A mass spectrometrical surface chemistry study of aluminum nitride ALD from tris-dimethylamido aluminum and ammonia†

IF 5.2 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Materials Advances Pub Date : 2024-10-28 DOI:10.1039/D4MA00922C

Pamburayi Mpofu, Houyem Hafdi, Jonas Lauridsen, Oscar Alm, Tommy Larsson and Henrik Pedersen

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Abstract

Dialkylamido compounds, such as tris-dimethylamido aluminum (TDMAA, Al(NMe₂)₃) and tetrakis-dimethylamido titanium (TDMAT, Ti(NMe₂)₄) are interesting precursors for depositing nitrides using atomic layer deposition (ALD) due to their high volatility and reactivity at low temperatures. In this study, we explored surface chemistry using mass spectrometry and discovered that the surface mechanisms involved β-hydride elimination and ligand decomposition, as well as transamination and hydrogenation reactions which facilitate ligand exchange. This is mainly based on the –N(Me)₂ and HN(Me)₂ detected during both TDMAA and NH₃ pulses, and CH₄ signals detected during the NH₃ pulse stage. The expected reductive elimination of the two dimethylamido ligands, via a direct nitrogen–nitrogen coupling reaction was not observed, suggesting that it is less thermodynamically favorable compared to reduction by NH₃. Arrhenius analysis between 150 and 300 °C found activation energies (E_a) = 27–30 kJ mol⁻¹ and pre-exponential factors (A) = 3–5 s⁻¹ for the reaction between TDMAA and NH₃.

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从三-二甲基氨基铝和氨†对氮化铝 ALD 的质谱表面化学研究

二烷基氨基化合物，如三烷基二甲基氨基铝（TDMAA，Al(NMe2)3）和四烷基二甲基氨基钛（TDMAT，Ti(NMe2)4），因其在低温下的高挥发性和高反应性，成为利用原子层沉积（ALD）沉积氮化物的有趣前体。在这项研究中，我们利用质谱法对表面化学进行了探索，发现其表面机理涉及 β-酸酐消除和配体分解，以及促进配体交换的转氨化和氢化反应。这主要是基于在 TDMAA 和 NH3 脉冲阶段检测到的 -N(Me)2 和 HN(Me)2 以及在 NH3 脉冲阶段检测到的 CH4 信号。没有观察到两个二甲基氨基配体通过直接的氮-氮偶联反应发生预期的还原消除，这表明与 NH3 的还原反应相比，还原消除在热力学上不太有利。Arrhenius 分析发现，TDMAA 和 NH3 反应的活化能（Ea）= 27-30 kJ mol-1，预指数（A）= 3-5 s-1。

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