材料科学
电介质
原子层沉积
覆盖层
电容器
微电子
纳米制造
凝聚态物理
光电子学
钙钛矿(结构)
热传导
薄膜
沉积(地质)
高-κ电介质
纳米技术
脉冲激光沉积
绝缘体(电)
成核
纳米
纳米尺度
图层(电子)
异质结
铁电性
亚稳态
半导体
电阻率和电导率
电容
作者
Mahesh Nepal,Tara P. Dhakal
标识
DOI:10.1021/acsami.5c18459
摘要
Nanolaminates─atomically layered stacks of dissimilar oxides─are widely used to engineer dielectric behavior at the nanometer scale. Among these, atomic layer deposition (ALD)-grown Al2O3/TiO2 stacks have been reported to exhibit "giant" dielectric constant (κ ∼ 103) at subnanometer periods. Here we show that the apparent high-κ is not an intrinsic dielectric enhancement but a measurement artifact arising from electrically percolative Al2O3/TiO2 stacks treated as ideal dielectrics. Using Al2O3/TiO2 nanolaminate metal-insulator-metal (MIM) capacitors and a combination of electrical (C-f, I-V, EIS), spectroscopic (XPS, HAXPES), and structural (TEM) measurements, we found that TMA/H2O growth yields Al-deficient Al2O3 on TiO2 that appears morphologically continuous yet lacks full atomic closure, forming electronically percolative pathways that recover insulating behavior only after a fully coalesced overlayer develops. In contrast, TMA/O3 deposition produces fully continuous Al2O3 that remains insulating even at subnanometer thickness. These results establish practical design rules, showing that oxidant chemistry and film thickness together govern film continuity and insulating behavior, thereby clarifying when ultrathin ALD Al2O3 functions as a true insulator versus a quasi-conductive layer. The insights extend directly to applications in microelectronics (gate stacks, MIM/DRAM capacitors), quantum devices (2DEGs, tunnel barriers), and electrochemical/photovoltaic systems (battery electrodes, electrocatalysts, and perovskite interface engineering), where reliable subnanometer coatings are essential.
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