Dynamic through-silicon-via filling process using copper electrochemical deposition at different current densities

Wang, Fuliang; Zhao, Zhipeng; Nie, Nantian; Wang, Feng; Zhu, Wenhui

doi:10.1038/srep46639

Cited by 23 publications

(14 citation statements)

References 28 publications

(30 reference statements)

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“…Such a setup requires large-volume deposition baths with high concentrations of chemical reagents that produce large amounts of effluent. The current maximum deposition rate, for instance, for the fabrication of copper in a printed circuit board or in a silicon-via-filling process, is relatively small (∼0.1–1.5 μm min –1 at 30–40 °C) using such complex baths. ,, Therefore, high-performance, area-selective deposition processes that enable the direct deposition of metal patterns at high rates using small-volume baths at low concentrations need to be developed to overcome these restrictions; they would also strongly impact on the abovementioned environmental and energy-related issues.…”

Section: Introductionmentioning

confidence: 99%

Controlling Interfacial Ion-Transport Kinetics Using Polyelectrolyte Membranes for Additive- and Effluent-free, High-Performance Electrodeposition

Akamatsu

Kimura

Takashima

et al. 2021

ACS Appl. Mater. Interfaces

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The development of high-performance, environmentally friendly electrodeposition processes is critical for emerging coating technologies because current technologies use highly complex baths containing metal salts, supporting electrolytes, and various kinds of organic additives, which are problematic from both environmental and cost perspectives. Here, we show that a 200 μm-thin polyelectrolyte membrane sandwiched between electrodes effectively concentrates metal ions through interfacial penetration, which increases the conductance between the electrodes to 0.30 S and realizes solid-state electrodeposition that produces no mist, sludge, or even waste effluent. Both, experimental results and theoretical calculations, reveal that electrodeposition is controlled by ion penetration at the solution/polyelectrolyte interface, providing an intrinsically different ion-transport mechanism to that of conventional diffusion-controlled electrodeposition. The setup, which includes 0.50 mol L −1 copper sulfate and no additives, delivers a maximum current density of 300 mA cm −2 , which is nearly fivefold higher than that of a current commercial plating bath containing organic additives.

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Section: Introductionmentioning

confidence: 99%

Controlling Interfacial Ion-Transport Kinetics Using Polyelectrolyte Membranes for Additive- and Effluent-free, High-Performance Electrodeposition

Akamatsu

Kimura

Takashima

et al. 2021

ACS Appl. Mater. Interfaces

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“…Furthermore, Cu metallization is better than aluminum in terms of resistance to electromigration and stress voiding phenomena [3,4]. The main technique to produce thick copper film on silicon substrate is electrochemical deposition (ECD), which is a highly efficient wet process for depositing a uniform layer of metal (like copper) on a semiconductor wafer [5,6]. Furthermore, Cu front metal is very attractive for integrated circuit (IC) manufacturing because it enables high-reliable Cu-Cu wire bonding solution [7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Warpage Behavior on Silicon Semiconductor Device: The Impact of Thick Copper Metallization

et al. 2021

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Electrochemical deposited (ECD) thick film copper on silicon substrate is one of the most challenging technological brick for semiconductor industry representing a relevant improvement from the state of art because of its excellent electrical and thermal conductivity compared with traditional materials, such as aluminum. The main technological factor that makes challenging the industrial implementation of thick copper layer is the severe wafer warpage induced by Cu annealing process, which negatively impacts the wafer manufacturability. The aim of presented work is the understanding of warpage variation during annealing process of ECD thick (20 μm) copper layer. Warpage is experimentally characterized at different temperature by means of Phase-Shift Moiré principle, according to different annealing profiles. Physical analysis is employed to correlated the macroscopic warpage behavior with microstructure modification. A linear Finite Element Model (FEM) is developed to predict the geometrically stress-curvature relation, comparing results with analytical models.

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“…In recent years, decreasing the through silicon via (TSV) size has caused a rapid increase in the aspect ratio (AR) during pitching in technology nodes below 10 nm [1], resulting in poor film coverage of barrier/seed layers owing to thermomechanical stress [2]. Problematic resistance (R)-capacitance (C) delays with increased resistance caused the boundary scattering and shorter mean free paths that result from using nano-thick copper as a reasonable material for interconnections [3][4][5].…”

Section: Introductionmentioning

confidence: 99%

Effect of Pulsed Light Irradiation on Patterning of Reduction Graphene Oxide-Graphene Oxide Interconnects for Power Devices

Choi

Pyo

2021

Coatings

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Reduction graphene oxide (r-GO) lines on graphene oxide (GO) films can be prepared by a photocatalytic reduction and photothermal reduction method. A mechanism of partial GO reduction by pulsed photon energy is identified for preparing patterned rGO-GO films. The photocatalytic reduction method efficiently reduces GO at low photon energies. The successful production of a patterned rGO-GO film without damage by the photo thermal reduction method is possible when an energy density of 6.0 or 6.5 J/m2 per pulse is applied to a thin GO film (thickness: 0.45 μm). The lowest resistance obtained for a photo-reduced rGO line is 0.9 kΩ sq−1. The GO-TiO2 pattern fabricated on the 0.23 μm GO-TiO2 composite sheet through the energy density of each pulse is 5.5 J/m2 for three pulses.

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Dynamic through-silicon-via filling process using copper electrochemical deposition at different current densities

Cited by 23 publications

References 28 publications

Controlling Interfacial Ion-Transport Kinetics Using Polyelectrolyte Membranes for Additive- and Effluent-free, High-Performance Electrodeposition

Controlling Interfacial Ion-Transport Kinetics Using Polyelectrolyte Membranes for Additive- and Effluent-free, High-Performance Electrodeposition

Warpage Behavior on Silicon Semiconductor Device: The Impact of Thick Copper Metallization

Effect of Pulsed Light Irradiation on Patterning of Reduction Graphene Oxide-Graphene Oxide Interconnects for Power Devices

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