Reaction Chemistry during the Atomic Layer Deposition of Sc₂O₃ and Gd₂O₃ from Sc(MeCp)₃, Gd(ⁱPrCp)₃, and H₂O

Abstract: The reaction chemistry during the atomic layer deposition (ALD) of Sc2O3 and Gd2O3 from Sc(MeCp)3, Gd(iPrCp)3, and H2O was investigated by in situ time-resolved quadrupole mass spectrometry. Despite the similarity of the ligands of the Sc and Gd precursors, the growth characteristics and ligand dissociation patterns of the Sc2O3 and Gd2O3 ALD processes showed considerably different behavior. For both processes, the precursors reacted with the hydroxylated surface by proton transfer and release of the protonate… Show more

“…The GPC map over the full wafer indicates that the deposition occurred preferentially at the gas inlet of the cross‐flow reactor. This is reminiscent of the H 2 O‐based ALD process where the strong hygroscopicity of Gd 2 O 3 led to hydroxide formation as well as to sorbed H 2 O and, as a consequence, to parasitic CVD and rapid precursor exhaustion near the inlet . Accordingly, the GPC at points close to the gas inlet reached values of >0.4 nm, which are very large for steric hindrance limited ALD using Gd( i PrCp) 3 .…”

“…The understanding of the ALD surface chemistry and the relation with film and deposition process properties are keys to the successful integration of Gd 2 O 3 thin films in micro‐ or optoelectronic devices . Recently, we have reported on the surface chemistry of Gd 2 O 3 ALD from Gd( i PrCp) 3 and H 2 O . A major complication was the strong hygroscopicity of Gd 2 O 3 , which led to parasitic chemical vapor deposition (CVD) due to sorbed H 2 O.…”

Ozone‐Based Atomic Layer Deposition of Gd₂O₃ from Tris(isopropyl‐cyclopentadienyl)gadolinium: Growth Characteristics and Surface Chemistry

“…The GPC map over the full wafer indicates that the deposition occurred preferentially at the gas inlet of the cross‐flow reactor. This is reminiscent of the H 2 O‐based ALD process where the strong hygroscopicity of Gd 2 O 3 led to hydroxide formation as well as to sorbed H 2 O and, as a consequence, to parasitic CVD and rapid precursor exhaustion near the inlet . Accordingly, the GPC at points close to the gas inlet reached values of >0.4 nm, which are very large for steric hindrance limited ALD using Gd( i PrCp) 3 .…”

“…The understanding of the ALD surface chemistry and the relation with film and deposition process properties are keys to the successful integration of Gd 2 O 3 thin films in micro‐ or optoelectronic devices . Recently, we have reported on the surface chemistry of Gd 2 O 3 ALD from Gd( i PrCp) 3 and H 2 O . A major complication was the strong hygroscopicity of Gd 2 O 3 , which led to parasitic chemical vapor deposition (CVD) due to sorbed H 2 O.…”

Ozone‐Based Atomic Layer Deposition of Gd₂O₃ from Tris(isopropyl‐cyclopentadienyl)gadolinium: Growth Characteristics and Surface Chemistry

“…We have confirmed these saturation characteristics in Gd x Sc 2− x O 3 layers, of which the supercycle consisted of two Gd( i PrCp) 3 /H 2 O and one Sc(MeCp) 3 /H 2 O subcycles. The surface chemistry of these subcycles has also been examined by in situ time‐resolved quadrupole mass spectrometry (QMS) .…”

Atomic layer deposition of scandium‐based oxides

“…However, the composition and combined growth rate during multi-element ALD typically deviate from what is expected from the growth rates of the binary processes, an observation that has been explained in many cases by nucleation effects when switching from one binary process to the other. [6][7][8][9][10][11] Various theories for these deviating trends have been proposed, such as the a) E-mail: sbent@stanford.edu contribution of etching reactions, 9 differences in reactive site densities between the two binary metal-oxide surfaces, 12 or the occurrence of ligand exchange from an adsorbed precursor molecule to a metal surface atom. 13 The deposition of zinc-tin-oxide (ZTO) by ALD has been investigated more extensively than most ternary ALD processes because of its potential applications.…”

Incomplete elimination of precursor ligands during atomic layer deposition of zinc-oxide, tin-oxide, and zinc-tin-oxide