TY - JOUR
AU - Münir M Besli
AU - Camille Usubelli
AU - Michael Metzger
AU - Sondra Hellstrom
AU - Sami Sainio
AU - Dennis Nordlund
AU - Jake Christensen
AU - Gerhard Schneider
AU - Marca M Doeff
AU - Saravanan Kuppan
AB - <p>In this study, the long-term chemothermal stability of chemically delithiated Li<small><sub>0.3</sub></small>Ni<small><sub>0.8</sub></small>Co<small><sub>0.15</sub></small>Al<small><sub>0.05</sub></small>O<small><sub>2</sub></small> (Li<small><sub>0.3</sub></small>NCA) was systematically investigated at relevant operating temperatures of polymer solid-state batteries using <em>ex situ</em> synchrotron-based hard and soft X-ray absorption spectroscopy. The reduction of nickel on the surface, subsurface, and in the bulk of secondary NCA particles was studied and directly related to aging time, temperature, the presence of polymeric electrolyte (poly(ethylene oxide) or polycaprolactone), and lithium salt (lithium tetrafluoroborate or lithium bis(trifluoromethanesulfonyl)imide). Depending on the polymer and/or lithium salt accompanying the delithiated Li<small><sub>0.3</sub></small>NCA, reduction of nickel at the surface, subsurface, and bulk occurs to varying extents, starting at the surface and propagating into the bulk material. Our results indicate how degradation (reduction of nickel) is strongly correlated to temperature, time, and the presence of blended polymer and/or lithium salt in the cathode. The relative stability of the NCA material in cathodes having different polymer and lithium salt combinations identified in the <em>ex situ</em> spectroscopy study is directly demonstrated in solid-state polymer batteries.</p>
BT - Journal of Materials Chemistry A
DA - 03/2019
DO - 10.1039/C9TA11103D
IS - 47
LA - eng
N2 - <p>In this study, the long-term chemothermal stability of chemically delithiated Li<small><sub>0.3</sub></small>Ni<small><sub>0.8</sub></small>Co<small><sub>0.15</sub></small>Al<small><sub>0.05</sub></small>O<small><sub>2</sub></small> (Li<small><sub>0.3</sub></small>NCA) was systematically investigated at relevant operating temperatures of polymer solid-state batteries using <em>ex situ</em> synchrotron-based hard and soft X-ray absorption spectroscopy. The reduction of nickel on the surface, subsurface, and in the bulk of secondary NCA particles was studied and directly related to aging time, temperature, the presence of polymeric electrolyte (poly(ethylene oxide) or polycaprolactone), and lithium salt (lithium tetrafluoroborate or lithium bis(trifluoromethanesulfonyl)imide). Depending on the polymer and/or lithium salt accompanying the delithiated Li<small><sub>0.3</sub></small>NCA, reduction of nickel at the surface, subsurface, and bulk occurs to varying extents, starting at the surface and propagating into the bulk material. Our results indicate how degradation (reduction of nickel) is strongly correlated to temperature, time, and the presence of blended polymer and/or lithium salt in the cathode. The relative stability of the NCA material in cathodes having different polymer and lithium salt combinations identified in the <em>ex situ</em> spectroscopy study is directly demonstrated in solid-state polymer batteries.</p>
PY - 2019
SP - 27135 
EP -  27147
ST - J. Mater. Chem. A
T2 - Journal of Materials Chemistry A
TI - Long-term chemothermal stability of delithiated NCA in polymer solid-state batteries
VL - 7
SN - 2050-7488
ER -