Ömer L. Gülder scite author profile

Laser-induced incandescence (LII) has proved to be a useful diagnostic tool for spatially and temporally resolved measurement of particulate (soot) volume fraction and primary particle size in a wide range of applications, such as steady flames, flickering flames, and Diesel engine exhausts. We present a novel LII technique for the determination of soot volume fraction by measuring the absolute incandescence intensity, avoiding the need for ex situ calibration that typically uses a source of particles with known soot volume fraction. The technique developed in this study further extends the capabilities of existing LII for making practical quantitative measurements of soot. The spectral sensitivity of the detection system is determined by calibrating with an extended source of known radiance, and this sensitivity is then used to interpret the measured LII signals. Although it requires knowledge of the soot temperature, either from a numerical model of soot particle heating or experimentally determined by detecting LII signals at two different wavelengths, this technique offers a calibration-independent procedure for measuring soot volume fraction. Application of this technique to soot concentration measurements is demonstrated in a laminar diffusion flame.

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Determination of the soot absorption function and thermal accommodation coefficient using low-fluence LII in a laminar coflow ethylene diffusion flame

Snelling

Liu

Smallwood

et al. 2004

Combustion and Flame

239

138

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Soot concentration and temperature measurements in co-annular, nonpremixed CH/air laminar flames at pressures up to 4 MPa

Thomson

Gülder

Weckman

et al. 2005

Combustion and Flame

173

122

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Soot formation in high pressure laminar diffusion flames

Karataş

Gülder

2012

Progress in Energy and Combustion Science

226

131

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Correlations of Laminar Combustion Data for Alternative S.I. Engine Fuels

Gülder¹

1984

194

126

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Numerical study on the influence of hydrogen addition on soot formation in a laminar ethylene–air diffusion flame

Guo

Liu

Smallwood

et al. 2006

Combustion and Flame

165

101

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Numerical modelling of soot formation and oxidation in laminar coflow non-smoking and smoking ethylene diffusion flames

Liu¹,

Guo²,

Smallwood³

et al. 2003

TCTM

117

102

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Ömer L. Gülder

The chemical effects of carbon dioxide as an additive in an ethylene diffusion flame: implications for soot and NOx formation

A calibration-independent laser-induced incandescence technique for soot measurement by detecting absolute light intensity

Determination of the soot absorption function and thermal accommodation coefficient using low-fluence LII in a laminar coflow ethylene diffusion flame

Soot concentration and temperature measurements in co-annular, nonpremixed CH/air laminar flames at pressures up to 4 MPa

Soot formation in high pressure laminar diffusion flames

Correlations of Laminar Combustion Data for Alternative S.I. Engine Fuels

Numerical study on the influence of hydrogen addition on soot formation in a laminar ethylene–air diffusion flame

Numerical modelling of soot formation and oxidation in laminar coflow non-smoking and smoking ethylene diffusion flames

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