Atomic layer deposition

About: Atomic layer deposition is a research topic. Over the lifetime, 19821 publications have been published within this topic receiving 477332 citations. The topic is also known as: ALD.

Method of manufacturing a contact interconnection layer containing a metal and nitrogen by atomic layer deposition for deep sub-micron semiconductor technology

Abstract: An atomic layer deposition method is used to deposit a TiN or TiSiN film having a thickness of about 50 nm or less on a substrat. A titanium precursor which is tetrakis(dimethylamido)titanium (TDMAT), tetrakis(diethylamido)titanium (TDEAT), or Ti{OCH(CH 3 ) 2 } 4 avoids halide contamination from a titanium halide precursor and is safer to handle than a titanium nitrate. After a monolayer of the titanium precursor is deposited on a substrate, a nitrogen containing reactant is introduced to form a TiN monolayer which is followed by a second purge. For TiSiN, a silicon source gas is fed into the process chamber after the TiN monolayer formation. The process is repeated several times to produce a composite layer comprised of a plurality of monolayers that fills a contact hole. The ALD method is cost effective and affords an interconnect with lower impurity levels and better step coverage than conventional PECVD or CVD processes.

Method for forming a dielectric layer

Abstract: The present invention relates to a deposition of a dielectric layer. On a substrate having a structured area a crystallization seed layer for a dielectric layer is deposited via an atomic layer deposition technique employing a first and a second precursor on the structured area of the substrate. The first pre-cursor is a compound having the constitutional formula M1(R1Cp)x(R2)4-x, wherein M1 is one of hafnium and zirconium, Cp is cyclopentadienyl, R1 is independently selected of methyl, ethyl and alkyl, R2 is independently selected of hydrogen, methyl, ethyl, alkyl and alkoxyl, and x is one or two. The dielectric layer is deposited on the crystallization seed layer via an atomic layer deposition technique employing a third and a forth precursor wherein the third pre-cursor being a compound having the constitutional formula M2 R3 R4 R5 R6, wherein M2 is one of hafnium or zirconium and R3, R4, R5, and R6 are independently selected of alkyl amines.

Ferromagnetic nanotubes by atomic layer deposition in anodic alumina membranes

Abstract: In this paper, two methods for the synthesis of magnetic nanotubes inside the pores of anodic alumina membranes by atomic layer deposition (ALD) are compared. The precursors were nickelocene or cobaltocene, and H2O or O3. The first method consists of a three-step ALD cycle: First, the sample is exposed to the metal-organic precursor, subsequently to water, and finally, to hydrogen. In the second method, metal oxide is deposited by a conventional two-step ALD cycle. After the ALD process, the sample is reduced under hydrogen atmosphere. The magnetic nanotubes obtained by the second method have a smaller grain size and improved magnetic properties. The magnetic nanotubes with diameters ranging from 35to60nm exhibit a preferential magnetization direction along the nanowire axis. The Ni or Co nanotubes with larger diameters (around 160nm) show a nearly isotropic magnetic behavior, with the magnetic moments arranged in a vortex state at zero field.

Method of forming a barrier film and method of forming wiring structure and electrodes of semiconductor device having a barrier film

Abstract: There is provided a method of forming a barrier metal which is designed to be interposed between a metal layer and an insulating layer, both constituting a multi-layered structure of semiconductor device, the method comprising the steps of positioning a substrate having the insulating layer formed thereon at a predetermined position inside a processing vessel forming a processing space, and alternately introducing a gas containing a refractory metallic atom, a gas containing Si atom and a gas containing N atom into the processing vessel under a predetermined processing pressure, thereby allowing a refractory metal nitride or a refractory metal silicon nitride to be deposited on the insulating layer by way of atomic layer deposition.

Al2O3/TiO2 nanolaminate thin film encapsulation for organic thin film transistors via plasma-enhanced atomic layer deposition.

Abstract: Organic electronic devices require a passivation layer that protects the active layers from moisture and oxygen because most organic materials are very sensitive to such gases. Passivation films for the encapsulation of organic electronic devices need excellent stability and mechanical properties. Although Al2O3 films obtained with plasma enhanced atomic layer deposition (PEALD) have been tested as passivation layers because of their excellent gas barrier properties, amorphous Al2O3 films are significantly corroded by water. In this study, we examined the deformation of PEALD Al2O3 films when immersed in water and attempted to fabricate a corrosion-resistant passivation film by using a PEALD-based Al2O3/TiO2 nanolamination (NL) technique. Our Al2O3/TiO2 NL films were found to exhibit excellent water anticorrosion and low gas permeation and require only low-temperature processing (<100 °C). Organic thin film transistors with excellent air-stability (52 days under high humidity (a relative humidity of 90% a...