The role of Ru passivation and doping on the barrier and seed layer properties of Ru-modified TaN for copper interconnects

Beilstein J. Nanotechnol.

2021

Self Cite

Layered materials, such as MoS2, have a wide range of potential applications due to the properties of a single layer, which often differ from the bulk material. They are of particular interest as ultrathin diffusion barriers in semiconductor device interconnects and as supports for low-dimensional metal catalysts. Understanding the interaction between metals and the MoS2 monolayer is of great importance when selecting systems for specific applications. In previous studies the focus has been largely on the strength of the interaction between a single atom or a nanoparticle of a range of metals, which has created a significant knowledge gap in understanding thin film nucleation on 2D materials. In this paper, we present a density functional theory (DFT) study of the adsorption of small Co and Ru structures, with up to four atoms, on a monolayer of MoS2. We explore how the metal–substrate and metal–metal interactions contribute to the stability of metal clusters on MoS2, and how these interactions change in the presence of a sulfur vacancy, to develop insight to allow for a prediction of thin film morphology. The strength of interaction between the metals and MoS2 is in the order Co > Ru. The competition between metal–substrate and metal–metal interaction allows us to conclude that 2D structures should be preferred for Co on MoS2, while Ru prefers 3D structures on MoS2. However, the presence of a sulfur vacancy decreases the metal–metal interaction, indicating that with controlled surface modification 2D Ru structures could be achieved. Based on this understanding, we propose Co on MoS2 as a suitable candidate for advanced interconnects, while Ru on MoS2 is more suited to catalysis applications.

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Prediction of Co and Ru nanocluster morphology on 2D MoS₂ from interaction energies

Nies

Beilstein J. Nanotechnol.

2021

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“…These are (a) a lack of metal-metal bonds, (b) ML rearrangements including incorporation of metal atoms into the S layer and (c) formation of metal-S clusters. Incorporation of adatoms into the surface layer is known to increase the metal-substrate interaction, as is the lack of metal-metal bonds [47] A gain in the metal-substrate interaction energy from formation of a metal-S cluster is due to Eq. 2 not accounting for this, meaning that energy contributions from the formation of metal-S clusters are included in the metal-substrate interaction energy and thus it cannot be used in a straightforward manner as an indicator of 2D vs 3D growth for these geometries.…”

Section: Discussionmentioning

confidence: 99%

“…Based on this understanding, alongside the magnitude of metal-substrate and metal-metal interactions we will be able to predict the morphology of Co and Ru thin films on 2D MoS 2 . We have previously studied 2D vs 3D Cu clusters on TaN, where we determined that there are two useful descriptors for 2D vs 3D growth: [47] 1. If the metal-substrate interaction is more favourable than the metal-metal interaction, 2D growth is preferred.…”

Section: Introductionmentioning

confidence: 99%

Prediction of Co and Ru Nanocluster Morphology on 2D MoS2 from Interaction Energies

Nies¹,

2021

Preprint

Self Cite

Layered materials, such as \ce{MoS2}, have a wide range of potential applications due to the properties of a single layer which often differ from the bulk material. They are of particular interest as ultra-thin diffusion barriers in semi-conductor device interconnects and as supports for low dimensional metal catalysts. Understanding the interaction between metals and the \ce{MoS2} monolayer is of great importance when selecting systems for specific applications. In previous studies the focus has been largely on the strength of the interaction between a single atom or a nanoparticle of a range of metals, which has created a significant knowledge gap in understanding thin film nucleation on 2D materials. In this paper, we present a density functional theory (DFT) study of the adsorption of small Co and Ru structures, with up to four atoms, on a monolayer of \ce{MoS2}. We explore how the metal-substrate and metal-metal interactions contribute to the stability of metal clusters on \ce{MoS2}, and how these interactions change in the presence of a sulphur vacancy, to develop insight to allow prediction of thin film morphology. The strength of interaction between the metals and \ce{MoS2} is in the order Co > Ru. The competition between metal-substrate and metal-metal interaction allows us to conclude that 2D structures should be preferred for Co on \ce{MoS2}, while Ru prefers 3D structures on \ce{MoS2}. However, the presence of a sulphur vacancy decreases the metal-metal interaction, indicating that with controlled surface modification 2D Ru structures could be achieved. Based on this understanding, we propose Co on \ce{MoS2} as a suitable candidate for advanced interconnects, while Ru on \ce{MoS2} is more suited to catalysis applications.

“…[3][4][5][6] Otherwise copper tends to form non-conducting islands. [3,7,8] Figure 1: Overview of issues related to downscaling of Cu interconnects and a proposed solution, adapted from Natarajan et al [9] However, as the dimensions of transistor devices decrease, this setup becomes problematic. For example, difficulties arise in depositing two additional layers of material and the Cu interconnect in the high aspect ratio interconnect via.…”

Section: Introductionmentioning

confidence: 99%

Control of Cu morphology on Ru-passivated and Ru-doped TaN Surfaces – promoting growth of 2D conducting copper for CMOS interconnects

Nies

Natarajan²,

2021

Preprint

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Prolonging the lifetime of Cu as level 1 and level 2 interconnect metal in future nanoelectronic devices is a significant challenge as device dimensions continue to shrink and device structures become more complex. At nanoscale dimensions Cu has high resistivity which prevents it functioning as a conducting wire and prefers to form non-conducting 3D islands. Given that changing from Cu to an alternative metal is challenging, we are investigating new materials that combine properties of diffusion barriers and seed liners to reduce the thickness of this layer and to promote successful electroplating of Cu to facilitate the coating of high-aspect ratio interconnect vias and to allow for optimal electrical conductance.In this study we propose a new combined barrier/liner materials based on modifying the surface layer of TaN barrier through Ru incorporation. Simulating a model Cu29 structure at 0 K and through finite temperature ab initio molecular dynamics on these surfaces allows us to demonstrate how the Ru content can control copper wetting, adhesion and thermal stability properties. Activation energies for single atom migrations onto a nucleating island of Cu allow insight into the growth mechanism of a Cu thin-film. Using this understanding allows us to tailor the Ru content on TaN to control the final morphology of the Cu film.