Introducing lignin as a binder material for the aqueous production

By enabling water-based cathode processing, the energy-intensive N-methyl-2-pyrrolidone (NMP) recovery step can be eliminated, reducing the cost and environmental impact of LIBs. Aqueous processing of high capacity Ni-containing LiNixMn1−x−yCoyO2 (NMC) cathodes is problematic due to lithium-ion(Li+) leaching

Structure, chemistry and physicochemistry of lignin for material functionalization

a)–(f) Area specific impedance (ASI) as a function of voltage for

Introducing lignin as a binder material for the aqueous production of NMC111 cathodes for Li-ion batteries - Materials Advances (RSC Publishing) DOI:10.1039/D2MA00850E

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View of H + /Li + substituted α-LiCoO 2 structure (MOPAC calculation

FTIR data showing the normalized 870 cm −1 carbonate peak area as a

Long-term cycling performance (C/3 charge, C/3 discharge), and b) area

When the NMC material is exposed to water Li⁺ starts leaching out from

The same primary particle as in Figure 4, with the edge regions

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3D pore size visualization and evolution with cycling for the

Lignin–Inorganic Interfaces: Chemistry and Applications from Adsorbents to Catalysts and Energy Storage Materials - Budnyak - 2020 - ChemSusChem - Wiley Online Library

EBC-coated test pieces via spraying: (a) SiC/SiC mini-composite; (b)

Requirements and desired properties of binders in energy storage

Lignin for energy applications – state of the art, life cycle, technoeconomic analysis and future trends - Green Chemistry (RSC Publishing) DOI:10.1039/D2GC02724K