Dissertation in the field of micro- and nanosciences, Jeanette Lindroos

2015-04-24 12:00:00 2015-04-24 16:00:00 Europe/Helsinki Dissertation in the field of micro- and nanosciences, Jeanette Lindroos The dissertation is entitled: "Copper-related light-induced degradation in crystalline silicon". http://old.eea.aalto.fi/en/midcom-permalink-1e4c17347588d9ec17311e487def7f2ab86c8d7c8d7 Otakaari 1, 02150, Espoo

The dissertation is entitled: "Copper-related light-induced degradation in crystalline silicon".

24.04.2015 / 12:00 - 16:00
lecture hall E, Otakaari 1, 02150, Espoo, FI

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Jeanette Lindroos will defend the doctoral dissertation entitled: "Copper-related light-induced degradation in crystalline silicon".

Unintentional copper and nickel impurities are common in silicon-based devices due to the
abundance of contamination sources in industrial silicon crystallization and wafer processing
lines. High solubility and diffusivity result readily in significant impurity concentrations,
which cause charge-carrier recombination and reduce the device response. This work confirms that nickel diffuses as fast as copper in silicon, emphasizing the importance of contamination control in silicon-based devices.

Copper contamination is known to form recombination-active defects in silicon during illumination, which is observed as copper-related light-induced degradation (Cu-LID). In order to identify the extent of degradation in silicon-based devices, this work focuses on determining the properties of Cu-LID in gallium-doped Czochralski (Cz) silicon, boron-doped Cz-Si, and boron-doped multicrystalline silicon. Cu-LID is determined to be predominantly a bulk recombination effect, and the formed defects are found to be stable at 200°C. Slower Cu-LID is observed in Ga-Si compared to B-Si, suggesting that Cu-LID formation is limited by the effective copper diffusivity.

Cu-LID is shown to completely disappear after negative sample surface charging and illumination. The negative surface charge is achieved by corona charging or aluminum oxide deposition. Cu-LID removal is observed to have no impact on classical boron-oxygen-related light-induced degradation (BO-LID), which has previously been shown to recover at 200°C. Unlike BO-LID, the activation energy of Cu-LID is found to depend on the silicon doping concentration. Hence, Cu-LID and BO-LID are concluded to be two different degradation effects, which can occur simultaneously in silicon-based devices.

Opponent: Professor Eicke Weber Universität Freiburg, Germany

Supervisor: Professor Hele Savin Aalto University School of Electrical Engineering, Department of Micro- and Nanosciences

https://aaltodoc.aalto.fi/handle/123456789/15601

Contact information:

Jeanette Lindroos
jeanette.lindroos@aalto.fi
tel. +358 50 4318 869