In the ongoing quest for energy production by nonconventional methods, energy conversion by vacuum and solid-state thermionic emission devices is one of the potentially efficient pathways for converting thermal energy directly into electrical power. The realization of practical of thermionic energy conversion devices strongly depends on achieving low work function materials, which is thus far a limiting factor. In an attempt to develop a new low work function thermionic material, this work reports thermionic emission energy distributions (TEEDs) from nanocrystalline diamond (NCD) films in the temperature range from 700 to 900 degrees C that reveal a consistent effective work function of 3.3 eV. The NCD films also exhibit emission peaks corr...
Solid state thermal energy conversion techniques are becoming increasingly important for both terres...
Thermionic energy conversion is one of the promising technologies for transforming thermal energy in...
Thermionic emission relies on the low work function and negative electron affinity of the, often fun...
In the ongoing quest for energy production by nonconventional methods, energy conversion by vacuum a...
In the ongoing quest for energy production by nonconventional methods, energy conversion by vacuum a...
In the ongoing quest for energy production by nonconventional methods, energy conversion by vacuum a...
ABSTRACT Thermionic electron emission provides a means of direct energy conversion. Some of the bene...
Thermionic electron emission forms the basis of both electron sources for a variety ...
Thermionic electron emission forms the basis of both electron sources for a variety of applications ...
abstract: Thermionic energy conversion, a process that allows direct transformation of thermal to el...
abstract: In this dissertation, combined photo-induced and thermionic electron emission from low wor...
This work examines electron field-emission characteristics of polycrystalline diamond films at eleva...
Thin films of nanocrystalline diamond with thickness around 100 nm were deposited on highly doped p-...
Thin films of nanocrystalline diamond with thickness around 100 nm were deposited on highly doped p-...
Thin films of nanocrystalline diamond with thickness around 100 nm were deposited on highly doped p-...
Solid state thermal energy conversion techniques are becoming increasingly important for both terres...
Thermionic energy conversion is one of the promising technologies for transforming thermal energy in...
Thermionic emission relies on the low work function and negative electron affinity of the, often fun...
In the ongoing quest for energy production by nonconventional methods, energy conversion by vacuum a...
In the ongoing quest for energy production by nonconventional methods, energy conversion by vacuum a...
In the ongoing quest for energy production by nonconventional methods, energy conversion by vacuum a...
ABSTRACT Thermionic electron emission provides a means of direct energy conversion. Some of the bene...
Thermionic electron emission forms the basis of both electron sources for a variety ...
Thermionic electron emission forms the basis of both electron sources for a variety of applications ...
abstract: Thermionic energy conversion, a process that allows direct transformation of thermal to el...
abstract: In this dissertation, combined photo-induced and thermionic electron emission from low wor...
This work examines electron field-emission characteristics of polycrystalline diamond films at eleva...
Thin films of nanocrystalline diamond with thickness around 100 nm were deposited on highly doped p-...
Thin films of nanocrystalline diamond with thickness around 100 nm were deposited on highly doped p-...
Thin films of nanocrystalline diamond with thickness around 100 nm were deposited on highly doped p-...
Solid state thermal energy conversion techniques are becoming increasingly important for both terres...
Thermionic energy conversion is one of the promising technologies for transforming thermal energy in...
Thermionic emission relies on the low work function and negative electron affinity of the, often fun...
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