TY - JOUR
T1 - Mechanism of Thermal Atomic Layer Etch of W Metal Using Sequential Oxidation and Chlorination
T2 - A First-Principles Study
AU - Kondati Natarajan, Suresh
AU - Nolan, Michael
AU - Theofanis, Patrick
AU - Mokhtarzadeh, Charles
AU - Clendenning, Scott B.
PY - 2020/8/12
Y1 - 2020/8/12
N2 - Thermal atomic layer etch (ALE) of W metal can be achieved by sequential self-limiting oxidation and chlorination reactions at elevated temperatures. In this paper, we analyze the reaction mechanisms of W ALE using the first-principles simulation. We show that oxidizing agents such as O2, O3, and N2O can be used to produce a WOx surface layer in the first step of an ALE process with ozone being the most reactive. While the oxidation pulse on clean W is very exergonic, our study suggests that runaway oxidation of W is not thermodynamically favorable. In the second ALE pulse, WCl6 and Cl2 remove the oxidized surface W atoms by the formation of volatile tungsten oxychloride (WxOyClz) species. In this pulse, each adsorbed WCl6 molecule was found to remove one surface W atom with a moderate energy cost. Our calculations further show that the desorption of the additional etch products is endothermic by up to 4.7 eV. Our findings are consistent with the high temperatures needed to produce ALE in experiments. In total, our quantum chemical calculations have identified the lowest energy pathways for ALE of tungsten metal along with the most likely etch products, and these findings may help guide the development of improved etch reagents.
AB - Thermal atomic layer etch (ALE) of W metal can be achieved by sequential self-limiting oxidation and chlorination reactions at elevated temperatures. In this paper, we analyze the reaction mechanisms of W ALE using the first-principles simulation. We show that oxidizing agents such as O2, O3, and N2O can be used to produce a WOx surface layer in the first step of an ALE process with ozone being the most reactive. While the oxidation pulse on clean W is very exergonic, our study suggests that runaway oxidation of W is not thermodynamically favorable. In the second ALE pulse, WCl6 and Cl2 remove the oxidized surface W atoms by the formation of volatile tungsten oxychloride (WxOyClz) species. In this pulse, each adsorbed WCl6 molecule was found to remove one surface W atom with a moderate energy cost. Our calculations further show that the desorption of the additional etch products is endothermic by up to 4.7 eV. Our findings are consistent with the high temperatures needed to produce ALE in experiments. In total, our quantum chemical calculations have identified the lowest energy pathways for ALE of tungsten metal along with the most likely etch products, and these findings may help guide the development of improved etch reagents.
KW - Atomic layer etching
KW - Atomistic simulations
KW - Density functional theory
KW - First principles
KW - Self-limiting reaction
KW - Transistor contacts
UR - http://www.scopus.com/inward/record.url?scp=85089710402&partnerID=8YFLogxK
U2 - 10.1021/acsami.0c06628
DO - 10.1021/acsami.0c06628
M3 - Article
C2 - 32666796
AN - SCOPUS:85089710402
SN - 1944-8244
VL - 12
SP - 36670
EP - 36680
JO - ACS applied materials & interfaces
JF - ACS applied materials & interfaces
IS - 32
ER -