A number of nanoscale materials have been explored as
potential electrode materials that could promise far higher performance than today's batteries.
Not exact matches
This structure is key to their
potential for being used as
electrode materials for lithium - sulfur batteries.
The new study is the first to demonstrate the synthesis of active
electrode materials using a fungal biomineralization process, illustrating the great
potential of these fungal processes as a source of useful biomaterials.
As a
potential contact
electrode and interconnection
material, wafer - scale graphene could be an essential component in microelectronic circuits, but most graphene fabrication methods are not compatible with silicon microelectronics, thus blocking graphene's leap from
potential wonder
material to actual profit - maker.
Once we fabricate
electrodes and measure their surface areas, we use a suite of characterization methods to determine unknown semiconductor properties by the following procedure: We determine the conductivity type of an unknown
material by monitoring the open - circuit
potential response upon illumination, which is important to establish the reverse - bias conditions used for all subsequent testing.
Though the value of m / e came out the same whatever the
material of the
electrode, the appearance of the discharge varied greatly; and as the measurements showed, the
potential - difference between the cathode and anode depended greatly upon the metal used for the
electrode; the pressure being the same in all cases.