- Cement based composites for thin building elements: Fracture and fatigue parameters. In: Procedia Engineering, v. 2, n. 1 (April 2010). (2010):
- Effect of petrographic composition and chemistry of aggregate on the local and general fracture response of cementitious composites. In: Frattura ed Integrità Strutturale, v. 16, n. 60 (25 März 2022). (2022):
- Crack initiation of selected geopolymer mortars with hemp fibers. In: Procedia Structural Integrity, v. 13 ( 2018). (2018):
- Evaluation of fracture response of Silesian granite specimens via Effective Crack Model approach and finite element analysis. In: Procedia Structural Integrity, v. 23 ( 2019). (2019):
- Fracture parameters of alkali-activated aluminosilicate composites with ceramic precursor: durability aspects. In: Procedia Structural Integrity, v. 33 ( 2021). (2021):
- Influence of rock inclusion composition on the fracture response of cement-based composite specimens. In: Procedia Structural Integrity, v. 33 ( 2021). (2021):
- Characterisation of Thermal-loaded Cement-based Composites by Combined Time-lapse Tomography and the Four-point Bending Test. In: Stavební obzor - Civil Engineering Journal, v. 29, n. 1 ( 2020). (2020):
- Performance-based design of concrete structures: durability aspects. In: Structural Engineering and Mechanics, v. 35, n. 4 (Juli 2010). (2010):
- Change of Fatigue and Mechanical Fracture Properties of a Cement Composite due to Partial Replacement of Aggregate by Red Ceramic Waste. In: Periodica Polytechnica Civil Engineering. :
- Engineering properties of composite materials containing waste ceramic dust from advanced hollow brick production as a partial replacement of Portland cement. In: Journal of Building Physics, v. 40, n. 1 (November 2015). (2015):
- Pilot evaluation of a fracture process zone in a modified compact tension specimen by X-ray tomography. In: Frattura ed Integrità Strutturale, v. 11, n. 42 (September 2017). (2017):
- High performance concrete containing lower slag amount: A complex view of mechanical and durability properties. In: Construction and Building Materials, v. 23, n. 6 (Juni 2009). (2009):
- High performance concrete with Czech metakaolin: Experimental analysis of strength, toughness and durability characteristics. In: Construction and Building Materials, v. 24, n. 8 (August 2010). (2010):
- Mechanical, fracture-mechanical, hydric, thermal, and durability properties of lime–metakaolin plasters for renovation of historical buildings. In: Construction and Building Materials, v. 31 (Juni 2012). (2012):
- Carbon nanotube reinforced alkali-activated slag mortars. In: Construction and Building Materials, v. 119 (August 2016). (2016):
- Mechanical, durability and hygrothermal properties of concrete produced using Portland cement-ceramic powder blends. In: Structural Concrete, v. 17, n. 1 (Februar 2016). (2016):
- Stochastic fracture-mechanical parameters for the performance-based design of concrete structures. In: Structural Concrete, v. 15, n. 3 (September 2014). (2014):