Surface and grain-boundary scattering in nanometric Cu films

Sun, Tik; Yao, Bo; Warren, Andrew P.; Barmak, K.; Toney, Michael F.; Peale, Robert E.; Coffey, Kevin R.

doi:10.1103/physrevb.81.155454

Cited by 182 publications

(190 citation statements)

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“…We also examined our own new experimental data on NbN thin films. In these data, relating dT c to R s provided fits with reduced scatter relative to fits suggested by previous models [7][8][9][10][30][31][32]. Finally, we supply two possible explanations of the observed universal behavior.…”

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confidence: 61%

“…Figures 1(a) and 1(b) show the dependence of T c on thickness and on sheet resistance for our NbN films, allowing a comparison of the data with the existing models [7][8][9][10][30][31][32]. Although a general trend can be seen in both T c (d) and T c (R s ), Chemical treatment of the substrate prior to deposition is suspected of influencing the properties of the red solid points here and in Fig.…”

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confidence: 84%

“…Theoretically, the relationship ρ(d) is usually discussed in terms of derivatives of Fuchs's theory [30], sometimes combined with Matthiessen's rule [31]. However, surprisingly, to date, the existing theories encounter difficulties in fitting the experimental data, which are often scattered when plotted on a ρ(d) graph [32]. In addition to challenging our understanding of metallic thin films, such scatter prevents a smooth quantitatively valuable transition between descriptions of T c (R s ) and T c (d) in the case of superconductors.…”

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confidence: 99%

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Universal scaling of the critical temperature for thin films near the superconducting-to-insulating transition

et al. 2014

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Thin superconducting films form a unique platform for geometrically confined, strongly interacting electrons. They allow an inherent competition between disorder and superconductivity, which in turn enables the intriguing superconducting-to-insulating transition and is believed to facilitate the comprehension of high-T c superconductivity. Furthermore, understanding thin film superconductivity is technologically essential, e.g., for photodetectors and quantum computers. Consequently, the absence of established universal relationships between critical temperature (T c ), film thickness (d), and sheet resistance (R s ) hinders both our understanding of the onset of the superconductivity and the development of miniaturized superconducting devices. We report that in thin films, superconductivity scales as dT c (R s ). We demonstrated this scaling by analyzing the data published over the past 46 years for different materials (and facilitated this database for further analysis). Moreover, we experimentally confirmed the discovered scaling for NbN films, quantified it with a power law, explored its possible origin, and demonstrated its usefulness for nanometer-length-scale superconducting film-based devices. Relationships between low-temperature and normal-state properties are crucial for understanding superconductivity. For instance, the Bardeen-Cooper-Schrieffer theory (BCS) successfully associates the normal-to-superconducting transition temperature, T c , with material parameters, such as the Debye temperature ( D ) and the density of states at the Fermi level [N (0)]. Hence, the BCS model allows us to infer superconducting characteristics (i.e., T c ) from properties measured at higher temperatures [1]. In the BCS framework, superconductivity occurs when attractive phonon-mediated electron-electron interactions overcome the Coulomb repulsion, giving rise to paired electrons (Cooper pairs) with a binding energy gap:. Moreover, within a superconductor, all Cooper pairs are coupled, giving rise to a collective electron interaction. Such a collective state is described by a complex global order parameter with real amplitude ( ) and phase (ϕ): = e iϕ .Because superconductivity relies on a collective electron behavior, the onset of superconductivity occurs when the number of participating electrons is just enough to be considered collective, i.e., at the nanoscale [2-5]. Thus, it is known that the superconductivity-disorder interplay varies in thin films and is effectively tuned with the film thickness (d) or with the disorder in the system, which is represented by sheet resistance of the film at the normal state (R s ) [6][7][8][9][10]. The mechanism of superconductivity in thin films has been investigated since the 1930s [6] increase in T c with decreasing thickness in aluminum films in a study that pioneered the currently ongoing research of thin superconducting films. This enhancement of T c , which is still not completely understood, was later confirmed by Strongin et al. [12], who also reported the more common be...

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confidence: 84%

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Universal scaling of the critical temperature for thin films near the superconducting-to-insulating transition

et al. 2014

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“…Prior work by Sun et al [2][3][4] on SiO 2 and Ta/SiO 2 -encapsulated nanometric Cu films showed grain-boundary scattering to be the dominant mechanism contributing to the resistivity increase related to the classical size effect. These studies also showed a weaker, but still significant, contribution from surface scattering.…”

Section: Introductionmentioning

confidence: 96%

On twin density and resistivity of nanometric Cu thin films

Barmak

Darbal

et al. 2016

Journal of Applied Physics

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Crystal orientation mapping in the transmission electron microscope was used to quantify the twin boundary length fraction per unit area for five Ta38Si14N48/SiO2 encapsulated Cu films with thicknesses in the range of 26–111 nm. The length fraction was found to be higher for a given twin-excluded grain size for these films compared with previously investigated SiO2 and Ta/SiO2 encapsulated films. The quantification of the twin length fraction per unit area allowed the contribution of the twin boundaries to the size effect resistivity to be assessed. It is shown that the increased resistivity of the Ta38Si14N48 encapsulated Cu films compared with the SiO2 and Ta/SiO2 encapsulated films is not a result of increased surface scattering, but it is a result of the increase in the density of twin boundaries. With twin boundaries included in the determination of grain size as a mean-intercept length, the resistivity data are well described by 2-parameter Matthiessen's rule summation of the Fuchs-Sondheimer and Mayadas Shatzkes models, with p and R parameters that are within experimental error equal to those in prior reports and are p = 0.48(+0.33/−0.31) and R = 0.27 ± 0.03.

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“…[10][11][12] As a result, by adding several nanometers of a low conductivity tantalum nitride barrier layer (~10 6 S/m) onto Cu (5.96 × 10 7 S/m), the effective width of a Cu wire would be decreased by 10 -20 %, thus drastically decreasing the overall conductivity of the nanoscale interconnects. [13][14] Therefore, a high-conductivity metallic material with Cu stabilization functionalities is needed for furtherdown-sized microelectronic interconnects.…”

Section: Introductionmentioning

confidence: 99%

Direct-Liquid-Evaporation Chemical Vapor Deposition of Nanocrystalline Cobalt Metal for Nanoscale Copper Interconnect Encapsulation

Feng

Gong

Lou

et al. 2017

ACS Appl. Mater. Interfaces

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In advanced microelectronics, precise design of liner and capping layers becomes critical, especially when it comes to the fabrication of Cu interconnects with dimensions lower than its mean free path. Herein, we demonstrate that direct-liquid-evaporation chemical vapor deposition (DLE-CVD) of Co is a promising method to make liner and capping layers for nanoscale Cu interconnects. DLE-CVD makes pure, smooth, nanocrystalline and highly conformal Co films with highly controllable growth characteristics. This process allows full Co 2 encapsulation of nanoscale Cu interconnects, thus stabilizing Cu against diffusion and electromigration. Electrical measurements and high-resolution elemental imaging studies show that the DLE-CVD Co encapsulation layer can improve the reliability and thermal stability of Cu interconnects. Also, with the high conductivity of Co, the DLE-CVD Co encapsulation layer can potentially further decrease the power consumption of nanoscale Cu interconnects, paving the way for Cu interconnects with higher efficiency in future high-end microelectronics.

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Surface and grain-boundary scattering in nanometric Cu films

Cited by 182 publications

References 30 publications

Universal scaling of the critical temperature for thin films near the superconducting-to-insulating transition

Universal scaling of the critical temperature for thin films near the superconducting-to-insulating transition

On twin density and resistivity of nanometric Cu thin films

Direct-Liquid-Evaporation Chemical Vapor Deposition of Nanocrystalline Cobalt Metal for Nanoscale Copper Interconnect Encapsulation

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