İbrahim Türkmen
- Enhancing acid resistance of geopolymer concrete composites by utilising styrene-butadiene latex, nano-silica and micro-silica powder. In: European Journal of Environmental and Civil Engineering, v. 27, n. 15 (March 2023). (2023):
- Several properties of mineral admixtured lightweight mortars at elevated temperatures. In: Fire and Materials, v. 37, n. 5 (March 2012). (2012):
- Fire resistance of geopolymer concrete produced from Elazığ ferrochrome slag. In: Fire and Materials, v. 40, n. 6 (January 2016). (2016):
- Relationship between ultrasonic velocity and compressive strength for high-volume mineral-admixtured concrete. In: Cement and Concrete Research, v. 34, n. 12 (December 2004). (2004):
- Mechanical and durability characteristics of GGBS-based self-healing geopolymer mortar produced using by an endospore-forming bacterium. In: Journal of Building Engineering, v. 57 (October 2022). (2022):
- Improving elevated temperature performance of geopolymer concrete utilizing nano-silica, micro-silica and styrene-butadiene latex. In: Construction and Building Materials, v. 286 (June 2021). (2021):
- Performance of self-healing geopolymer paste produced using Bacillus subtilis. In: Construction and Building Materials, v. 325 (March 2022). (2022):
- Influence of various factors on properties of geopolymer paste: A comparative study. In: Structural Concrete, v. 22 (January 2021). (2021):
- Prediction of compressive strength and ultrasonic pulse velocity of admixtured concrete using tree model M5P. In: Structural Concrete, v. 22 (January 2021). (2021):
- A Taguchi approach for investigation of some physical properties of concrete produced from mineral admixtures. In: Building and Environment, v. 43, n. 6 (June 2008). (2008):
- Effects of expanded perlite aggregate and different curing conditions on the physical and mechanical properties of self-compacting concrete. In: Building and Environment, v. 42, n. 6 (June 2007). (2007):
- Thermo-mechanical properties of concrete containing high-volume mineral admixtures. In: Building and Environment, v. 42, n. 1 (January 2007). (2007):
- Optimization of production parameters of geopolymer mortar and concrete: A comprehensive experimental study. In: Construction and Building Materials, v. 228 (December 2019). (2019):
- The effects of different cement dosages, slumps and pumice aggregate ratios on the freezing and thawing of concrete. In: Computers and Concrete, v. 3, n. 2-3 (April 2006). (2006):
- The improvement of mechanical, physical and durability characteristics of volcanic tuff based geopolymer concrete by using nano silica, micro silica and Styrene-Butadiene Latex additives at different ratios. In: Construction and Building Materials, v. 201 (March 2019). (2019):
- Mechanical properties and setting time of ferrochrome slag based geopolymer paste and mortar. In: Construction and Building Materials, v. 72 (December 2014). (2014):
- Modeling with ANN and effect of pumice aggregate and air entrainment on the freeze–thaw durabilities of HSC. In: Construction and Building Materials, v. 25, n. 11 (November 2011). (2011):