than 57% of the dissolved inorganic carbon—mostly as gas at the anode and partly as solid carbonate at the cathode”, Rossi said. “We achieved this with energy demands as low as 3.4 kilowatt-hours per kilogram of CO2, putting our approach on par with or even ahead of many current carbon capture technologies for air or ocean water“.

Renewables are the decisive factor for eliminating Carbon –

Rossi and Yun recognise that because geography, seasons, and even the time of day can change the composition of untreated wastewater, carbon-capture cells are not a one-size-fits-all solution. In addition, since the cells consume energy during operation, they must be powered by renewable energy sources to achieve a net reduction of carbon emissions.

The researchers believe that if proven at larger scales, their approach could become a cost-effective and practical addition to global carbon removal strategies, helping cities lower their environmental footprints without overhauling their existing water infrastructure.

“This proof-of-concept study shows the potential of water reclamation facilities in contributing to a better environment“, Rossi said, “not only cleaning up contaminants from waste streams, but also removing greenhouse gases”.

Team Maverick