Thermal Challenges in Next-Generation Electronic Systems

Garimella, Suresh V.; Fleischer, Amy S.; Murthy, Jayathi Y.; Keshavarzi, Ali; Prasher, Ravi; Patel, Chandrakant D.; Bhavnani, Sushil H.; Venkatasubramanian, R.; Mahajan, Ravi; Joshi, Yogendra; Sammakia, Bahgat; Myers, Bruce A.; Chorosinski, Len; Baelmans, Martine; Sathyamurthy, Prabhu; Raad, Peter E.

doi:10.1109/tcapt.2008.2001197

Cited by 363 publications

(174 citation statements)

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“…As an example, the reported operating temperature of a central processing unit (CPU) can reach temperatures as high as 150 °C [8][9][10] . However, the oxidation behavior of copper at a temperature below 300 °C has received little attention.…”

Section: Discussionmentioning

confidence: 99%

“…Copper has been widely used as bonding wires or interconnects within many electronic components. Due to increasing component density and decreasing line width, the temperature within an electronic device may reach a temperature above 200 °C during operation [8][9][10] . In this study, the oxidation behavior of copper at 200 °C and 300 C in air is investigated.…”

Section: Introductionmentioning

confidence: 99%

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Oxidation Behavior of Copper at a Temperature below 300 °C and the Methodology for Passivation

2016

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In this study, we investigate the oxidation behavior of copper at temperatures below 300 °C and its mechanism. A methodology to slow down the oxidation rate is then proposed based on the observed mechanism. The oxides formed after oxidation at low temperatures have fine crystal sizes; the rate constants reach 2×10 -15 m 2 /s and 6×10 -14 m 2 /s at 200 °C and 300 °C, respectively. A passivation treatment at 600 °C in nitrogen produces a thin oxide layer composed of relatively large Cu 2 O crystals. The presence of such a layer slows down the oxidation rate constants by an order of magnitude. This study demonstrates that the oxidation of copper at low temperatures is controlled by the grain boundary diffusion. Increasing the crystal size in the surface oxide reduces the oxidation rate significantly.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Oxidation Behavior of Copper at a Temperature below 300 °C and the Methodology for Passivation

2016

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“…Efficient heat removal became a critical issue for the performance and reliability of modern electronic, optoelectronic, photonic devices and systems. Thermal interface materials (TIMs), applied between heat sources and heat sinks, are essential ingredients of thermal management [2][3][4][5][6]. Conventional TIMs filled with thermally conductive particles require high volume fractions f of filler (f~50%) to achieve thermal conductivity K of the composite in the range of ~1-5 W/mK at room temperature (RT) [3][4][5][6].…”

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confidence: 99%

Graphene–Multilayer Graphene Nanocomposites as Highly Efficient Thermal Interface Materials

2012

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We found that an optimized mixture of graphene and multilayer graphene -produced by the high-yield inexpensive liquid-phase-exfoliation technique -can lead to an extremely strong enhancement of the cross-plane thermal conductivity K of the composite. The "laser flash" measurements revealed a record-high enhancement of K by 2300 % in the graphene-based polymer at the filler loading fraction f =10 vol. %. It was determined that a relatively high concentration of single-layer and bilayer graphene flakes (~10-15%) present simultaneously with thicker multilayers of large lateral size (~ 1 m) were essential for the observed unusual K enhancement. The thermal conductivity of a commercial thermal grease was increased from an initial value of ~5.8 W/mK to K=14 W/mK at the small loading f=2%, which preserved all mechanical properties of the hybrid. Our modeling results suggest that graphene -multilayer graphene nanocomposite used as the thermal interface material outperforms those with carbon nanotubes or metal nanoparticles owing to graphene's aspect ratio and lower Kapitza resistance at the graphene -matrix interface.

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“…Increasingly, heat looms as the single largest obstacle to computing's continued advancement 1 . The problem is fundamental: the smaller and more densely packed circuits become, the hotter they get.…”

mentioning

confidence: 99%