Thermally Stable Crystalline InGaO Channels via Optimized ALD for Advanced DRAM Applications
- Authors
- Kim, Dong-Gyu; Oh, Hye-Jin; Yang, Hae Lin; Kho, Jihyun; Kim, Yurim; Kuh, Bong Jin; Park, Jin-Seong
- Issue Date
- May-2025
- Publisher
- AMER CHEMICAL SOC
- Keywords
- atomic layer deposition(ALD); oxide semiconductors; high-temperature stability; field-effect transistors(FETs); process parameters
- Citation
- ACS Applied Electronic Materials, v.7, no.11, pp 5304 - 5315
- Pages
- 12
- Indexed
- SCIE
SCOPUS
- Journal Title
- ACS Applied Electronic Materials
- Volume
- 7
- Number
- 11
- Start Page
- 5304
- End Page
- 5315
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/207919
- DOI
- 10.1021/acsaelm.5c00721
- ISSN
- 2637-6113
2637-6113
- Abstract
- Oxide semiconductors have gained considerable interest as potential materials to address the challenges posed by the scaling down of dynamic random-access memory devices. High-temperature stability is critical for the application of oxide semiconductors in memory devices, as maintaining a consistent crystal structure across varying annealing temperatures is essential for overcoming high-temperature instability. In this study, we propose an optimized crystalline InGaO (IGO) film for enhanced high-temperature stability by engineering atomic layer deposition process parameters, ozone concentration, and deposition temperature. Our results indicate that high-temperature stability can be achieved through increased ozone concentrations and deposition temperatures during IGO deposition. IGO deposited at 300 degrees C exhibited only slight changes in the main (222) intensity when annealed at 700 degrees C compared to 400 degrees C. Furthermore, a highly c-axis aligned (222) plane was observed. The field-effect transistor with an IGO active layer deposited at 300 degrees C showed minimal changes in electrical parameters after annealing at 700 degrees C (mu FE: 58.4-68.7 cm2/(V s)) and demonstrated excellent positive bias temperature stress (PBTS) stability (Delta V TH: 0.15 V) at 3 MV/cm and 95 degrees C. These results suggest the potential of oxide semiconductors for use in memory devices with high-temperature thermal budgets.
Oxide semiconductors have gained considerable interest as potential materials to address the challenges posed by the scaling down of dynamic random-access memory devices. High-temperature stability is critical for the application of oxide semiconductors in memory devices, as maintaining a consistent crystal structure across varying annealing temperatures is essential for overcoming hightemperature instability. In this study, we propose an optimized crystalline InGaO (IGO) film for enhanced high-temperature stability by engineering atomic layer deposition process parameters, ozone concentration, and deposition temperature. Our results indicate that high-temperature stability can be achieved through increased ozone concentrations and deposition temperatures during IGO deposition. IGO deposited at 300 °C exhibited only slight changes in the main (222) intensity when annealed at 700 °C compared to 400 °C. Furthermore, a highly c-axis aligned (222) plane was observed. The field-effect transistor with an IGO active layer deposited at 300 °C showed minimal changes in electrical parameters after annealing at 700 °C (μFE: 58.4−68.7 cm2/(V s)) and demonstrated excellent positive bias temperature stress (PBTS) stability (ΔVTH: 0.15 V) at 3 MV/cm and 95 °C. These results suggest the potential of oxide semiconductors for use in memory devices with hightemperature thermal budgets.
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