Jani Päiväsaari scite author profile

Organometallic tris(methylcyclopentadienyl)erbium and water were successfully exploited as precursors for the atomic layer deposition (ALD) of Er 2 O 3 thin films. Deposition studies were carried out in the temperature range 175±450 C, where Si(100) and soda-lime glass were used as substrates. ALD-type growth mechanism could be verified at relatively low deposition temperatures of 250 C and 300 C, where a high growth rate (1.5 per cycle) for an ALD process was obtained. The deposited Er 2 O 3 films were smooth and very uniform, and contained only low concentrations of carbon and hydrogen as impurities. The films were crystalline with the (111) orientation of the cubic phase dominating. The effective permittivity of the Er 2 O 3 /native SiO 2 insulator stack was approximately 10.

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Atomic layer deposition of rare earth oxides: erbium oxide thin films from β-diketonate and ozone precursors

Päiväsaari¹,

Putkonen²,

Sajavaara

et al. 2004

Journal of Alloys and Compounds

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Synthesis, structure and properties of volatile lanthanide complexes containing amidinate ligands: application for Er2O3 thin film growth by atomic layer deposition

Päiväsaari¹,

Dezelah²,

Back

et al. 2005

J. Mater. Chem.

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Treatment of anhydrous rare earth chlorides with three equivalents of lithium 1,3-di-tertbutylacetamidinate (prepared in situ from the di-tert-butylcarbodiimide and methyllithium) in tetrahydrofuran at ambient temperature afforded Ln( t BuNC(CH 3 )N t Bu) 3 (Ln = Y, La, Ce, Nd, Eu, Er, Lu) in 57-72% isolated yields. X-Ray crystal structures of these complexes demonstrated monomeric formulations with distorted octahedral geometry about the lanthanide(III) ions. These new complexes are thermally stable at .300 uC, and sublime without decomposition between 180-220 uC/0.05 Torr. The atomic layer deposition of Er 2 O 3 films was demonstrated using Er( t BuNC(CH 3 )N t Bu) 3 and ozone with substrate temperatures between 225-300 uC. The growth rate increased linearly with substrate temperature from 0.37 A ˚per cycle at 225 uC to 0.55 A ˚per cycle at 300 uC. Substrate temperatures of .300 uC resulted in significant thickness gradients across the substrates, suggesting thermal decomposition of the precursor. The film growth rate increased slightly with an erbium precursor pulse length between 1.0 and 3.0 s, with growth rates of 0.39 and 0.51 A ˚per cycle, respectively. In a series of films deposited at 250 uC, the growth rates varied linearly with the number of deposition cycles. Time of flight elastic recoil analyses demonstrated slightly oxygen-rich Er 2 O 3 films, with carbon, hydrogen and fluorine levels of 1.0-1.9, 1.7-1.9 and 0.3-1.3 atom%, respectively, at substrate temperatures of 250 and 300 uC. Infrared spectroscopy showed the presence of carbonate, suggesting that the carbon and slight excess of oxygen in the films are due to this species. The as-deposited films were amorphous below 300 uC, but showed reflections due to cubic Er 2 O 3 at 300 uC. Atomic force microscopy showed a root mean square surface roughness of 0.3 and 2.8 nm for films deposited at 250 and 300 uC, respectively.

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