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| title | chunk | source | category | tags | date_saved | instance |
|---|---|---|---|---|---|---|
| Calcium looping | 6/6 | https://en.wikipedia.org/wiki/Calcium_looping | reference | science, encyclopedia | 2026-05-05T10:46:20.922266+00:00 | kb-cron |
== Benefits of calcium looping compared with other post-combustion capture processes == Calcium looping compares favorably with several post-combustion capture technologies. Amine scrubbing is the capture technology closest to being market-ready, and calcium looping has several marked benefits over it. When modeled on a 580 MW coal-fired power plant, Calcium looping experienced not only a smaller efficiency penalty (6.7-7.9% points compared to 9.5% for monoethanolamine and 9% for chilled ammonia) but also a less complex retrofitting process. Both technologies would require the plant to be retrofitted for adoption, but the calcium looping retrofitting process would result in twice the net power output of the scrubbing technology. Furthermore, this advantage can be compounded by introducing technology such as cryogenic O2 separation systems. This ups the efficiency of the calcium looping technology by increasing the energy density by 57.4%, making the already low energy penalties even less of an issue. Calcium looping already has an energy advantage over amine scrubbing, but the main problem is that amine scrubbing is the more market-ready technology. However, the accompanying infrastructure for amine scrubbing include large solvent scrubbing towers, the likes of which have never been used on an industrial scale. The accompanying infrastructure for calcium looping capture technologies are circulating fluidized beds, which have already been implemented on an industrial scale. Although the individual technologies differ in terms of current technological viability, the fact that the infrastructure needed to properly implement an amine scrubbing system has yet to be developed keeps calcium looping competitive from a viability standpoint.
== References ==