References
- [1] Kumar, A., Mohanta, K., Kumar, D., Parkash, O. (2012). Properties and industrial applications of rice husk: A review. International Journal of Emerging Technology and Advanced Engineering, 2 (10), 86-90.
- [2] Rao, P.P., Kumar, A.P., Singh, B.B. (2014). A study on use of rice husk ash in concrete. International Journal of Education and Applied Research, 4 (2), 75-81.
- [3] Akeke, G.A., Ephraim, M.E., Akobo, I.Z.S., Ukpata, J.O. (2013). Structural properties of rice husk ash concrete. International Journal of Engineering and Applied Sciences, 3 (3), 57-62.
- [4] Dabai, M.U., Muhammad, C., Bagudo, B.U., Musa, A. (2009). Studies on the effect of rice husk ash as cement admixture. Nigerian Journal of Basic and Applied Science, 17 (2), 252-256.
- [5] Habeeb, G.A., Mahmud, H.B. (2010). Study on properties of rice husk ash and its use as cement replacement material. Materials Research, 13 (2), 185-190.
- [6] Kartini, K. (2011). Rice husk ash - pozzolanic material for sustainability. International Journal of Applied Science and Technology, 1 (6), 169-178.
- [7] Kusbiantoro, A., Nuruddin, M.F., Shafiq, N., Qazi, S.A. (2012). The effect of microwave incinerated rice husk ash on the compressive and bond strength of fly ash based geopolymer concrete. Construction and Building Materials, 36, 695-703.
- [8] Bui, L.A.T., Chen, C.T., Hwang, C.L., Wu, W.S. (2012). Effect of silica forms in rice husk as on the properties of concrete. International Journal of Minerals, Metallurgy and Materials, 19 (3), 252-258.
- [9] Karim, M.R., Zain, M.F.M., Jamil, M., Lai, F.C., Islam, M.N. (2012). Strength of mortar and concrete as influenced by rice husk ash: A review. Word Applied Sciences Journal, 19 (10), 1501-1513.
- [10] Krishna, R.N. (2012). Rice husk ash - an ideal admixture for concrete in aggressive environments. In 37th Conference on Our World in Concrete & Structures, 29-31 August 2012, Singapore.
- [11] Jamil, M., Hassan, M.K., Al-Mattarneh, H.M.A., Zain, M.F.M. (2013). Concrete dielectric properties investigation using microwave nondestructive techniques. Material and Structures, 46, 77-87.
- [12] You, K.Y., Abbas, Z., Malek, M.F.A., Cheng, E.M. (2014). Non-destructive dielectric measurements and calibration for thin materials using waveguide-coaxial adaptors. Measurement Science Review, 14 (1), 16-24.
- [13] Roj, J., Cichy, A. (2015). Method of measurement of capacitance and dielectric loss factor using artificial neural networks. Measurement Science Review, 15 (3), 127-131.
- [14] Industrial Applications and Chemistry Section. (2002). Guidebook on Non-destructive Testing of Concrete Structures. Vienna, Austria: International Atomic Energy Agency.
- [15] Cheng , E.M., Fareq, M., Shahriman, A.B., Afendi, M., Zulkarnay, Z., Khor, S.F., Liyana, Z., Nashrul, F. M.N., Tan, W.H., Noorpi, N.S.M., Mukhtar, N.M., Othman, M. (2014). Development of low cost microwave detection system for salinity and sugar detection. International Journal of Mechanical & Mechatronics Engineering, 14 (5), 59-71.
- [16] Vrba, J. (2013). Coaxial reflection probe for measurements of temperature and frequency dependent dielectric-properties of low-loss liquids. In Progress in Electromagnetics Research Symposium Proceedings, 12-15 August 2013, Stockholm, Sweden. PIERS, 1091-1094.
- [17] Guo, W.C., Nelson, S.O., Trabelsi, S., Kays, S.J. (2007). 10-1800-MHz dielectric properties of fresh apples during storage. Journal of Food Engineering, 83 (4), 562-569.
- [18] Brinley, T.A., Truong, V.D., Coronel, P., Simunovic, J., Sandeep, K.P. (2008). Dielectric properties of sweet potato purees at 915 MHz as affected by temperature and chemical composition. International Journal of Food Properties, 11 (1), 158-172.
- [19] Yeow, Y.K., Abbas, Z., Khalid, K. (2010). Application of microwave moisture sensor for determination of oil palm fruit ripeness. Measurement Science Review, 10 (1), 7-14.
- [20] Faktorová, D. (2007). Complex permittivity of biological materials measurement at microwave frequencies. Measurement Science Review, 7 (2-2), 12-15.
- [21] Angkawisittpan, N., Manasri, T. (2012). Determination of sugar content in sugar solutions using interditital capacitor sensor. Measurement Science Review, 12 (1), 8-13.
- [22] Harnsoongnoen, S., Siritaratiwat, A. (2015). Electrical and absorption properties of fresh cassava tubers and cassava starch. Journal of Instrumentation, 10, 1-12.
- [23] Zhong, Y.H., Zhang, B., Shi, W.B., Wang, T. (2012). Experimental research on relationships between dielectric constant of cement concrete materials and measuring frequency. In 14th International Conference on Ground Penetrating Radar, 4-8 June 2012, Shanghai, China, 403-406.
- [24] Filali, B., Boone, F., Rhazi, J., Ballivy, G. (2008). Design and calibration of a large open-ended coaxial probe for the measurement of the dielectric properties of concrete. IEEE Transactions and Microwave Theory and Techniques, 56 (10), 2322-2328.
- [25] Kwon, S.J., Feng, M.Q., Park, T.W., Na, U.J. (2009). An experimental study on evaluation of compressive strength in cement mortar using averaged electromagnetic properties. International Journal of Concrete Structures and Materials, 3 (1), 25-32.
- [26] Chen, L.F., Ong, C.K., Neo, C.P., Varadan, V.V., Varadan, V.K. (2004). Microwave Electronics: Measurement and Materials Characterization. John Wiley and Sons, 288-290.
- [27] Komarov, V., Wang, S., Tang, J. (2005). Permittivity and measurement. In Encyclopedia of RF and Microwave Engineering. John Wiley & Sons, 3693-3711.
- [28] Agilent Technologies. (2006). Basics of measuring the dielectric properties of materials: Application note. http://www3.imperial.ac.uk.
- [29] Kang, B., Park, J.H., Cho, J., Kwon, K., Lim, S., Yoon, J., Cheon, C., Kim, Y.K., Kwon, Y. (2005). Novel low-cost planar probes with broadside apertures for nondestructive dielectric measurement of biological materials at microwave frequencies. IEEE Transaction on Microwave Theory and Techniques, 53 (1), 134-143.
- [30] Nyshadham, A., Sibbald, C.L., Stuchly, S.S. (1992). Permittivity measurements using open-ended sensors and reference liquid calibration - an uncertainty analysis. IEEE Transections on Microwave Theory and Techniques, 40 (2), 305-314.
- [31] Blackham, D.V., Pollard, R.D. (1997). An improved technique for permittivity measurements using a coaxial probe. IEEE Transaction on Instrumentation and Measurement, 46 (5), 1093-1099.
- [32] Kang, B., Cho, J., Cheon, C., Kwon, Y. (2004). A planar-type probe with a coaxial aperture for nondestructive complex permittivity measurement of biological materials up to 30 GHz. In IEEE MTT-S International Microwave Symposium Digest, 6-11 June 2004. IEEE, Vol. 3, 1441-1444.
- [33] Buff, P.M., Steer, M.B., Lazzi, G. (2006). Cole-Cole dispersion models for aqueous gelatin-syrup dielectric composites. IEEE Transactions on Geoscience and Remote Sensing, 44 (2), 351-355.
- [34] Buckley, F., Maryott, A.A. (1958). Tables of Dielectric Dispersion Data for Pure Liquids and Dilute Solutions. National Bureau of Standards Circular 589, United States Department of Commerce.