Sentence examples for most effective surface from inspiring English sources

CD4 is one of the most effective surface markers for identifying Th cells.

During immobilization, Au NPs and Au NPs/MPA were used in biosensor fabrication in order to achieve the most effective surface design for target biosensor.

The improved method, however, cannot be applied to complicated structures, since it is difficult to determine which is the most effective surface for designing such structures.

Considering Li residual removal as well as capacity and capacity retention upon cycling, the most effective surface modification was achieved in the case of a 1 1 Co/P coating, which increased initial capacity and capacity retention by 10 mAh g−1 and 3%, respectively, as compared to the uncoated sample.

Among those radical species, H is most effective for surface reaction due to the fast diffusion near the a-IGZO surface.

It is shown that the most effective antifouling surface may be accomplished by a good balance of the polymer chain length and the grafting density.

Among those plasmon nanostructures, nanoparticles have the most effective localized surface plasmon resonance absorption enhancement at visible wavelengths, which can be utilized in energy harvesting, photocatalyst, solar cells or water splitting [8 10].

Surface coating is one of the most effective techniques of surface modification and surface engineering, which is important in biomaterials research and biomedical engineering.

The analysis results showed that material structure was the most effective factor on surface roughness and feed rate was the dominant factor affecting cutting force.

Thermal growth of silicon oxide is the most effective c-Si surface passivation technique for solar cell, but this technique is not suitable for low-cost industrial processes as it requires very high temperature (above 1,000 °C) treatment.

Among all these approaches, coating of iron oxide nanoparticles with synthetic or natural polymers is the most effective at inducing surface modification of nanomaterials so as to transform them into core shell nanostructures having metal oxide as the core and an organic polymer layer as the shell (Oh et al. 2011).