It is demonstrated that the sensing characteristics of a semiconductor gas sensor using SnO2 can be improved by controlling fundamental factors
which affect its receptor and transducer functions.
The transducer function is deeply related with the microstructure of the
elements, i.e., the grain size of SnO2 (D) and the depth of the surface
space-charge layer (L). The sensitivity is drastically promoted when D
is made comparable to or less than 2L, either by control of D for pure
SnO2 elements or by control of the Debye length for impurity-doped
elements.
On the other hand, the receptor function is drastically modified by the
introduction of foreign receptors on the surface of SnO2. In the
particular cases of Pd and Ag promoters, the oxides (PdO and Ag2O)
formed in air interact with the SnO2 surface to produce an
electron-deficient space-charge layer, and this contributes much to
promoting the gas sensitivity.
For a test gas having a specific reactivity, such specificity can be
utilized for exploiting gas-selective receptors, as exemplified by CuO
SnO2 and La2O3 SnO2 elements, which detect H2S and ethanol gas
respectively very sensitively.
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