Abstract
In this study, vanadium oxide (V
x
O
y
) semiconducting resistive thermometer thin films were developed, and their temperature-dependent resistive behavior was examined. Multilayers of 5-nm-thick vanadium pentoxide (V
2
O
5
) and 5-nm-thick vanadium (V) films were alternately sputter-deposited, at room temperature, to form 105-nm-thick V
x
O
y
films, which were post-deposition annealed at 300 °C in O
2
and N
2
atmospheres for 30 and 40 min. The synthesized V
x
O
y
thin films were then patterned into resistive thermometer structures, and their resistance versus temperature (
R
-
T
) characteristics were measured. Samples annealed in O
2
achieved temperature coefficients of resistance (TCRs) of −3.0036 and −2.4964%/K at resistivity values of 0.01477 and 0.00819 Ω·cm, respectively. Samples annealed in N
2
achieved TCRs of −3.18 and −1.1181%/K at resistivity values of 0.04718 and 0.002527 Ω·cm, respectively. The developed thermometer thin films had TCR/resistivity properties suitable for microbolometer and antenna-coupled microbolometer applications. The employed multilayer synthesis technique was shown to be effective in tuning the TCR/resistivity properties of the thin films by varying the annealing conditions.