https://novaprd-lb.newcastle.edu.au/vital/access/ /manager/Index en-au 5 https://novaprd-lb.newcastle.edu.au/vital/access/ /manager/Repository/uon:39596 Wed 15 Jun 2022 12:47:16 AEST ]]> https://novaprd-lb.newcastle.edu.au/vital/access/ /manager/Repository/uon:51674 Wed 13 Sep 2023 13:23:44 AEST ]]> https://novaprd-lb.newcastle.edu.au/vital/access/ /manager/Repository/uon:53691 Wed 10 Jan 2024 10:34:44 AEDT ]]> https://novaprd-lb.newcastle.edu.au/vital/access/ /manager/Repository/uon:51088 Wed 06 Mar 2024 15:14:42 AEDT ]]> https://novaprd-lb.newcastle.edu.au/vital/access/ /manager/Repository/uon:48220 Sat 11 Mar 2023 12:36:58 AEDT ]]> https://novaprd-lb.newcastle.edu.au/vital/access/ /manager/Repository/uon:49526 Mon 22 May 2023 08:31:22 AEST ]]> https://novaprd-lb.newcastle.edu.au/vital/access/ /manager/Repository/uon:51383 Mon 04 Sep 2023 10:37:52 AEST ]]> https://novaprd-lb.newcastle.edu.au/vital/access/ /manager/Repository/uon:46157 2 g⁻¹). The optimized material exhibits a high surface area of 2278m² g⁻¹ and a pore volume of 1.00 cm³ g⁻¹. As high microporosity is beneficial for CO₂ adsorption, the prepared materials are employed as adsorbents for the capture of CO₂. The optimized sample displays excellent CO₂ uptakes at 0 °C/0.15 bar (1.1–1.8 mmol g⁻¹) and 0 °C/1 bar (4.3–6.1 mmol g⁻¹). The high surface area of the materials allows for high CO₂ uptakes at 0 °C/30 bar (17.3–22.0 mmol g⁻¹). The microporosity of these high surface area carbons is further decorated with strontium carbonate nanoparticles. The adsorption capacity per unit surface area is increased significantly upon the incorporation of the nanoparticles, revealing the role of the nanoparticles on the enhancement of the CO₂ adsorption capacity. A similar strategy could be extended for the fabrication of a series of microporous carbons derived from biomass for many applications including CO₂ capture.]]> Fri 11 Nov 2022 19:13:04 AEDT ]]>