ITZO-TFTs (bottom-gate & top-contact type) were fabricated on ITO-coated EAGLE XG^® glass substrates. Firstly, amorphous AlO_x film (ε_r = 8, 106 nm^t, C_i = 67 nF cm⁻²) was deposited by the ALD technique followed by the deposition of 10-nm-thick amorphous ITZO by PLD through a stencil mask. Then, the multilayer film was annealed at 350 °C in air. Finally, 20-nm-thick Ti films were evaporated as source & drain electrodes through a stencil mask.
The resultant ITZO-TFTs showed excellent transistor characteristics as shown in Fig. a (μ_FE ~48 cm² V⁻¹ s⁻¹, μ_eff ~58 cm² V⁻¹ s⁻¹, S.S. ~100 mV decade⁻¹). We measured thermopower of ITZO channels with L = 800 μm and W = 400 μm when applying V_g. Figure b shows the change in the thermopower (S) with sheet carrier concentration (n_2D) that obtained from C_i (V_g − V_th). The absolute value of S decreases with increasing n_2D. Then, we fabricated ITZO films on EAGLE XG^® and AlO_x/ITO/EAGLE XG^®, and measured the thermopower and bulk carrier concentration n_3D (Fig. c). We extracted that the density of states effective mass of ITZO is 0.11 m₀, which is lighter than that of a-IGZO (m* ~0.3 m₀). Then, we compared the n_2D and n_3D at the same S. Interestingly, the effective thickness that is estimated as n_2D/n_3D is ~20 nm, which is thicker than the ITZO film thickness (~10 nm). We would like to discuss this difference in thickness at the conference.