Inexpensive thermochemical energy storage utilising additive enhanced limestone

Inexpensive thermochemical energy storage utilising additive enhanced limestone

Energy storage is one of the key challenges in our society to enable a transition to renewable energy sources. The endothermic decomposition of limestone into lime and CO2is one of the most cost-effective energy storage systems but it significantly degrades on repeated energy cycling (to below 10% c...

Full description

Bibliographic Details
Main Authors: Møller, K.T., Ibrahim, A., Buckley, Craig, Paskevicius, Mark
Format: Journal Article
Language:English
Published: ROYAL SOC CHEMISTRY 2020
Subjects:
Science & Technology
Physical Sciences
Technology
Chemistry, Physical
Energy & Fuels
Materials Science, Multidisciplinary
Chemistry
Materials Science
CAO-BASED SORBENTS
CO2 CAPTURE
BIFUNCTIONAL CATALYST
CONDUCTIVITY
ALUMINATE
CAPACITY
BATTERY
CARBON
CAZRO3
Online Access:http://purl.org/au-research/grants/arc/FT160100303
http://hdl.handle.net/20.500.11937/91767
Description
Summary:Energy storage is one of the key challenges in our society to enable a transition to renewable energy sources. The endothermic decomposition of limestone into lime and CO2is one of the most cost-effective energy storage systems but it significantly degrades on repeated energy cycling (to below 10% capacity). This study presents the first CaCO3system operating under physical conditions that mimic a real-life ‘thermal battery’ over an extended cycling life. These important results demonstrate that a thermal energy storage device based on CaCO3will be suitable for a range of applications,e.g.concentrated solar power plants, wind farms, photovoltaics, and excess grid energy. The operating temperature of 900 °C ensures a higher Carnot efficiency than state-of-the-art technologies at a fraction of the material cost. The capacity degradation of pure CaCO3as a function of calcination/carbonation cycling is overcome by the addition of either ZrO2(40 wt%) or Al2O3(20 wt%), which results in 500 energy storage cycles at over 80% capacity. The additives result in the formation of ternary compounds,e.g.CaZrO3and Ca5Al6O14, which restrict sintering and allow for the transmission of Ca2+and O2-ions to reaction sites.

Similar Items