Cite this Article
Liu Guannan, Liu Dong. Reconstruction model for temperature and concentration profiles of soot and metal-oxide nanoparticles in a nanofluid fuel flame by using a CCD camera. Chinese Physics B, 2018, 27(5): 054401  
Permissions
Reconstruction model for temperature and concentration profiles of soot and metal-oxide nanoparticles in a nanofluid fuel flame by using a CCD camera
Liu Guannan1, 2, Liu Dong1, 2, †
MIIT Key Laboratory of Thermal Control of Electronic Equipment, School of Energy and Power Engineering, Nanjing University of Science and Technology, Nanjing 210094, China
Advanced Combustion Laboratory, School of Energy and Power Engineering, Nanjing University of Science and Technology, Nanjing 210094, China

 

† Corresponding author. E-mail: dongliu@njust.edu.cn

Abstract

This paper presents a numerical study on the simultaneous reconstruction of temperature and volume fraction fields of soot and metal-oxide nanoparticles in an axisymmetric nanofluid fuel sooting flame based on the radiative energy images captured by a charge-coupled device (CCD) camera. The least squares QR decomposition method was introduced to deal with the reconstruction inverse problem. The effects of ray numbers and measurement errors on the reconstruction accuracy were investigated. It was found that the reconstruction accuracies for volume fraction fields of soot and metal-oxide nanoparticles were easily affected by the measurement errors for radiation intensity, whereas only the metal-oxide volume fraction field reconstruction was more sensitive to the measurement error for the volume fraction ratio of metal-oxide nanoparticles to soot. The results show that the temperature, soot volume fraction, and metal-oxide nanoparticles volume fraction fields can be simultaneously and accurately retrieved for exact and noisy data using a single CCD camera.

PACS: 44.40.+a;44.05.+e;02.30.Zz
Keyword:simultaneous reconstruction;temperature distribution;soot and metal-oxide volume fraction;nanofluid fuel flame
1. Introduction

As hydrocarbon fuel supplies are gradually diminishing and environmental pollution is getting worse, the need for new alternatives to conventional hydrocarbon fuels is increasingly imperative. Furthermore, the development of hypersonic vehicle propulsion systems and power microelectromechanical systems are largely dependent on the physical and thermal properties of liquid fuels. Nanofluid fuels are uniform and stable suspensions containing available nanoscale additives in dilute concentrations ( ),[1,2] which can enhance fuel energy density,[3,4] shorten ignition delay time,[5,6] improve reaction rates,[7,8] and reduce pollutant emissions.[9,10] In addition, many studies have shown that the addition of nanoparticles can promote the heat transfer rate of the base fuel.[1116] Therefore, nanofluid fuels are expected to be the next generation of new fuels.

Sabourin et al.[7] compared the combustion of the monopropellant nitromethane with that of nitromethane containing colloidal particles of functionalized graphene sheets or metal hydroxides at room temperature and high-pressure conditions in a silica glass tube. The results demonstrate that the ignition temperature decreases and the burning rates increase for the suspensions compared to those of the monopropellant alone, especially in the burning rate improvement of greater than 175% for graphene sheet suspension. Gan et al.[17,18] investigated the burning characteristics of fuel droplets containing nanosized aluminum, boron, and iron particles, and they proposed various combustion stages (preheating, ignition, classical combustion, microexplosion, surfactant flame, and particle droplet combustion) through observing the recorded burning images of the nanofluid fuel droplets. Tanvir et al.[19] utilized a droplet stream flame to measure the burning rate of ethanol droplets with the addition of graphite nanoparticles, which was determined by estimating droplet sizes at corresponding locations via backlight shadowgraphy using a high-speed camera. Liu et al.[20] analyzed the geometrical parameters of nanofluid fuel flames using an image processing technique to study the combustion characteristics of flowing nanofluid fuels in a half-opening slot tube.

To date, studies on the combustion characteristics of nanofluid fuels are still in the primary stage and the combustion diagnostic methods for nanofluid fuels remain very limited. Temperature, volume fraction fields of soot, and metal-oxide nanoparticles in nanofluid fuel flame are important combustion characteristic parameters and should be measured accurately in the burning process of nanofluid fuel for the in-depth study.

The temperature and particle volume fraction measurement methods of the participating media are categorized as contact and noncontact diagnostic methods. The thermocouple method is one of the most common contact methods. Gan et al.[17] used a type-K thermocouple to suspend the nanofluid fuel droplet and measure its temperature history during the burning process. However, the nanoparticles in the droplet flame easily aggregate and deposit on the thermocouple surface, which decreases the accuracy and sensitivity of temperature measurement. Additionally, only the temperature of the single point in contact with the thermocouple tip can be measured.

Optical measurement techniques are currently preferred for their noncontact and multidimensional measurement advantages, which include tomography reconstruction, light extinction/scattering, and laser-induced incandescence (LII). Because a high-quality background radiation source is needed for transmission measurements, self-emission tomography systems have received particular attention in the last decade. The inverse analysis of radiative heat transfer based on a self-emission tomography system can be used to reconstruct the temperature, soot volume fraction, and radiation property fields of flame from the knowledge of the exit radiation intensity at the boundary surfaces. These days, the optical diagnostic technology combined with inverse radiation analysis for retrieving combustion characteristic fields of flame is developing fast and intensively.[2143] Zhou et al.[21] first simulated the three-dimensional (3D) temperature distributions in furnaces through radiative energy images captured by multiple charge-coupled device (CCD) cameras mounted around the furnace. They proposed a fast algorithm based on the Monte Carlo method and angular factor effective of image formation to calculate the radiative energy, and used a modified Tikhonov regularization method to solve the inversion problem of 3D temperature distributions. Brisley et al.[23] and Lu et al.[25] applied an imaging-based multicolor pyrometric system combined with a novel optical splitting/filtering device to visualize temperature distributions in a coal-fired flame. Liu et al.[32] developed an inverse radiation analysis based on backward Monte Carlo (BMC) methods and the least squares QR (LSQR) algorithm for concurrent reconstruction of a temperature field and radiative properties in a two-dimensional (2D) rectangular, absorbing, emitting, and scattering gray medium by means of CCD cameras. Subsequently, Liu et al.[33,34] utilized multiple CCD cameras to retrieve the soot temperature and volume fraction profiles in a 3D optically thin flame. Niu et al.[38,39] developed hybrid LSQR-particle swarm optimization (LSQR-PSO) and LSQR-stochastic particle swarm optimization (LSQR-SPSO) algorithms to simultaneously reconstruct 3D temperature distribution and radiative properties of participating media. They found that the temperature field could be estimated to be more accurate than the absorption coefficients and the reconstruction accuracy of temperature distributions, scattering coefficients, and absorption coefficients decrease with the increase in extinction coefficient, but varies little with the scattering albedo. Ni et al.[40] used four CCD cameras combined with liquid crystal tunable filters (LCTF) to capture multispectral flame images for obtaining the line-of-sight radiation intensities, from which temperature and soot volume fraction profiles could be determined. The results show that the average error of the reconstructed volume fraction can be decreased from 8% by a two-color method to 3.17% through a multiwavelength method. Xu et al.[43] proposed a novel optical sectioning tomography for the measurement of 3D temperature of a flame through a single camera in combination with an ionic electrowetting-based variable-focus liquid lens.

The optical reconstruction methods mentioned above only focused on soot-involved flames, but the method for nanofluid fuel flame, in which metal-oxide nanoparticles and soot simultaneously exist, was insufficient. Niu et al.[44] and Huang et al.[45] developed a generalized sourced multiflux method (GSMFM) to simulate outgoing radiation intensities in arbitrary directions for describing the direct problem and used hybrid algorithms to reconstruct 3D temperature distribution and radiative properties in Al2O3 nanoparticle-filled ethylene diffusion flame. However, the retrieved estimations were the corresponding average values in the discrete element of the participating media, and the characteristic parameters for soot and metal-oxide nanoparticles were not distinguished reasonably. In order to further study nanofluid fuel flame, the characteristic parameters fields of metal-oxide nanoparticles and soot required to be respectively constructed.

In the present study, we develop a method for the simultaneous reconstruction of temperature and volume fraction fields of soot and metal-oxide nanoparticles in an axisymmetric nanofluid fuel sooting flame based on the radiative energy images captured by a single CCD camera. The CCD camera can instantaneously capture the images of the entire flame surface from which the radiative intensities can be obtained to overcome the difficulties in measuring the transient spectra of the entire flame by the spectrometer.

The contents of the paper are organized in the following way. The details of direct and inverse problems are described in Section 2. The direct problem for solving the radiation intensities was calculated directly using the line-of-sight discrete equation of the ray-tracing from ring to ring based on the assumed temperature, soot volume fraction, and metal-oxide volume fraction, while the inverse problem was formulated as a linear optimization problem which was solved by the LSQR method. In Section 3, the assumed temperature, volume fraction fields of soot and metal-oxide nanoparticles were provided for validating the method presented in Section 2. Some results and discussion of the effects of ray number and measurement errors on reconstruction accuracy are given. Finally, the conclusions are presented in Section 4.

2. Analysis
2.1. Direct problem

The direct problem here was to calculate the exit line-of-sight radiation intensity emission based on the known temperature, soot volume fraction, and metal-oxide nanoparticle volume fraction fields in an axisymmetric nanofluid fuel sooting flame.

The considered system based on line-of-sight method is depicted in Fig. 1, which is similar to the system in Refs. [46] and [47]. The horizontal cross-section of the flame at a given height was divided into M rings with equal spacing, and the outer radius of each ring was represented by r. A CCD camera was used to capture flame cross-section image and the camera central wavelengths of the red channel ( ) and green channel ( ) were considered. The distance of the camera to the flame center was Le and the camera field angle was . The image pixel intensities were processed to obtain monochromatic radiation intensity emissions of the flame. N was assumed to be the number of the discrete radiation emission lines (ray number) received by the camera within the field angle.

Fig. 1. (color online) Schematic of line-of-sight radiation intensities received by a CCD camera at a cross-section of a nanofluid fuel sooting flame.

The nanofluid fuel flame was assumed to be optically thin and the sizes of soot and metal-oxide nanoparticles in the flame were considered to be small in the Rayleigh scattering range. Therefore, the effects of flame species internal self-absorption and scattering can be negligible. The temperature fields of soot and metal-oxide nanoparticles here were considered to be equal and the particle system was independent scattering. Therefore, the following equation can be applied to the radiation intensity emission along ray j from the flame to the CCD camera,

where is the monochromatic radiation emission intensity of flame into the spectrometer along the ray j, is the local monochromatic absorption coefficient, is the local monochromatic radiation intensity of blackbody, is the local monochromatic absorption coefficient in the ith ring, is the local monochromatic radiation intensity of a blackbody in the ith ring, is the crossing length of the ray jin the ith ring, M is the total number of rings, and is the local monochromatic emission source in the ith ring, which is equal to multiplied by .

According to Wienʼs law

where is the temperature in the ith ring, and c1 and c2 are the first and second radiation constants.

The local monochromatic absorption coefficient for a cloud of small particles in the independent scattering system can be calculated by the algebraic sum of the monochromatic absorption coefficient of every single particle in the corresponding ring[48]

where U is the total number of particles in the ith ring, is the number of particles per unit volume, is the absorption cross-section, Dw is the diameter of the wth single particle, is the volume fraction of the wth particle and , where is the absorption factor of the wth single particle, which is given by the Rayleigh approximation as follows:
where and are the real and imaginary parts of the wavelength-dependent particle complex refraction index. The complex refraction indexes of metal-oxide nanoparticles and soot in this study were chosen from Refs. [49] and [50], respectively.

Substituting Eq. (4) into Eq. (3), can be described as

where the subscript NPs refer to the metal-oxide nanoparticles.

Equation (1) can be discrete and expressed as

Then, equation (6) can be transformed into a matrix form as
where is the vector of monochromatic radiation intensities of the flame ( ), is the matrix of the crossing length in each ring for each ray ( ), and is the vector of local monochromatic emission source ( ).

The monochromatic emission source can be obtained from Eqs. (2) and (5) with the known temperature, volume fraction distributions of soot, and metal-oxide nanoparticles. Then, equation (7) was used to calculate radiation intensity .

2.2. Inverse problem

For the inverse problem, the temperature, volume fraction fields of soot, and metal-oxide nanoparticles were assumed to be unknown. These parameters can be estimated by the exit line-of-sight radiation intensity vector measured by a single CCD camera using the inverse method.

Here, the LSQR algorithm was introduced for solving Eq. (7) to obtain the value of from the measured radiation intensity vector . The details of the LSQR method are available in Refs. [5153] and the method was successfully used to solve the inverse problem in Refs. [30,32,33,36,38], and [39]. Another parameter Rt was introduced to represent the volume fraction ratio of metal-oxide nanoparticles to soot, i.e., . The volume fraction of particles in any particular (organic or inorganic) system can be determined by thermophoretic sampling particle diagnostic (TSPD) technique via measuring the particle mass deposited on an electron microscope grid during a certain sampling time.[54] When using the TSPD method, copper grids for the transmission electron microscope (TEM) measurements were treated as the sampling probes in the nanofluid fuel flame, and a very short sampling time was chosen to prevent overlapping of the particle aggregates. The local soot and metal-oxide nanoparticles volume fractions in flame were respectively expressed as[55,56]

where Rx is the vertical position on the sampling probe, is the soot total volume deposited in a TEM image, is the total volume of metal-oxide nanoparticles deposited in a TEM image, is the particle thermophoretic diffusivity, is the local Nusselt number for heat transfer, Ai is the total area of the TEM image, is the sampling time, and and are the thermophoretic probe wall temperature and gas temperature, respectively.

According to Eqs. (8) and (9), the volume fraction ratio of metal-oxide nanoparticles to soot was simplified to

where and were given by TEM analysis followed by the image processing technique. Therefore, from Eq. (10), Rt can be obtained without needing to know the gas temperature at the corresponding location in the flame.

After at two wavelengths was retrieved and Rt was measured, the local temperature, soot volume fraction, and metal-oxide nanoparticle volume fraction can be finally calculated by

The inverse procedure for retrieving temperature and volume fraction distributions of soot and metal-oxide nanoparticles using a single CCD camera can be summarized as follows.

Step 1 According to the geometrical relationships between rings and rays, the crossing length matrix was calculated.

Step 2 Based on the calculated matrix and the measured radiation intensity vectors and by the CCD camera, local monochromatic emission sources and in Eq. (7) at two wavelengths can be respectively solved via the LSQR method.

Step 3 Obtain the volume fraction ratio vector Rt by the TSPD technique.

Step 4 Compute the unknown temperature and volume fraction distributions of soot and metal-oxide nanoparticles according to the formulations described in Eqs. (11)–(13).

3. Results and discussion

The radiation intensities vectors received by the CCD camera were simulated by adding random errors of normal distribution with zero average value and mean square deviation to the exact intensities obtained from the direct problem. Meanwhile, the measured volume fraction ratio vector Rt obtained from the TSPD techniques were simulated by adding random errors of normal distribution with zero average value and mean square deviation to the exact volume fraction ratio vector.

where and are the measured radiation intensity vector with error and the exact radiation intensity vector. and are the measured volume fraction ratio vector with error and the exact volume fraction ratio vector. The signal-to-noise ratio (SNR) is defined in terms of the logarithmic decibel scale.[31] SNR of and are described, respectively, as
where SNR1 and SNR2 are the measured SNR of radiation intensity and volume fraction ratio.

To demonstrate the validity and robustness of the reconstruction method, the distributions of temperature and soot volume fraction based on the laminar ethylene diffusion flame at 30 mm in Ref. [20] and the metal-oxide nanoparticles volume fraction distribution estimated from the diffusion flame of ethanol-based fuel with the addition of Al2O3 nanoparticles at 0.05 wt% concentration were adopted in the following simulation research. The flame radius at the given height was set as 3 mm and the horizontal cross-section was evenly divided into 30 rings with equal spacing of 0.1 mm. Figure 2 shows the exact temperature, volume fraction profiles of soot and metal-oxide nanoparticles. The field angle of the CCD camera was assumed to be 80° and the distance of the CCD to the flame center Le was calculated to be 4.7 mm.

Fig. 2. (color online) Exact temperature, Al2O3 nanoparticles volume fraction, and soot volume fraction fields.

The relative errors for temperature ( ), soot volume fraction ( ), and Al2O3 volume fraction ( ) reconstruction in each ring are defined as

where and represent the reconstructed and exact temperature, and represent the reconstructed and exact soot volume fraction, and represent the reconstructed and exact Al2O3 nanoparticles volume fraction, respectively.

In the following three cases, the effects of ray number, measurement errors of radiation intensity and volume fraction ratio Rt on the accuracies of reconstructed results were investigated. First, it was assumed that only had measurement error in case 1. Then, only Rt had measurement errors in case 2. Finally, both and Rt have measurement errors simultaneously in case 3.

3.1. Case 1

In this case, the effects of ray number and measurement errors for radiation intensity on the reconstruction accuracy and stability were examined.

3.1.1. Effects of ray number on reconstruction accuracy

The monochromatic radiation intensity emission profiles of the flame at the red channel (700 nm) and green channel (530 nm) using four ray numbers N (30, 60, 90, and 120) are presented in Fig. 3. Here, these different ray numbers N and three different (65 dB, 60 dB, 46 dB) were studied and compared, as shown in Fig. 4. It can be found that with the increase in ray number from 30 to 90, the average and maximum relative errors of temperature, soot volume fraction, and Al2O3 volume fraction distributions reconstruction decreased significantly under certain fixed measurement errors. However, from ray number 90 to 120, these relative errors did not decrease obviously, and the computing time increased. Therefore, ray number 90 was chosen as the best reconstructed result, which was the trade-off between the reconstruction accuracy and computing time. With N = 90 and SNR1 = 46 dB, the average relative errors of temperature and volume fraction distributions reconstruction of soot and Al2O3 are 0.12%, 1.19%, and 1.19%, respectively. The respective maximum relative errors for these parameters are 0.51%, 5.15%, and 5.15%. The SNR of the CCD camera used in the experiments is usually higher than 65 dB, which means that better reconstructed results could be expected. Moreover, the reconstructed results of temperature and volume fraction distributions with SNR1 = 46 dB are displayed in Fig. 5. In general, the reconstructed fields agreed well with the exact values, especially at the locations with high temperature range from 1738 K to 1886 K. However, the reconstructed results at locations with low temperatures were easily influenced by measurement errors, because less radiative information from these locations could be received by the CCD camera.

Fig. 3. (color online) Monochromatic radiation intensity emission profiles of the flame at the red channel (700 nm) and the green channel (530 nm) using ray number ((a) 30, (b) 60, (c) 90, and (d) 120).
Fig. 4. (color online) Effects of ray numbers (N) and measurement errors for radiation intensity (SNR1) on the reconstruction accuracy. (a) No error added, (b) SNR1 = 65 dB, (c) SNR1 = 60 dB, (d) SNR1 = 46 dB.
Fig. 5. (color online) (a) Local temperature and volume fraction distributions reconstruction of (b) soot and (c) Al2O3 nanoparticles using ray number 90 on the condition of measurement error for radiation intensity (SNR1) of 46 dB. For the sake of comparison, the exact value and relative error are also included.
3.1.2. Effect of measurement error on stability of the reconstruction method

Here, ray number 90 was used and four different SNR1 were assumed. Owing to the random errors adding to the exact solution of the direct problem, the stability of the reconstruction method was tested through 20 samples, as shown in Fig. 6. The average and maximum relative errors of volume fraction distribution reconstruction of Al2O3 stayed exactly the same as those of soot. The maximum of the maximum relative errors of the temperature distribution reconstruction for 20 samples were below 0.88%, even with SNR1 as low as 46 dB. Therefore, the reconstruction results of the temperature field were satisfying under these measurement errors. When SNR1 was 60 dB, the maximum of the maximum relative errors of volume fraction distribution reconstruction for 20 samples was below 1.79%. However, as SNR1 further decreased to 46 dB, the maximum of the maximum relative errors of volume fraction distribution reconstruction for 20 samples increased to 14.24%, which meant that the reconstruction failed. If the temperature and volume fraction fields of soot and Al2O3 nanoparticles were desired to be reconstructed accurately, the SNR of the CCD camera should be limited within an appropriate range.

Fig. 6. (color online) Effects of measurement errors for radiation intensity (SNR1) on the reconstruction accuracy with 20 samples. (a) SNR1 = 80 dB, (b) SNR1 = 65 dB, (c) SNR1 = 60 dB, (d) SNR1 = 46 dB.
3.2. Case 2

In this case, the effects of measurement errors for the volume fraction ratio Rt on the reconstruction accuracy were examined. Four SNR2 (65 dB, 60 dB, 46 dB, and 39 dB) were tested. Owing to the random errors adding to the exact volume fraction ratio Rt, all the reconstruction results were the average results of 20 samples.

The average of the local relative errors of temperature, soot volume fraction, and Al2O3 volume fraction reconstruction of 20 samples are shown in Fig. 7.

Fig. 7. (color online) Effects of measurement errors for volume fraction ratio Rt (SNR2) on the reconstruction accuracy. (a) SNR2 = 65 dB, (b) SNR2 = 60 dB, (c) SNR2 = 46 dB, (d) SNR2 = 39 dB.

From Fig. 7, the local relative error of the temperature reconstruction maintained the lowest level, whereas that of the Al2O3 volume fraction reconstruction maintained the highest level. The Al2O3 volume fraction was calculated using the soot volume fraction multiplied by the measured volume fraction ratio. Therefore, when the volume fraction ratio had the measurement error, the reconstruction error of the Al2O3 volume fraction was larger than that of soot volume fraction. However, when the measurement of volume fraction ratio had no error, the relative reconstruction errors of Al2O3 nanoparticles volume fraction and soot volume fraction were the same. This implied that compared with the other reconstruction, the Al2O3 volume fraction distribution reconstruction was more susceptible to the measurement error of the volume fraction ratio Rt. When SNR2 = 39 dB, the maximum of local relative errors of Al2O3 volume fraction reconstruction was no more than 1.2% at the location with a flame radius of 2.1 mm. Therefore, the parameter distributions of the temperature and volume fractions can be accurately retrieved even when SNR2 was as low as 39 dB, which decreased the requirement of the high measurement accuracy of the volume fraction ratio Rt by the TSPD technique.

3.3. Case 3

In this case, the measurement errors in the simultaneous presence of radiation intensity and volume fraction ratio Rt on the reconstruction accuracy are displayed in Fig. 8. All the reconstructed relative errors were the average results of 20 samples.

Fig. 8. (color online) Effects of measurement errors for radiation intensity (SNR1) and volume fraction ratio Rt (SNR2) on the reconstruction accuracy. (a) Temperature distribution reconstruction, (b) soot volume fraction distribution reconstruction, (c) Al2O3 volume fraction distribution reconstruction.

In comparison to the measurement error for the volume fraction ratio Rt, the reconstructed results were more easily influenced by that for the radiation intensity . As SNR2 decreased from 80 dB to 46 dB under SNR1 = 46 dB, the average relative errors of temperature and volume fraction distributions reconstruction of soot and Al2O3 increased by factors of 0.09, 0.2, and 0.24, respectively. While SNR1 decreased from 80 dB to 46 dB under SNR2 = 46 dB, the respective average relative errors for these parameters increased by factors of 19, 53.67, and 3.36.

The reconstruction accuracies of the temperature and soot volume fraction distributions were not sensitive to the measurement error for the volume fraction ratio Rt and the variations in the average reconstructed relative errors for these parameters were almost unobservable with the decrease in SNR2.

When SNR1 = 46 dB and SNR2 = 39 dB, the average relative error of the temperature distribution reconstruction was only 0.12%, and that of the volume fraction distribution reconstruction of soot and Al2O3 were only approximately 1.45% and 1.72%, respectively. Therefore, the reconstruction method developed in this study was effective and robust, and could reasonably retrieve the temperature and volume fraction fields of soot and metal-oxide nanoparticles in an axisymmetric nanofluid fuel sooting flame.

4. Conclusions

An efficient numerical inverse radiation analysis was proposed to reconstruct the temperature and volume fraction fields of soot and metal-oxide nanoparticles in an axisymmetric nanofluid fuel sooting flame using a single CCD camera. Numerical simulations were used and the reconstructed results were acceptable, even in the presence of simultaneous measurement errors of SNR1 of radiation intensity as low as 46 dB and SNR2 of volume fraction ratio Rt as low as 39 dB. The numeral analyses show that the method was capable and robust to concurrently retrieve the temperature and volume fraction fields of soot and metal-oxide nanoparticles in the nanofluid fuel flame for both exact and noisy data.

Reference
[1] Basu S Miglani A 2016 Int. J. Heat Mass Transf. 96 482
[2] Choi S U S 2009 J. Heat Transfer 131 033106
[3] Jones M Li C H Afjeh A Peterson G 2011 Nanoscale Res. Lett. 6 246
[4] Wen D S 2010 Energy Environ. Sci. 3 591
[5] Javed I Baek S W Waheed K 2015 Combust. Flame 162 191
[6] Javed I Baek S W Waheed K 2015 Combust. Flame 162 774
[7] Sabourin J L Dabbs D M Yetter R A Dryer F L Aksay I A 2009 Acs Nano 3 3945
[8] Huang X F Li S J 2016 Fuel 177 113
[9] Selvan V A M Anand R B Udayakumar M 2014 Fuel 130 160
[10] Sarvestany N S Farzad A Bajestan E E Mir M 2014 J. Dispers. Sci. Technol. 35 1745
[11] Xuan Y M Li Q Hu W 2003 AICHE J. 49 1038
[12] Xuan Y M Li Q 2003 J. Heat Transf. 125 151
[13] Xuan Y M Li Q 2000 Int. J. Heat Fluid Flow 21 58
[14] Xing J J Wu Z H Xie H Q Wang Y Y Li Y H Mao J H 2017 Chin. Phys. 26 104401
[15] Zhou X F Gao L 2007 Chin. Phys. 16 2028
[16] Hayat T Imtiaz M Alsaedi A Mansoor R 2014 Chin. Phys. 23 054701
[17] Gan Y N Qiao L 2011 Combust. Flame 158 354
[18] Gan Y N Lim Y S Qiao L 2012 Combust. Flame 159 1732
[19] Tanvir S Qiao L 2016 Combust. Flame 166 34
[20] Liu G N Liu D 2017 Sci. China Technol. Sci. 60 1075
[21] Zhou H C Han S D Sheng F Zheng C G 2002 J. Quant. Spectrosc. Radiat Transf. 72 361
[22] Snelling D R Thomson K A Smallwood G J Gülder O L Weckman E J Fraser R A 2002 AIAA J. 40 1789
[23] Brisley P M Lu G Yan Y Cornwell S 2005 IEEE Trans. Instrum. Meas. 54 1417
[24] Lou C Zhou H C 2005 Combust. Flame 143 97
[25] Lu G Yan Y Cornwell S Riley G 2006 Proc. IEEE 55 1658
[26] Lou C Zhou H C Yu P F Jiang Z W 2007 Proc. Combust. Inst. 31 2771
[27] Wang F Liu D Cen K F Yan J H Huang Q X Chi Y 2008 J. Quant. Spectrosc. Radiat. Transf. 109 2171
[28] Liu D Wang F Huang Q X Yan J H Chi Y Cen K F 2008 Chin. Phys. 17 1312
[29] Liu D Wang F Huang Q X Yan J H Chi Y Cen K F 2008 Acta Phys. Sin. 57 4812 in Chinese
[30] Liu D Wang F Cen K F Yan J H Huang Q X Chi Y 2008 Opt. Lett. 33 422
[31] Huang Q X Wang F Liu D Ma Z Y Yan J H Chi Y Cen C F 2009 Combust. Flame 156 565
[32] Liu D Yan J H Wang F Huang Q X Chi Y Cen K F 2010 Int. J. Heat. Mass Transf. 53 4474
[33] Liu D Huang Q X Wang F Chi Y Cen K F Yan J H 2010 J. Heat Transfer 132 061202
[34] Yan J H Wang F Huang Q X Chi Y Cen K F Liu D 2011 Acta Phys. Sin. 60 060701 in Chinese
[35] Liu D Yan J H Cen K F 2011 Int. J. Heat Mass Transf. 54 1684
[36] Liu D Yan J H Cen K F 2012 Int. J. Heat Mass Transf. 55 1553
[37] Liu D Yan J H Wang F Huang Q X Chi Y Cen K F 2012 Fuel 93 397
[38] Niu C Y Qi H Huang X Ruan L M Wang W Tan H P 2015 Chin. Phys. 24 114401
[39] Niu C Y Qi H Lew Z Y Ruan L M Tan H P 2015 3nd International Workshop on Heat Transfer Advances for Energy Conservation and Pollution Control October 16–19 Taipei, Taiwan, China
[40] Ni M J Zhang H D Wang F Xie Z C Huang Q X Yan J H Cen K F 2016 Appl. Therm. Eng. 96 421
[41] Sun J Xu C L Zhang B Wang S M Hossain M M Qi H Tan H P 2016 Instrum. Meas. Technol. Conf. Proc. 23 1 1�?
[42] Liu D 2016 Therm. Sci. 20 493
[43] Xu C L Zhao W C Hu J H Zhang B Wang S M 2017 Fuel 196 550
[44] Niu C Y Qi H Huang X Ruan L M Tan H P 2016 J. Quant. Spectrosc. Radiat. Transf. 184 44
[45] Huang X Qi H Niu C Y Ruan L M Tan H P Sun J Xu C L 2017 Appl. Therm. Eng. 115 1337
[46] Zhou H C Luo C Lu J 2008 The 6th International Symposium on Measurement Techniques for Multiphase Flows December 15–17, 2008 Okinawa, Japan 012086 10.1088/1742-6596/147/1/012086
[47] Yan W J Zheng S Zhou H C 2017 Appl. Therm. Eng. 124 1014
[48] Modest M F 2003 Radiative Heat Transfer 2 America Academic Press 361 412
[49] Querry M R 1985 Optical Constants 12
[50] Chang H Charalampopoulos T T 1990 Proc. R. Soc. 430 577
[51] Lanczons C 1950 J. Res. Natl. Bur. Stand 45 255
[52] Paige C C Saunders M A 1982 AMC Trans. Math. Softw. 8 43
[53] Paige C C Saunders M A 1982 AMC Trans. Math. Softw. 8 195
[54] Köylü Ü Ö McEnally C S Rosner D E Pfefferle L D 1997 Combust. Flame 110 494
[55] Xu Z W Zhao H B Chen X B Lou C 2017 Combust. Flame 180 158
[56] Xu Z W Zhao H B 2015 Combust. Flame 162 2200