Effect of encapsulation on electronic transport properties of nanoscale Cu(111) films

Shinde, Prashant P.; Adiga, Shashishekar P.; Pandian, S.; Mayya, K. S.; Shin, Hyeon‐Jin; Park, Seongjun

doi:10.1038/s41598-019-40193-6

Cited by 6 publications

(2 citation statements)

References 50 publications

(59 reference statements)

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“…The removal of Cu oxide by pretreatment at 400 °C led to the formation of an abrupt Gr#01/Cu interface. The Cu–O bonds deteriorated the resistivity of the Cu, and the removal of CuO during graphene capping can explain the reduction in the resistivity of Cu after graphene capping. , Furthermore, graphene is known to have a low density of states (DOS) . A capping layer with a low DOS can shift the diffuse scattering of electrons at the Cu surface toward a specular one, leading to a higher Cu conductivity. , By considering other factors, such as the resistivity of graphene and the grain size of Cu, we can conclude that the Cu surface is improved by graphene capping, leading to a further reduction in Cu resistivity.…”

Section: Resultsmentioning

confidence: 96%

“…The Cu−O bonds deteriorated the resistivity of the Cu, and the removal of CuO during graphene capping can explain the reduction in the resistivity of Cu after graphene capping. 17,34 Furthermore, graphene is known to have a low density of states (DOS). 35 A capping layer with a low DOS can shift the diffuse scattering of electrons at the Cu surface toward a specular one, leading to a higher Cu conductivity.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

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Graphene Capping of Cu Back-End-of-Line Interconnects Reduces Resistance and Improves Electromigration Lifetime

Shin

Cho

Nam

et al. 2023

ACS Appl. Nano Mater.

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As the pitch size of Cu lines in the back-end-of-line (BEOL) is decreased below a few tens of nanometers, resistivity exponentially increases and electromigration (EM) causes device failure. Graphene has shown promise for both problems, but graphene grown at 400 °C for the BEOL-compatible process is far from its ideal honeycomb lattice. In this report, we successfully demonstrated that graphene grown at low temperatures improves Cu resistance by 5% and increased the EM lifetime by 78 times compared to Cu-only interconnect. We proved that the resistivity gain by graphene capping is due to the improvement of the Cu surface, excluding other effects of parallel resistivity and grain boundary scattering. First-principles calculation demonstrated that the graphene edge–Cu bond can inhibit the migration of Cu vacancies, thereby improving the EM lifetime. We manipulated the graphene nanostructure to have more edge contact with Cu, which enhanced the EM lifetime by 116 times compared to Cu-only interconnect. This work systematically investigated the causes for the decrease in resistance of graphene-capped Cu and discovered key factors that contribute the improvement of the interconnect reliability.

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Section: Resultsmentioning

confidence: 96%

Section: ■ Results and Discussionmentioning

confidence: 99%

Graphene Capping of Cu Back-End-of-Line Interconnects Reduces Resistance and Improves Electromigration Lifetime

Shin

Cho

Nam

et al. 2023

ACS Appl. Nano Mater.

Self Cite

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The 3D Monolithically Integrated Hardware Based Neural System with Enhanced Memory Window of the Volatile and Non‐Volatile Devices

Jeon,

Seo,

Lee

et al. 2024

Advanced Science

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Abstract3D neuromorphic hardware system is first demonstrated in neuromorphic application as on‐chip level by integrating array devices with CMOS circuits after wafer bonding (WB) and interconnection process. The memory window of synaptic device is degraded after WB and 3 Dimesional (3D) integration due to process defects and thermal stress. To address this degradation, Ag diffusion in materials of Ta2O5 and HfO2 is studied in a volatile memristor, furthermore, the interconnection and gate metal Ru are investigated to reduce defective traps of gate interface in non‐volatile memory devices. As a result, a memory window is improved over 106 in both types of devices. Improved and 3D integrated 12 × 14 array devices are identified in the synaptic characteristics according to the change of the synaptic weight from the interconnected Test Element Group (TEG) of the Complementary Metal Oxide Semiconductor (CMOS) circuits. The trained array devices present recognizable image of letters, achieving an accuracy rate of 92% when utilizing a convolutional neural network, comparing the normalized accuracy of 93% achieved by an ideal synapse device. This study proposes to modulate the memory windows up to 106 in an integrated hardware‐based neural system, considering the possibility of device degradation in both volatile and non‐volatile memory devices demonstrated by the hardware neural system.

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Surface sulfurization of liner and ruthenium metallization to reduce interface scattering for Low-Resistance interconnect

Chen,

Hsiao,

et al. 2024

Applied Surface Science

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Effect of encapsulation on electronic transport properties of nanoscale Cu(111) films

Cited by 6 publications

References 50 publications

Graphene Capping of Cu Back-End-of-Line Interconnects Reduces Resistance and Improves Electromigration Lifetime

Graphene Capping of Cu Back-End-of-Line Interconnects Reduces Resistance and Improves Electromigration Lifetime

The 3D Monolithically Integrated Hardware Based Neural System with Enhanced Memory Window of the Volatile and Non‐Volatile Devices

Surface sulfurization of liner and ruthenium metallization to reduce interface scattering for Low-Resistance interconnect

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