Ionic liquid modified PVDF/BCZT nanocomposites for space charge induced mechanical energy harvesting performance.

Mechanical energy harvesting performances of poly(vinylidene fluoride) (PVDF) based composites are most often correlated with their polar phase and the individual piezoelectricity of the used filler materials. Here we show that the significant enhancement of space charge polarization of the said composites can play the key dominant role in determining their mechanical energy harvesting performance regardless of their polar phase and individual piezoelectricity of the used fillers. For this purpose, ionic liquid has been incorporated into PVDF/0.

Shortening the biologics clinical timeline with a novel method for generating stable, high-producing cell pools and clones.

Reducing drug development timelines is an industry-wide goal to bring medicines to patients in need more quickly. This was exemplified in the coronavirus disease 2019 pandemic where reducing development timelines had a direct impact on the number of lives lost to the disease. The use of drug substances produced using cell pools, as opposed to clones, has the potential to shorten development timelines.