Influence of O₂Gas on Etch Profile of Magnetic Tunnel Junction Stacks Etched in a CH₄/O₂/Ar Plasma

Abstract: The etch characteristics of magnetic tunnel junction (MTJ) stacks patterned with W/TiN films were examined using an inductively coupled plasma of a CH 4 /O 2 /Ar gas mix. The effect of the O 2 concentration on the etch rate, etch selectivity and etch profile of the MTJ stacks was examined. The etch profile of the MTJ stacks in 60% CH 4 /Ar gas appeared to be the best. The addition of 10% O 2 gas in CH 4 /Ar gas led to an improved etch profile with less redeposition on the sidewall of the MTJ stacks. This was a… Show more

“…4,13 Recent studies have focused on developing etching processes that employ non corrosive gas mixtures containing C, H, O and N, such as CO/NH 3 , CH 3 OH/Ar, CH 3 OH/H 2 O, CH 4 /Ar and CH 4 /O 2 /Ar. [5][6][7][8][9][10][11][12] MTJ stacks etching in such non corrosive gas mixtures mainly proceeds via oxidation of metals in the MTJ stack that compose each layer, formation of a protective layer and ion bombardment, which enables moderate etch rates and good etch profiles without any post etch degradation of the MTJ stacks. However, the lack of chemically reactive species in the plasma chemistry that can produce volatile etch byproducts results in heavy sidewall redeposition under certain conditions.…”

“…However, previous studies reported the formation of a protective layer and oxidation of the etched material. [9][10][11] The improved etch profile is attributed to partial oxidation of the film, which allows easy sputtering of the oxide layer and formation of a protective layer on the sidewall. Owing to fast etch rates and good etch profiles, 25% CH 3 COOH was selected as the standard concentration for the investigation of the etch profile evolution as a function of time.…”

Inductively Coupled Plasma Reactive Ion Etching of Magnetic Tunnel Junction Stacks in a CH3COOH/Ar Gas

“…4,13 Recent studies have focused on developing etching processes that employ non corrosive gas mixtures containing C, H, O and N, such as CO/NH 3 , CH 3 OH/Ar, CH 3 OH/H 2 O, CH 4 /Ar and CH 4 /O 2 /Ar. [5][6][7][8][9][10][11][12] MTJ stacks etching in such non corrosive gas mixtures mainly proceeds via oxidation of metals in the MTJ stack that compose each layer, formation of a protective layer and ion bombardment, which enables moderate etch rates and good etch profiles without any post etch degradation of the MTJ stacks. However, the lack of chemically reactive species in the plasma chemistry that can produce volatile etch byproducts results in heavy sidewall redeposition under certain conditions.…”

“…However, previous studies reported the formation of a protective layer and oxidation of the etched material. [9][10][11] The improved etch profile is attributed to partial oxidation of the film, which allows easy sputtering of the oxide layer and formation of a protective layer on the sidewall. Owing to fast etch rates and good etch profiles, 25% CH 3 COOH was selected as the standard concentration for the investigation of the etch profile evolution as a function of time.…”

Inductively Coupled Plasma Reactive Ion Etching of Magnetic Tunnel Junction Stacks in a CH3COOH/Ar Gas

Etch characteristics of CoFeB thin films and magnetic tunnel junction stacks in a H2O/CH3OH plasma

Etch characteristics of Ru thin films using O2/Ar, CH4/Ar, and O2/CH4/Ar plasmas