The Influences of Iodide Ion on Cu Electrodeposition and TSV Filling

Kim, Myung Joon; Kim, Hoe Chul; Kim, Jae Jeong

doi:10.1149/2.1111608jes

Cited by 28 publications

(35 citation statements)

References 35 publications

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“…The Cl − adsorbed on a Cu surface has been shown to activate Cu deposition, 55 but adsorbed I − suppresses Cu deposition. 56 The relatively covalent Cu−I bond is stronger than the relatively ionic Cu−Cl bond and involves a greater amount of charger transfer from I − to Cu. This stronger interaction between I − and Cu hinders atomic addition.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…Addition of I – replaces Cl – on the {111} facet, leading to its passivation. The Cl – adsorbed on a Cu surface has been shown to activate Cu deposition, but adsorbed I – suppresses Cu deposition . The relatively covalent Cu–I bond is stronger than the relatively ionic Cu–Cl bond and involves a greater amount of charger transfer from I – to Cu.…”

Section: Results and Discussionmentioning

confidence: 99%

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Isotropic Iodide Adsorption Causes Anisotropic Growth of Copper Microplates

et al. 2020

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Control over the shape of a metal nanostructure grants control over its properties, but the processes that cause solution-phase anisotropic growth of metal nanostructures are not fully understood. This article shows why the addition of a small amount (75–100 μM) of iodide ions to a Cu nanowire synthesis results in the formation of Cu microplates. Microplates are 100 nm thick and micronwide crystals that are thought to grow through atomic addition to {100} facets on their sides instead of the {111} facets on their top and bottom surfaces. Single-crystal electrochemical measurements show that the addition of iodide ions decreased the rate of Cu addition to Cu(111) by 8.2 times due to the replacement of adsorbed chloride by iodide. At the same time, the addition of iodide ions increased the rate of Cu addition to Cu(100) by 4.0 times due to the replacement of a hexadecylamine (HDA) self-assembled monolayer with the adsorbed iodide. The activation of {100} facets and passivation of {111} facets with increasing iodide ion concentration correlated with an increasing yield of microplates. Ab initio thermodynamics calculations show that, under the experimental conditions, a minority of iodide ions replaces an overwhelming majority of chloride and HDA on both Cu(100) and Cu(111). While Cu nanowire formation is predicted (and observed) in solutions containing chloride and HDA, the calculations indicate that a strong thermodynamic driving force occurs for {111} facet (and microplate) growth when a small amount of iodide is present, consistent with the experiment.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Section: Results and Discussionmentioning

confidence: 99%

Isotropic Iodide Adsorption Causes Anisotropic Growth of Copper Microplates

et al. 2020

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“…The solution-based electrodeposition of metals has been extensively studied academically as well as provided industrial solutions for practical devices. , One interesting and applicable avenue of research has been the use of surface modifiers to affect the structure and morphology of deposited metals, for example, surfactants, organic molecules, and halide salts . In liquid-based electrochemical deposition, iodine adsorption on metal surfaces is well known to influence the kinetics of crystallization and the morphology of metal growth and has been frequently utilized to form compact, uniform films. − For solid-state electrodeposition, several research teams have shown that modification of the lithium-metal surface has significantly improved the galvanic cycling properties using solid-state electrolytes; − however, iodine adsorption has not been evident during the solid-state deposition of lithium metal nor has its influence on cell failure. Understanding the electrochemical interphase is a vital step to engineering practical SSBs.…”

Section: Introductionmentioning

confidence: 99%

Role of Lithium Iodide Addition to Lithium Thiophosphate: Implications beyond Conductivity

Singh¹,

Horwath

Bonnick³

et al. 2020

Chem. Mater.

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Because of their high conductivity and potential to utilize lithium metal, lithium thiophosphate electrolytes have attracted significant attention to realize solid-state batteries for vehicle applications. However, lithium metal still presents many challenges in potentially maximizing the battery energy density. One important requirement is to limit the amount of lithium metal during cell construction or to operate the cell under limited lithium conditions. Here, the interface between lithium thiophosphate and lithium iodide-doped lithium thiophosphate with lithium metal is investigated. Lithium iodide plays a protective role at the interface and enables improved lithium cycling. Operando transmission electron microscopy analysis reveals delamination and dead lithium at the interface as major challenges for solid-state batteries.

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“…To determine C I − in the target plating bath, a RC-CVS analysis was performed as follows: (1) assessment of Q 0 from the CVS analysis of the base solution (volume: 52 mL), (2) measurement of Q after adding the standard solution to the base solution (addition volume: 1 mL), (3) consecutive repetition (eight times) of the procedure (2) to generate a response curve, (4) preparation of a new bath and the appraisal of Q 0 (5), evaluation of Q t after adding the target solutions to the base solution (addition volume: 3 mL), ( 6) determination of C I − in the target solutions by interpolating the Q t /Q 0 value to the response curve by using Eq. 2. where C St was the known concentration of I − in the standard solution (400 μM), V T the addition volume of the target solution (3 mL), x * the addition volume value in the response curve at the same Q/Q 0 with Q t /Q 0 obtained from the target solution, and V V the pre-dosed volume of the base solution (52 mL).…”

Section: Methodsmentioning

confidence: 99%

Cyclic Voltammetry Stripping Analysis to Determine Iodide Ion Concentration in Cu Plating Bath

Yoon

Ham

Kim

et al. 2018

J. Electrochem. Soc.

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Accurate monitoring of an electroplating bath's chemical balance is a key factor for maintaining its performance during a long-term plating operation. In this paper, a method is suggested to measure the concentration of iodide ion (I − ), an inorganic leveler for through-silicon via (TSV) filling, based on its electrochemical response. During the operation of plating, I − was consumed via the reaction with Cu + (Cu + + I → CuI), an oxidation reaction (2I − → I 2 + 2e), as well as a physical incorporation. The I − concentration decrease resulted in a degradation of the bath, while the major byproducts (CuI and I 2 ) rarely influenced on bath performance. In order to monitor the I − concentration by cyclic voltammetry stripping (CVS) analysis, the electrochemical response of I − was examined at various conditions. I − suppressed the Cu electrodeposition rate; this response was dependent on the mass transport of I − and the applied potential of cathode. A subsequent effective coverage analysis revealed that not only I − but also Cu(I) iodide (CuI) was a key inhibitor, demonstrating that the inhibition of I − becomes weaker at a negative potential. With a responsive curve (RC)-CVS analysis conducted at an optimized condition, a linear relationship between the real and measured concentrations could be found, irrespective of other additives' concentrations. The method suggested in this paper enabled the direct monitoring of the I − concentration in a Cu plating bath.

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The Influences of Iodide Ion on Cu Electrodeposition and TSV Filling

Cited by 28 publications

References 35 publications

Isotropic Iodide Adsorption Causes Anisotropic Growth of Copper Microplates

Isotropic Iodide Adsorption Causes Anisotropic Growth of Copper Microplates

Role of Lithium Iodide Addition to Lithium Thiophosphate: Implications beyond Conductivity

Cyclic Voltammetry Stripping Analysis to Determine Iodide Ion Concentration in Cu Plating Bath

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