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High density indium bumping through pulse plating used for pixel X-ray detectors

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High density indium bumping through pulse plating used for pixel X-ray detectors. / Tian, Yingtao; Hutt, David A.; Liu, Changqing et al.
Electronic Packaging Technology & High Density Packaging, 2009. ICEPT-HDP '09. International Conference on. IEEE, 2009. p. 456-460.

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNConference contribution/Paperpeer-review

Harvard

Tian, Y, Hutt, DA, Liu, C & Stevens, B 2009, High density indium bumping through pulse plating used for pixel X-ray detectors. in Electronic Packaging Technology & High Density Packaging, 2009. ICEPT-HDP '09. International Conference on. IEEE, pp. 456-460. https://doi.org/10.1109/ICEPT.2009.5270712

APA

Tian, Y., Hutt, D. A., Liu, C., & Stevens, B. (2009). High density indium bumping through pulse plating used for pixel X-ray detectors. In Electronic Packaging Technology & High Density Packaging, 2009. ICEPT-HDP '09. International Conference on (pp. 456-460). IEEE. https://doi.org/10.1109/ICEPT.2009.5270712

Vancouver

Tian Y, Hutt DA, Liu C, Stevens B. High density indium bumping through pulse plating used for pixel X-ray detectors. In Electronic Packaging Technology & High Density Packaging, 2009. ICEPT-HDP '09. International Conference on. IEEE. 2009. p. 456-460 doi: 10.1109/ICEPT.2009.5270712

Author

Tian, Yingtao ; Hutt, David A. ; Liu, Changqing et al. / High density indium bumping through pulse plating used for pixel X-ray detectors. Electronic Packaging Technology & High Density Packaging, 2009. ICEPT-HDP '09. International Conference on. IEEE, 2009. pp. 456-460

Bibtex

@inproceedings{1f269d15127e4235bebd29dc3fa5d76e,
title = "High density indium bumping through pulse plating used for pixel X-ray detectors",
abstract = "High density indium bump bonding is in high demand for devices which operate under cryogenic environments, such as pixellated X-ray detectors for high energy physics, due to the outstanding ductility of indium even at liquid helium temperatures. For these assembly applications, the connection pitch size is shifting to below 50 μm, such that the packaging density, i.e. I/Os, may exceed 40,000/cm2. Electrodeposition is a promising approach to enable a low-cost and high yield bump bonding process, compared with conventional sputtering or evaporation which is currently utilized for small-scale production. Previous studies have shown the capability of electrodeposition to achieve high yield and high density indium bumps. The challenge exists to improve the bump height uniformity and consistency of electroplated indium bumps across the wafer at ultra-fine pitches with the highest yield. This paper is an initial investigation of the application of pulsed plating to the indium plating process and considers the influence of various current waveforms on the morphology and uniformity of the bumps. The results indicated that change in frequency and duty cycle did not have a significant influence on the indium bump morphology, but, together with the addition of a thief ring to the wafer design, pulse plating did have a noticeable impact on the bump height uniformity.",
author = "Yingtao Tian and Hutt, {David A.} and Changqing Liu and Bob Stevens",
year = "2009",
month = aug,
day = "10",
doi = "10.1109/ICEPT.2009.5270712",
language = "English",
isbn = "9781424446582",
pages = "456--460",
booktitle = "Electronic Packaging Technology & High Density Packaging, 2009. ICEPT-HDP '09. International Conference on",
publisher = "IEEE",

}

RIS

TY - GEN

T1 - High density indium bumping through pulse plating used for pixel X-ray detectors

AU - Tian, Yingtao

AU - Hutt, David A.

AU - Liu, Changqing

AU - Stevens, Bob

PY - 2009/8/10

Y1 - 2009/8/10

N2 - High density indium bump bonding is in high demand for devices which operate under cryogenic environments, such as pixellated X-ray detectors for high energy physics, due to the outstanding ductility of indium even at liquid helium temperatures. For these assembly applications, the connection pitch size is shifting to below 50 μm, such that the packaging density, i.e. I/Os, may exceed 40,000/cm2. Electrodeposition is a promising approach to enable a low-cost and high yield bump bonding process, compared with conventional sputtering or evaporation which is currently utilized for small-scale production. Previous studies have shown the capability of electrodeposition to achieve high yield and high density indium bumps. The challenge exists to improve the bump height uniformity and consistency of electroplated indium bumps across the wafer at ultra-fine pitches with the highest yield. This paper is an initial investigation of the application of pulsed plating to the indium plating process and considers the influence of various current waveforms on the morphology and uniformity of the bumps. The results indicated that change in frequency and duty cycle did not have a significant influence on the indium bump morphology, but, together with the addition of a thief ring to the wafer design, pulse plating did have a noticeable impact on the bump height uniformity.

AB - High density indium bump bonding is in high demand for devices which operate under cryogenic environments, such as pixellated X-ray detectors for high energy physics, due to the outstanding ductility of indium even at liquid helium temperatures. For these assembly applications, the connection pitch size is shifting to below 50 μm, such that the packaging density, i.e. I/Os, may exceed 40,000/cm2. Electrodeposition is a promising approach to enable a low-cost and high yield bump bonding process, compared with conventional sputtering or evaporation which is currently utilized for small-scale production. Previous studies have shown the capability of electrodeposition to achieve high yield and high density indium bumps. The challenge exists to improve the bump height uniformity and consistency of electroplated indium bumps across the wafer at ultra-fine pitches with the highest yield. This paper is an initial investigation of the application of pulsed plating to the indium plating process and considers the influence of various current waveforms on the morphology and uniformity of the bumps. The results indicated that change in frequency and duty cycle did not have a significant influence on the indium bump morphology, but, together with the addition of a thief ring to the wafer design, pulse plating did have a noticeable impact on the bump height uniformity.

U2 - 10.1109/ICEPT.2009.5270712

DO - 10.1109/ICEPT.2009.5270712

M3 - Conference contribution/Paper

SN - 9781424446582

SP - 456

EP - 460

BT - Electronic Packaging Technology & High Density Packaging, 2009. ICEPT-HDP '09. International Conference on

PB - IEEE

ER -