Sentence examples for high density carbon from inspiring English sources

In order to overcome capacity decay caused by all the above mechanisms, we have prepared a composite cathode made of sulphur and high density carbon nanotube (HD-CNT) forest scaffold that is able to interfacially adsorb and volumetrically confine the polysulphide species and accommodate the expansion of sulphur discharge products effectively.

In order to obtain high density carbon films with keeping anisotropic deposition profile on trench substrates, we control mass density of carbon films deposited by a H-assisted plasma chemical vapor deposition (CVD) method by ion kinetic energy of ions irradiating on film surface during deposition.

We present a novel method for fabricating a high-density carbon nanotube microelectrode array (MEA) chip.

Mesocarbon microbeads have proved to be an excellent precursor for high-density carbon materials.

A multilayer (Ni/Al/Ni) catalyst design is proposed to synthesize high-density carbon nanotubes (CNTs) on a conductive titanium silicide substrate.

High-density carbon blocks are extensively applied in bearing and sealing structures of some advanced aero-engines.

Mesocarbon microbead (MCMB) based material, as a kind of high-density carbon, can potentially possess high mechanical strength at high temperature.

Mixtures formed by high-density carbon dioxide and linalool show considerably endothermic mixing (≈400 600 J mol−1) in the linalool-rich region and moderately exothermic mixing for the other compositions.

These include: multiwalled nanotubes (MWNT, MWNTT bundles, irregular high-density carbon nanofibers, long (up to 0.2 mm) uniform-diameter (∼100 nm) nanofibers, helical regularly coiled tubular nanofibers, and ribbon-like coiled nanofibers with rectangular cross section.

The technique proposed for growing these carbon octopi nanostructures is ideal to facilitate a new in situ transfer film process to place high-density carbon structures on secondary surfaces to produce high capacitance all-carbon contacts.

However, after carbon microfibers were boiled in the solution of H2SO4/HNO3 and were immersed in the solutions of Fe(NO3 3/xylene, Fe(NO3 3/acetone, ferrocene/acetone and Fe(NO3 3/ferrocene/acetone, the obtained products were a high-density carbon nanotubes, carbon nanotubes with many carbon particles, carbon submicrotubes and a mixture of carbon nanomaterial, respectively.