Colossal Dielectric Behavior of Ga+Nb Co-Doped Rutile TiO₂

Abstract: Stimulated by the excellent colossal permittivity (CP) behavior achieved in In+Nb co-doped rutile TiO2, in this work we investigate the CP behavior of Ga and Nb co-doped rutile TiO2, i.e., (Ga(0.5)Nb(0.5))(x)Ti(1-x)O2, where Ga(3+) is from the same group as In(3+) but with a much smaller ionic radius. Colossal permittivity of up to 10(4)-10(5) with an acceptably low dielectric loss (tan δ = 0.05-0.1) over broad frequency/temperature ranges is obtained at x = 0.5% after systematic synthesis optimizations. Syste… Show more

“…Additionally, Fig. 4(b) depicts that there should be a dissipation peak shifting to higher frequency with the increasing of temperature, which is in correspondence to the Debye relaxation 1, 3, 9, 25–27 . The dielectric relaxation time (τ) could be calculated with the extreme value relationwhere circular frequency ω p equals to 2πf p and f p is the characteristic frequency at the peak of tan δ.…”

“…The dielectric relaxation time (τ) could be calculated with the extreme value relationwhere circular frequency ω p equals to 2πf p and f p is the characteristic frequency at the peak of tan δ. The fast increase of f p indicates the decrease of τ with temperature increase, which is due to the thermally excited relaxation process 1, 3, 7, 24 . The activation energies required for these relaxations can be calculated with the Arrhenius law aswhere τ 0 is the pre-exponential factor, E a is the activation energy for the relaxation, K B is the Boltzmann constant, and T is the temperature corresponding to the peak of tan δ.…”

“…The CP behavior of materials can be explained on the basis of semiconducting grains and insulating grain boundaries 15–17 . There are other mechanisms used to explain the overall dielectric response in TiO 2 -based ceramics, including electron hopping 18 and non-Ohmic sample-electrode contact 3 . In addition, following researches introduced more similar types of ceramics such as Ga+Nb and Al+Nb co-doped TiO 2 2–4, 14 .…”

“…In addition, following researches introduced more similar types of ceramics such as Ga+Nb and Al+Nb co-doped TiO 2 2–4, 14 . However, both of the Ga+Nb and Al+Nb co-doped rutile TiO 2 ceramics were also reported to show poor dielectric properties compared with the In+Nb co-doped in TiO 2 ceramics 1, 3, 4, 13, 16, 17, 19–21 . Thus, developing more acceptor/donor for the AB co-doped rutile TiO 2 ceramics is essential for pursuing high quality colossal permittivity ceramic materials.…”

Dielectric properties of Y and Nb co-doped TiO2 ceramics

“…Additionally, Fig. 4(b) depicts that there should be a dissipation peak shifting to higher frequency with the increasing of temperature, which is in correspondence to the Debye relaxation 1, 3, 9, 25–27 . The dielectric relaxation time (τ) could be calculated with the extreme value relationwhere circular frequency ω p equals to 2πf p and f p is the characteristic frequency at the peak of tan δ.…”

“…The dielectric relaxation time (τ) could be calculated with the extreme value relationwhere circular frequency ω p equals to 2πf p and f p is the characteristic frequency at the peak of tan δ. The fast increase of f p indicates the decrease of τ with temperature increase, which is due to the thermally excited relaxation process 1, 3, 7, 24 . The activation energies required for these relaxations can be calculated with the Arrhenius law aswhere τ 0 is the pre-exponential factor, E a is the activation energy for the relaxation, K B is the Boltzmann constant, and T is the temperature corresponding to the peak of tan δ.…”

“…The CP behavior of materials can be explained on the basis of semiconducting grains and insulating grain boundaries 15–17 . There are other mechanisms used to explain the overall dielectric response in TiO 2 -based ceramics, including electron hopping 18 and non-Ohmic sample-electrode contact 3 . In addition, following researches introduced more similar types of ceramics such as Ga+Nb and Al+Nb co-doped TiO 2 2–4, 14 .…”

“…In addition, following researches introduced more similar types of ceramics such as Ga+Nb and Al+Nb co-doped TiO 2 2–4, 14 . However, both of the Ga+Nb and Al+Nb co-doped rutile TiO 2 ceramics were also reported to show poor dielectric properties compared with the In+Nb co-doped in TiO 2 ceramics 1, 3, 4, 13, 16, 17, 19–21 . Thus, developing more acceptor/donor for the AB co-doped rutile TiO 2 ceramics is essential for pursuing high quality colossal permittivity ceramic materials.…”

Dielectric properties of Y and Nb co-doped TiO2 ceramics

“…Unlike ferroelectric material such as BST, it had a higher energy efficiency on energy charge-discharge [10,17]. However, due to processing conditions, a small amount of oxygen vacancies as donor impurities often existed in titanium dioxide, which could increase dielectric loss and reduce breakdown strength [18][19][20][21][22]. Therefore, in this study, we chose acceptor (manganous)-doped titanium dioxide as the dielectric ceramic, the effect of different additive amounts of alkali-free glass on the dielectric properties of Mn-doped TiO 2 was investigated for its energy storage applications.…”

Dielectric properties of manganese-doped TiO2 with different alkali-free glass contents for energy storage application

Dielectric Ceramics and Films for Electrical Energy Storage