Enhanced Electrochemical Capacity of Spherical Co-Free Li1.2 Mn0.6 Ni0.2 O2 Particles after a Water and Acid Treatment and its Influence on the Initial Gas Evolution Behavior.

Li-rich layered oxides (LRLO) with specific energies beyond 900 Wh kg-1 are one promising class of high-energy cathode materials. Their high Mn-content allows reducing both costs and the environmental footprint. In this work, Co-free Li1.2 Mn0.6 Ni0.2 O2 was investigated. A simple water and acid treatment step followed by a thermal treatment was applied to the LRLO to reduce surface impurities and to establish an artificial cathode electrolyte interface. Samples treated at 300 °C show an improved cycling behavior with specific first cycle capacities of up to 272 mAh g-1 , whereas powders treated at 900 °C were electrochemically deactivated due to major structural changes of the active compounds. Surface sensitive analytical methods were used to characterize the structural and chemical changes compared to the bulk material. Online DEMS measurements were conducted to get a deeper understanding of the effect of the treatment strategy on O2 and CO2 evolution during electrochemical cycling.

Control of particle uptake kinetics from particulate mesoporous silica films by cells through covalent linking of particles to the substrate - towards sequential drug delivery for tissue engineering applications.

A sequential release of biological cues is of high interest in tissue engineering applications, as both the proliferation and the differentiation of stem cells can be drugged. In previous studies we have shown that particulate films of mesoporous silica particles can be successfully applied for influencing stem cell fates through intracellular drug delivery after particle internalisation by the cells. In this study, we develop this concept towards an enhanced control of the particle uptake kinetics through either adsorption or covalent linking of the mesoporous silica particles to the substrate. Microscopy glass slides were initially functionalized by an aminosilane to which a thin layer of hyaluronic acid was covalently attached through an amide bond. A sub-monolayer of amino-functionalized mesoporous silica nanoparticles with a diameter of 400 nm were then adsorbed to the hyaluronic acid-functionalized surface by adsorption under high-shear conditions. Subsequently, the adsorbed particles were covalently linked to the hyaluronic acid through an amide bond. Corresponding films without the covalent coupling step were used as the control. Muscle stem cells attach and proliferate nicely on all films, and do internalize particles in all cases. However, the kinetics of particle internalization was clearly delayed for the covalently attached particles in comparison to physisorbed particles. Thus, the results imply that tuning of the particle-substrate interactions through linking chemistries is a promising means of achieving sequential particle-mediated drug release from films and that corresponding chemistries should also be applicable for 3D scaffold systems.