L.K.J. Vandamme scite author profile

Experimental studies on l/f noise are reviewed with emphasis on experiments that may be decisive in finding the correct theoretical model for this type of noise. The experimental results are confronted with two theories: McWhorter's surface state theory and Clarke and Voss's theory of local temperature fluctuations. The applicability of either theory turns out to be very limited. The validity of an empirical relation is investigated. Its application to electronic devices proves rather successful. Experiments show that l/f noise obeying the empirical relation, which we shall call a: noise, is a fluctuation in that part of the mobility that is due to lattice scattering.

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Noise as a diagnostic tool for quality and reliability of electronic devices

Vandamme

1994

IEEE Trans. Electron Devices

526

232

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General relation between refractive index and energy gap in semiconductors

Hervé¹,

Vandamme²

1994

Infrared Physics & Technology

609

180

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1/f noise in MOS devices, mobility or number fluctuations?

Vandamme

Rigaud

1994

IEEE Trans. Electron Devices

310

151

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What Do We Certainly Know About $\hbox{1}/f$ Noise in MOSTs?

Vandamme

Hooge

2008

IEEE Trans. Electron Devices

220

140

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Empirical temperature dependence of the refractive index of semiconductors

Hervé¹,

Vandamme²

1995

259

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Values of the temperature coefficient of the refractive index were obtained from the derivation of a simple relation between energy band-gap and refractive index in semiconductors. These values, (dn/dT)/n, were compared to the experimental data found in literature. Our model, with only one fitting parameter dB/dT=2.5×10−5 K−1 for all semiconductors, results in the best agreement with experimental data.

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Critical discussion on unified 1/f noise models for MOSFETs

Vandamme

2000

IEEE Trans. Electron Devices

161

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Electrochemical noise and impedance of Au electrode/electrolyte interfaces enabling extracellular detection of glioma cell populations

Rocha

Schlett

Kintzel

et al. 2016

Sci Rep

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Microelectrode arrays (MEA) record extracellular local field potentials of cells adhered to the electrodes. A disadvantage is the limited signal-to-noise ratio. The state-of-the-art background noise level is about 10 μVpp. Furthermore, in MEAs low frequency events are filtered out. Here, we quantitatively analyze Au electrode/electrolyte interfaces with impedance spectroscopy and noise measurements. The equivalent circuit is the charge transfer resistance in parallel with a constant phase element that describes the double layer capacitance, in series with a spreading resistance. This equivalent circuit leads to a Maxwell-Wagner relaxation frequency, the value of which is determined as a function of electrode area and molarity of an aqueous KCl electrolyte solution. The electrochemical voltage and current noise is measured as a function of electrode area and frequency and follow unambiguously from the measured impedance. By using large area electrodes the noise floor can be as low as 0.3 μVpp. The resulting high sensitivity is demonstrated by the extracellular detection of C6 glioma cell populations. Their minute electrical activity can be clearly detected at a frequency below about 10 Hz, which shows that the methodology can be used to monitor slow cooperative biological signals in cell populations.

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L.K.J. Vandamme

Experimental studies on 1/f noise

Noise as a diagnostic tool for quality and reliability of electronic devices

General relation between refractive index and energy gap in semiconductors

1/f noise in MOS devices, mobility or number fluctuations?

What Do We Certainly Know About $\hbox{1}/f$ Noise in MOSTs?

Empirical temperature dependence of the refractive index of semiconductors

Critical discussion on unified 1/f noise models for MOSFETs

Electrochemical noise and impedance of Au electrode/electrolyte interfaces enabling extracellular detection of glioma cell populations

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