posted on 2022-10-19, 18:03authored byJörg S. Deutzmann, Frauke Kracke, Wenyu Gu, Alfred M. Spormann
Microbial
electrosynthesis (MES) of acetate is a process using
electrical energy to reduce CO2 to acetic acid in an integrated
bioelectrochemical system. MES powered by excess renewable electricity
produces carbon-neutral acetate while benefitting from inexpensive
but intermittent energy sources. Interruptions in electricity supply
also cause energy limitation and starvation of the microbial cells
performing MES. Here, we studied the effect of intermittent electricity
supply on the performance of hydrogen-mediated MES of acetate. Thermoanaerobacter kivui produced acetic acid for
more than 4 months from intermittent electricity supplied in 12 h
on–off cycles in a semicontinuously-fed MES system. After current
interruptions, hydrogen utilization and acetate synthesis rates were
severely diminished. They did not recover to the steady-state rates
of continuous MES within the 12 h current-on period under most conditions.
Accumulating high product (acetate) concentration exacerbated this
effect and prolonged recovery. However, supply of a low background
current of 1–5% of the maximum current during “off-times”
reduced the impact of current interruptions on subsequent MES performance.
This study presents sustained MES at a rate of up to 2 mM h–1 acetate at an average concentration of 60–90 mM by a pure
thermophilic microbial culture powered by intermittent electricity.
We identified product inhibition of accumulating acetic acid as a
key challenge to improving the efficiency of intermittently powered
MES.