Noise Sources of a-Si[sub 1−x]Ge[sub x]O[sub y] Microbolometers And Their Reduction By Forming Gas Passivation

This paper presents the fabrication and reduction of noise voltage power spectral density (PSD) of Si x Ge y O 1−x− y uncooled infrared microbolometers with four different compositions. The noise reduction was achieved by passivating Si x Ge y O 1−x− y with Si 3 N 4 layers and by annealing the devices in vacuum at 200°C, 250°C, or 300°C with different time intervals from 1 to 5 h. The voltage noise PSD was measured with a bias current between 0.07 and 0.6 µA before and after annealing. The lowest measured noise voltage PSD before annealing was on devices with Si 0.053 Ge 0.875 O 0.072 and Si 0.041 Ge 0.902 O 0.057 films. They were 7.42 × 10 −15 and 2.07 × 10 −14 V 2 /Hz at 23 Hz, respectively. The corresponding 1/f -noise coefficients, K f , of the devices were 3.65 × 10 −14 and 3.01 × 10 −14 , respectively.The voltage noise PSD was reduced as the annealing time and temperature were increased. The lowest measured noise was 1.96 × 10 −14 V 2 /Hz at the corner frequency, 12 Hz, on a device with Si 0.034 Ge 0.899 O 0.067 film annealed at 300°C for 4 h, before annealing the noise was 4.09 × 10 −13 V 2 /Hz at 12 Hz. This corresponds to a factor of 24 reduction of noise. The testing results demonstrate that annealing at higher temperature 300°C reduced the low-frequency voltage noise PSD more than that of 200°C and 250°C temperatures.

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“…The measured 1/f -noise at 70 Hz was 1×10 −15 V 2 /Hz using 0.3 μA. The calculated 1/f noise coefficient K f was 2.21×10 −10 [51].…”

Section: Introductionmentioning

confidence: 99%

Noise Reduction of Amorphous Si_xGe_yO_1–x–yThin Films for Uncooled Microbolometers by Si₃N₄Passivation and Annealing in Vacuum

et al. 2016

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“…Forming gas is used as an atmosphere for processes that need the properties of hydrogen gas without the explosion hazard. The Forming gas is also widely used in silicon and thin film technology for passivation [6].…”

Section: Introductionmentioning

confidence: 99%

Gas flow simulation of a fluxless Si solder bonding oven

Illés

Kristóf

Jakab

et al. 2010

33rd International Spring Seminar on Electronics Technology, ISSE 2010

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In this paper the technology of the "Linn" type Si fluxless solder bonding oven and gas flow simulations of the oven are discussed. This oven is used for fixing silicon chips on metal substrates with high temperature solder bonding process. The solder is applied in a foil form which is placed between the Si chip and the metal substrate and does not contain any flux. Therefore a reducing agent (Forming gas which is a mixture of 10 vol% H 2 and 90 vol% N 2 ) has to be applied to avoid the oxidation of the joints. The key factors of this soldering process has been studied which are the suitable temperature and the adequate H 2 concentration. A 3D gas flow model of the oven has been prepared which is based on the FVM (Finite Volume Model) method. The thermal and gas flow circumstances -used the basic and new theoretical oven settings -have been compared by simulations applied the ANSYS -FLUENT system. The model was verified by the measurements of the H 2 concentration, the temperature and the pressure inside the oven. The aim was to find new oven settings in order to improve the mechanical stability and decrease the void percent of the joints.

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Noise Sources of a-Si[sub 1−x]Ge[sub x]O[sub y] Microbolometers And Their Reduction By Forming Gas Passivation

Cited by 2 publications

References 10 publications

Noise Reduction of Amorphous Si_xGe_yO_1–x–yThin Films for Uncooled Microbolometers by Si₃N₄Passivation and Annealing in Vacuum

Noise Reduction of Amorphous Si_xGe_yO_1–x–yThin Films for Uncooled Microbolometers by Si₃N₄Passivation and Annealing in Vacuum

Gas flow simulation of a fluxless Si solder bonding oven

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Noise Sources of a-Si[sub 1−x]Ge[sub x]O[sub y] Microbolometers And Their Reduction By Forming Gas Passivation

Cited by 2 publications

References 10 publications

Noise Reduction of Amorphous SixGeyO1–x–yThin Films for Uncooled Microbolometers by Si3N4Passivation and Annealing in Vacuum

Noise Reduction of Amorphous SixGeyO1–x–yThin Films for Uncooled Microbolometers by Si3N4Passivation and Annealing in Vacuum

Gas flow simulation of a fluxless Si solder bonding oven

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Noise Reduction of Amorphous Si_xGe_yO_1–x–yThin Films for Uncooled Microbolometers by Si₃N₄Passivation and Annealing in Vacuum

Noise Reduction of Amorphous Si_xGe_yO_1–x–yThin Films for Uncooled Microbolometers by Si₃N₄Passivation and Annealing in Vacuum