Lawrence Livermore scientists have discovered and demonstrated a new technique to remove and store atmospheric¹ carbon dioxide while generating carbon-negative hydrogen and producing alkalinity（碱性）, which can be used to offset² ocean acidification. The team demonstrated, at a laboratory scale, a system that uses the acidity³ normally produced in saline water electrolysis to accelerate silicate⁴ mineral dissolution while producing hydrogen fuel and other gases. The resulting electrolyte solution was shown to be significantly elevated in hydroxide concentration that in turn proved strongly absorptive and retentive⁵ of atmospheric CO2.

 

Further, the researchers suggest that the carbonate and bicarbonate produced in the process could be used to mitigate⁶ ongoing⁷ ocean acidification, similar to how an Alka Seltzer neutralizes⁹ excess acid in the stomach.

 

"We not only found a way to remove and store carbon dioxide from the atmosphere while producing valuable H2, we also suggest that we can help save marine¹⁰ ecosystems¹¹ with this new technique," said Greg Rau, an LLNL visiting scientist, senior scientist at UC Santa Cruz and lead author of a paper appearing this week (May 27) in the Proceedings¹² of the National Academy of Sciences.  When carbon dioxide is released into the atmosphere, a significant fraction is passively taken up by the ocean forming carbonic acid that makes the ocean more acidic. This acidification has been shown to be harmful to many species of marine life, especially corals and shellfish. By the middle of this century, the globe will likely warm by at least 2 degrees Celsius¹³ and the oceans will experience a more than 60 percent increase in acidity relative to pre-industrial levels. The alkaline solution generated by the new process could be added to the ocean to help neutralize⁸ this acid and help offset its effects on marine biota¹⁴. However, further research is needed, the authors said.

 

"When powered by renewable electricity and consuming globally abundant minerals and saline solutions, such systems at scale might provide a relatively¹⁵ efficient, high-capacity means to consume and store excess atmospheric CO2 as environmentally beneficial seawater bicarbonate or carbonate," Rau said. "But the process also would produce a carbon-negative 'super green' fuel or chemical feedstock in the form of hydrogen."

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