[1] F.Soltanzadeh, J.A.O.Barros, R.F.C.Santos, High performance fiber reinforced concrete for the shear reinforcement: Experimental and numerical research, Construction and Building Materials, Volume 77, 15 February 2015, Pages 94-109
[2] Jordi Massana, Encarnación Reyes, Jesús Bernal, Néstor León, Elvira Sánchez-Espinosa, Influence of nano- and micro-silica additions on the durability of a high-performance self-compacting concrete, Construction and Building Materials, Volume 165, 20 March 2018, Pages 93-103
[3] Aloys Dushimimana, Aude Amandine Niyonsenga, Frederic Nzamurambaho, A review on strength development of high performance concrete, Construction and Building Materials, Volume 307, 8 November 2021, 124865
[4] Bengi Arisoy, Hwai-Chung Wu, Material characteristics of high performance lightweight concrete reinforced with PVA, Construction and Building Materials, Volume 22, Issue 4, April 2008, Pages 635-645
[5] O. Kayali, Fly ash lightweight aggregates in high performance concrete, Construction and Building Materials, Volume 22, Issue 12, December 2008, Pages 2393-2399
[6] Manu S.Nadesan, P.Dinakar, Influence of type of binder on high-performance sintered fly ash lightweight aggregate concrete, Construction and Building Materials, Volume 176, 10 July 2018, Pages 665-675
[7] Abdulaziz Alaskar, Mohammad Alshannag, Mahmoud Higazey, Mechanical properties and durability of high-performance concrete internally cured using lightweight aggregates, Construction and Building Materials, Volume 288, 21 June 2021, 122998
[8] Jian-Xin Lu, Peiliang Shen, Hafiz Asad Ali, Chi Sun Poon, Development of high performance lightweight concrete using ultra high performance cementitious composite and different lightweight aggregates, Cement and Concrete Composites, Volume 124, November 2021, 104277
[9] Kok Seng Chia, Min-Hong Zhang, Water permeability and chloride penetrability of high-strength lightweight aggregate concrete, Cement and Concrete Research, Volume 32, Issue 4, April 2002, Pages 639-645
[10] Xuemei Liu, Kok Seng Chia, Min-Hong Zhang, Water absorption, permeability, and resistance to chloride-ion penetration of lightweight aggregate concrete, Construction and Building Materials, Volume 25, Issue 1, January 2011, Pages 335-343
[11] Xuemei Liu, Kok Seng Chia, Min-Hong Zhang, Development of lightweight concrete with high resistance to water and chloride-ion penetration, Cement and Concrete Composites, Volume 32, Issue 10, November 2010, Pages 757-766
[12] V. Ducman, B. Mirtič, Water vapour permeability of lightweight concrete prepared with different types of lightweight aggregates, Construction and Building Materials, Volume 68, 15 October 2014, Pages 314-319
[13] Mehmet Gesoğlu, Erhan Güneyisi, Turan Özturan, Hatice Öznur Öz, Diler Sabah Asaad, Permeation characteristics of self compacting concrete made with partially substitution of natural aggregates with rounded lightweight aggregates, Construction and Building Materials, Volume 59, 30 May 2014, Pages 1-9
[14] Erhan Güneyisi, Mehmet Gesoğlu, Emad Booya, Kasım Mermerdaş, Strength and permeability properties of self-compacting concrete with cold bonded fly ash lightweight aggregate, Construction and Building Materials, Volume 74, 15 January 2015, Pages 17-24
[15] Jiří Pazderka, Eva Hájková, crystalline admixtures and their effect on selected properties of concrete, Acta Polytechnica 56(4):306–311, 2016
[16] Pejman Azarsa, Rishi Gupta, Alireza Biparva, Crystalline Waterproofing Admixtures Effects on Self-healing and Permeability of Concrete, 1st International Conference on New Horizons in Green Civil Engineering (NHICE-01), Victoria, BC, Canada, April 25 – 27, 2018
[17] Pejman Azarsa, Rishi Gupta, Alireza Biparva, Inventive Microstructural and Durability Investigation of Cementitious Composites Involving Crystalline Waterproofing Admixtures and Portland Limestone Cement, Materials 2020, 13, 1425; doi:10.3390/ma13061425
[18] Ozkan Sengul, Senem Azizi, Filiz Karaosmanoglu, Mehmet Ali Tasdemir, Effect of expanded perlite on the mechanical properties and thermal conductivity of lightweight concrete, Energy and Buildings, Volume 43, Issues 2–3, February–March 2011, Pages 671-676
[19] Canan Tasdemir, Ozkan Sengul, Mehmet Ali Tasdemir, A comparative study on the thermal conductivities and mechanical properties of lightweight concretes, Energy and Buildings, Volume 151, 15 September 2017, Pages 469-475
[20] Mactar Faye, Berangere Lartigue, Souleye Kane, Influence of structural and thermophysical parameters of insulating aggregates on the effective thermal conductivity of lightweight concrete, Journal of Building Engineering, Volume 21, January 2019, Pages 74-81
[21] Muhammad Riaz Ahmad, Bing Chen, Experimental research on the performance of lightweight concrete containing foam and expanded clay aggregate, Composites Part B: Engineering, Volume 171, 15 August 2019, Pages 46-60
[22] Muhammad Riaz Ahmad, Bing Chen, Syed Farasat Ali Shah, Investigate the influence of expanded clay aggregate and silica fume on the properties of lightweight concrete, Construction and Building Materials, Volume 220, 30 September 2019, Pages 253-266
[23] O. Gencel, F. Koksal, M. Sahin, M. Y. Durgun, H. E. Hagg Lobland, W. Brostow, modeling of thermal conductivity ofconcrete with vermiculite by using artificial neural networks approaches, Experimental Heat Transfer, 26:360–383, 2013
[24] Adilson Schackow, Carmeane Effting, Marilena V. Folgueras, Saulo Güths, Gabriela A. Mendes, Mechanical and thermal properties of lightweight concretes with vermiculite and EPS using air-entraining agent, Construction and Building Materials, Volume 57, 30 April 2014, Pages 190-197
[25] Mehmet Karatas, Ahmet Benli, Hasan Anil Toprak, Effect of incorporation of raw vermiculite as partial sand replacement on the properties of self-compacting mortars at elevated temperature, Construction and Building Materials, Volume 221, 10 October 2019, Pages 163-176
[26] Abid Ustaoglu, Kubra Kurtoglu, Osman Gencel, Fatih Kocyigit, Impact of a low thermal conductive lightweight concrete in building: Energy and fuel performance evaluation for different climate region, Journal of Environmental Management, Volume 268, 15 August 2020, 110732
[27] Waleed A.Al-Awsh, Omar S. Baghabra Al-Amoudi, Mohammed A.Al-Osta, Aftab Ahmad, Tawfik A.Saleh, Experimental assessment of the thermal and mechanical performance of insulated concrete blocks, Journal of Cleaner Production, Volume 283, 10 February 2021, 124624
[28] ASTM C33, Standard Specification for Concrete Aggregates, 2018
[29] BS EN 12390-3:2002, Testing hardened concrete - Part 3: Compressive strength of test specimens
[30] American Society for Testing and Materials. Standard Test Method for Splitting Tensile Strength of Cylindrical Concrete Specimens, ASTM C496/C496M, Annual Book of ASTM Standard, 2011.
[31] EN12504-4, Testing concrete-Part 4: Determination of pulse velocity, European Committee for Standardization CEN, 2004
[32] AASHTO TP 95, Standard Method of Test for Surface Resistivity Indication of Concrete’s Ability to Resist Chloride Ion Penetration
[33] ASTM C642 – 13, Standard Test Method for Density, Absorption, and Voids in Hardened Concrete
[34] ASTM C518 – 17, Standard Test Method for Steady-State Thermal Transmission Properties by Means of the Heat Flow Meter Apparatus.