Aluminum Nitride Nanofilms by Atomic Layer Deposition Using Alternative Precursors Hydrazinium Chloride and Triisobutylaluminum

Abstract: The aim of this study is motivated by the pursuit to investigate the performance of new and as yet untested precursors such as hydrazinium chloride (N2H5Cl) and triisobutylaluminum Al(C4H9)3 in the AlN atomic layer deposition (ALD) process as well as to study effects of successive annealing on the quality of the resulting layer. Both precursors are significantly cheaper than their conventional counterparts while also being widely available and can boast easy handling. Furthermore, Al(C4H9)3 being a rather larg… Show more

“…Crystallinity generally increases with the deposition temperature, however according to the literature most of the AlN films grown both at relatively low and high temperatures are crystalline. [18][19][20][21][22][23][24][25] This fact indicates that the major contributing factor leading to a decrease in the crystallinity is apparently not the deposition temperature but the chemical structure of MMH. Namely, the suppression in crystallinity is likely resulting from the presence of methyl groups in the MMH molecules, which upon reaction at the surface occupy more space than NH 3 or N 2 H 4 , thereby disturbing the order and suppressing the crystallite growth.…”

“…Amorphous AlN films are of particular interest due to their improved mechanical, electrical and optical properties compared to those of the crystalline phase of AlN. [14][15][16][17] However, most AlN films grown by ALD are of crystalline nature [18][19][20][21][22][23][24][25] hence obtaining amorphous AlN films by ALD is an actual problem. AlCl 3 with NH 3 is a common precursor combination that has often been used for depositing AlN.…”

Amorphous AlN films grown by ALD from trimethylaluminum and monomethylhydrazine

“…Crystallinity generally increases with the deposition temperature, however according to the literature most of the AlN films grown both at relatively low and high temperatures are crystalline. [18][19][20][21][22][23][24][25] This fact indicates that the major contributing factor leading to a decrease in the crystallinity is apparently not the deposition temperature but the chemical structure of MMH. Namely, the suppression in crystallinity is likely resulting from the presence of methyl groups in the MMH molecules, which upon reaction at the surface occupy more space than NH 3 or N 2 H 4 , thereby disturbing the order and suppressing the crystallite growth.…”

“…Amorphous AlN films are of particular interest due to their improved mechanical, electrical and optical properties compared to those of the crystalline phase of AlN. [14][15][16][17] However, most AlN films grown by ALD are of crystalline nature [18][19][20][21][22][23][24][25] hence obtaining amorphous AlN films by ALD is an actual problem. AlCl 3 with NH 3 is a common precursor combination that has often been used for depositing AlN.…”

Amorphous AlN films grown by ALD from trimethylaluminum and monomethylhydrazine

“…Besides this classic set of precursors, other precursors and combinations have been introduced. Alternative nitrogen precursors are forming gas (N 2 + H 2 ), ,− hydrazine (N 2 H 4 ), − hydrazinium chloride (N 2 H 5 Cl), and monomethyl hydrazine (N 2 CH 6 ) . Alternative metal precursors are AlCl 3 , ,− TEA, , TMAA, , TDMAA, ,− DMEAA, − TDEAA, TiBA, and DMAA .…”

Area-Selective Low-Pressure Thermal Atomic Layer Deposition of Aluminum Nitride

“…There are several working deposition methods, all with their own capabilities and limitations, like molecular beam epitaxy (MBE) (Ueno, Okaura, Funakubo, & Saito, 2005), metal–organic vapor deposition (MOCVD) (Kabelac, Ghosh, Dobal, & Katiyar, 2007; Ueno et al, 2005) and pulsed layer deposition (PLD) (Yang et al, 2005), but these all struggle when trying to deposit a uniform and precisely detailed thin layer of BFO at low temperatures. The only method that is able to clear all these requirements is atomic layer deposition (ALD) (Abdulagatov et al, 2018; Dallaev, Sobola, Tofel, Škvarenina, & Sedlák, 2020; George, 2010; Puurunen, 2005), which is the reason why it is used to prepare BFO layers in this paper.…”

Multiferroic behavior of the functionalized surface of a flexible substrate by deposition of Bi₂O₃ and Fe₂O₃