Hyunjin Joh scite author profile

Ferroelectricity in HfO2 thin films can be utilized for fast, power‐efficient, and highly scalable non‐volatile memories. However, the required wake‐up process for inducing ferroelectricity/ achieving higher polarization is one of the major hurdles that hinder HfO2‐based thin films from developing reliable electronic devices. The wake‐up effect is believed to originate from i) phase transformation from non‐ferroelectric to ferroelectric, ii) movement of defect entities (mainly oxygen vacancy defects) near the film‐electrode interface, and iii) heterogeneity of the electrode interfaces. In the present study, an experimental strategy is designed to overcome these sources of the wake‐up process. A multi‐step deposition and annealing process is carried out to induce wake‐up‐free ferroelectricity in Yttrium doped HfO2 (Y:HfO2) thin film directly grown on Si‐substrate. Furnace annealing is utilized instead of the standard rapid thermal annealing process to reduce the oxygen deficiencies and stimulate the direct growth of the polar Y:HfO2. The oxygen‐vacancy‐related defects are found to be the dominating source of wake‐up effect in Y‐doped HfO2 films. The step‐wise deposition and annealing in the oxygen atmosphere facilitate direct growth of the polar phase, reduce the oxygen vacancies, and induce wake‐up‐free ferroelectricity in Y:HfO2.

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Low-Temperature Growth of Ferroelectric Hf_0.5Zr_0.5O₂ Thin Films Assisted by Deep Ultraviolet Light Irradiation

Joh

Anoop

Lee

et al. 2021

ACS Appl. Electron. Mater.

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Low-temperature deposition of inorganic ferroelectric (FE) thin films is highly demanded for lowering the environmental impact through lesser energy consumption. Doped HfO2-based FE thin films commonly require high crystalline temperature (>450 °C) to exhibit ferroelectricity. Here, we report that the crystallization temperature of the metastable orthorhombic (O) phase in Hf0.5Zr0.5O2 thin films can be lowered to 350 °C via a deep ultraviolet (DUV) irradiation process carried out before rapid thermal annealing (RTA). The DUV irradiation initializes a nucleation process of the crystal growth through photochemical cleavage of organic residues, followed by the densification of metal oxide films, and the subsequent RTA at 350 °C crystallizes the Hf0.5Zr0.5O2 thin film with a higher O-phase fraction. The DUV-irradiated films annealed at 350 °C exhibited FE characteristics, whereas the non-irradiated films annealed above 450 °C become FE. Our study suggests that DUV irradiation can be successfully utilized to lower the crystallization temperature of HZO thin films and can lead to the realization of flexible FE random access memories.

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Large electrocaloric effect with high thermal and electric field cycling stability in solution-processed Y:HfO₂ thin films

et al. 2022

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Co:BaTiO₃/Sn:BaTiO₃ Heterostructure Thin‐Film Capacitors with Ultrahigh Energy Density and Breakdown Strength

Choi

Kim

Park

et al. 2023

Adv Elect Materials

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Ferroelectric (FE) capacitors exhibiting ultrahigh power densities are widely utilized as electrostatic energy storage devices in pulsed electronic devices. One approach to maximize the discharge energy density (Ud) of capacitors is to increase the breakdown strength (Eb) accompanied with high maximum polarization (Pm) while suppressing the energy loss. However, the inverse relationship between Eb and Pm challenges the simultaneous enhancement of Eb and Ud. To overcome this limitation, FE/relaxor FE (RFE) heterostructure capacitors composed of Co‐doped BaTiO3 (BTCO) and Sn‐doped BaTiO3 (BTS) epitaxial thin film layers to decouple the Eb and Pm values are fabricated and the simultaneous enhancement of the Eb and Ud up to 7.9 MV cm−1 and 117 J cm−3, respectively is achieved. The high Eb and Ud values can be attributed to the suppression of the leakage current at the BTCO/BTS interface, a narrower hysteresis loop contributed by the BTS, and high Pm and Eb from the BTCO layer. Additionally, the BTCO/BTS heterostructure capacitors exhibit excellent fatigue endurance of up to 108 cycles and are thermal stable even at 160 °C. Through properly designing the FE and RFE layers, thermally stable and reliable FE/RFE heterostructure capacitors exhibiting high Ud and Eb can be realized.

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Hyunjin Joh

Ferroelectricity in solution-processed V-doped ZnO thin films

Multi‐Step Chemical Solution Deposition‐Annealing Process Toward Wake‐Up Free Ferroelectricity in Y:HfO₂ Films

Low-Temperature Growth of Ferroelectric Hf_0.5Zr_0.5O₂ Thin Films Assisted by Deep Ultraviolet Light Irradiation

Large electrocaloric effect with high thermal and electric field cycling stability in solution-processed Y:HfO₂ thin films

Co:BaTiO₃/Sn:BaTiO₃ Heterostructure Thin‐Film Capacitors with Ultrahigh Energy Density and Breakdown Strength

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Hyunjin Joh

Ferroelectricity in solution-processed V-doped ZnO thin films

Multi‐Step Chemical Solution Deposition‐Annealing Process Toward Wake‐Up Free Ferroelectricity in Y:HfO2 Films

Low-Temperature Growth of Ferroelectric Hf0.5Zr0.5O2 Thin Films Assisted by Deep Ultraviolet Light Irradiation

Large electrocaloric effect with high thermal and electric field cycling stability in solution-processed Y:HfO2 thin films

Co:BaTiO3/Sn:BaTiO3 Heterostructure Thin‐Film Capacitors with Ultrahigh Energy Density and Breakdown Strength

Contact Info

Product

Resources

About

Multi‐Step Chemical Solution Deposition‐Annealing Process Toward Wake‐Up Free Ferroelectricity in Y:HfO₂ Films

Low-Temperature Growth of Ferroelectric Hf_0.5Zr_0.5O₂ Thin Films Assisted by Deep Ultraviolet Light Irradiation

Large electrocaloric effect with high thermal and electric field cycling stability in solution-processed Y:HfO₂ thin films

Co:BaTiO₃/Sn:BaTiO₃ Heterostructure Thin‐Film Capacitors with Ultrahigh Energy Density and Breakdown Strength