2020
DOI: 10.1063/5.0029706
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Dielectric, energy storage, and loss study of antiferroelectric-like Al-doped HfO2 thin films

Abstract: Antiferroelectric thin films have properties ideal for energy storage due to their lower losses compared to their ferroelectric counterparts as well as their robust endurance properties. We fabricated Al-doped HfO2 antiferroelectric thin films via atomic layer deposition at variable thicknesses (20 nm or 50 nm) with varying dopant concentrations (4 at. % or 8 at. %). 50 nm thick 8 at. % Al-doped HfO2 showed a maximum energy storage density of 63 J/cm3 while maintaining an efficiency of 85%. A study comparing t… Show more

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Cited by 36 publications
(15 citation statements)
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“…Apart from these perovskite lead-free relaxor candidates, HfO 2 -based ceramic films have also been explored and demonstrate promising energy storage properties, stabilities/reliabilities, scalability, and integration. W rec ∼ 46 J cm –3 with excellent temperature stability (up to 175 °C) and cyclic fatigue resistant (up to 10 9 time) was reported by Park in a 9.2 nm thick Hf 0.3 Zr 0.7 O 2 film and W rec ∼ 63 J cm –3 with η ∼ 85% were realized in 50 nm thick Al doped HfO 2 ceramic films with excellent temperature and frequency stability …”
Section: State-of-the-art In Electroceramics For Energy Storagementioning
confidence: 59%
See 1 more Smart Citation
“…Apart from these perovskite lead-free relaxor candidates, HfO 2 -based ceramic films have also been explored and demonstrate promising energy storage properties, stabilities/reliabilities, scalability, and integration. W rec ∼ 46 J cm –3 with excellent temperature stability (up to 175 °C) and cyclic fatigue resistant (up to 10 9 time) was reported by Park in a 9.2 nm thick Hf 0.3 Zr 0.7 O 2 film and W rec ∼ 63 J cm –3 with η ∼ 85% were realized in 50 nm thick Al doped HfO 2 ceramic films with excellent temperature and frequency stability …”
Section: State-of-the-art In Electroceramics For Energy Storagementioning
confidence: 59%
“…W rec ∼ 46 J cm −3 with excellent temperature stability (up to 175 °C) and cyclic fatigue resistant (up to 10 9 time) was reported by Park in a 9.2 nm thick Hf 0.3 Zr 0.7 O 2 film 458 and W rec ∼ 63 J cm −3 with η ∼ 85% were realized in 50 nm thick Al doped HfO 2 ceramic films with excellent temperature and frequency stability. 459 3.2.3. Summary of State-of-the-Art in Ceramic MLs and Films.…”
Section: State-of-the-art In Electroceramics For Energy Storagementioning
confidence: 99%
“…APAPA has the lowest current density compared to PZO, PAP, and APA. Moreover, the higher electric field is mainly concentrated in the AO insulating layer due to lower dielectric constant, which is beneficial to increase E b of the film. …”
Section: Resultsmentioning
confidence: 99%
“…[21][22][23] HfO 2 has also been extensively studied as a representative high-k material for gate dielectric and DRAM capacitor dielectric applications. [24][25][26] Many studies have been performed to increase the k value of HfO 2 , [27][28][29][30][31][32][33][34] for example, through the use of dopants such as carbon, [27] Si, [29] and Al 2 O 3 . [30,31,35] HfO 2 can exist in various crystal structures with different values of k such as the monoclinic (k % 20), orthorhombic (k % 30), cubic, and tetragonal structures (k > 40).…”
Section: Introductionmentioning
confidence: 99%
“…[24][25][26] Many studies have been performed to increase the k value of HfO 2 , [27][28][29][30][31][32][33][34] for example, through the use of dopants such as carbon, [27] Si, [29] and Al 2 O 3 . [30,31,35] HfO 2 can exist in various crystal structures with different values of k such as the monoclinic (k % 20), orthorhombic (k % 30), cubic, and tetragonal structures (k > 40). In particular, the dielectric constant of tetragonal phase (t-phase) HfO 2 calculated by first-principles calculations in a previous work was approximately 70.…”
Section: Introductionmentioning
confidence: 99%