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activated carbon being 85% microporous and the alginate materials predominantly mesoporous (66–93%), albeit with some microporosity developing at higher temperatures.

      Source: Data from Shannon et al. [39].

Bioactive Adsorption capacity (mg g−1)
AC A300 A500 A800
Gibberelic acid (A) 72 98 76 118
Indole‐acetic acid (B) 210 115 150 157
Kinetin (C) 205 120 125 121
Abietic acid (D) 314 282 239 370

      3.2.5 Conclusion

      What this chapter has attempted to show is that highly functional and functioning advanced materials can be produced relatively simply from biomass residues, utilising the inherent functionality and structural properties of the polysaccharide materials. This aids in the important aim of transforming our mindset as a society from a linear economy model (extract – make – use – discard) to a more circular structure, where the discarded elements are treated as a resource to be valorised rather than to be disposed of. Such models are crucial if we are to attain a sustainable society which can support the needs of all of us.

      Due to the conversion of the ‘waste’ polysaccharides into a range of tunable high‐surface area, highly mesoporous materials can now be carried out at scale and the understanding of the processes has developed rapidly over the last few years, such that these materials have moved from the lab to production and commercialisation. This chapter has focused on two major areas of activity: adsorption and catalysis. We describe the various adsorption/desorption processes at which the materials excel, partly due to their relatively large pore size (with respect to the more traditional activated carbons) which allows them to effectively adsorb (and desorb) relatively large molecules, which are excluded from micropores. The tunable surface functionality also plays a significant role here, with the evolution of the surface being controlled by thermal treatments. However, it is not only small molecules that are adsorbed in impressive amounts – a wide range of acidic and basic gases are also taken up by the material, including ammonia, sulphur dioxide, hydrogen sulphide, and carbon dioxide, making these materials capable of air purification as well as water treatment.

      The catalytic aspects of the materials have also been explored, and in this part of the review, a range of surface functionalisation methodologies are presented. Again, these rely on the various surface functionalities for their success (e.g. bromination of unsaturated functionality to provide anchor points for further functionalisation, attachment of activating groups via hydroxyl functionalities and sulphonation to generate strongly acidic sites) and complex structures can be built up on the surface of the materials, again aided by large enough pores to allow ingress and egress of relatively bulky substrates.

      For purposes of space, the chapter does not include the development of nanoparticulate metal – Starbon composites, readily carried out, generally without the need for an additional reductant, making the process particularly green. Such materials have proved their use as catalysts, and related metal oxide nanoparticle – Starbon systems have recently been shown to be highly performing in battery applications. Similarly, the functionalisation of the materials with elements such as nitrogen is in its very early stages, with promising initial results presented here. However, much remains to be done to develop, control, and understand these materials, and to make the most of the perturbation that the nitrogen centres provide to the material.

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