P. Łukowski scite author profile

The increasing concern for safety and sustainability of structures is calling for the development of smart self-healing materials and preventive repair methods. The appearance of small cracks (<300 µm in width) in concrete is almost unavoidable, not necessarily causing a risk of collapse for the structure, but surely impairing its functionality, accelerating its degradation, and diminishing its service life and sustainability. This review provides the state-ofthe-art of recent developments of self-healing concrete, covering autogenous or intrinsic healing of traditional concrete followed by stimulated autogenous healing via use of mineral additives, crystalline admixtures or (superabsorbent) polymers, and subsequently autonomous self-healing mechanisms, i.e. via, application of micro-, macro-, or vascular encapsulated polymers, minerals, or bacteria. The (stimulated) autogenous mechanisms are generally limited to healing crack widths of about 100-150 µm. In contrast, most autonomous self-healing mechanisms can heal cracks of 300 µm, even sometimes up to more than 1 mm, and usually act faster. After explaining the basic concept for each self-healing technique, the most recent advances are collected, explaining the progress and current limitations, to provide insights toward the future developments. This review addresses the research needs required to remove hindrances that limit market penetration of self-healing concrete technologies.

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Cement concrete and concrete–polymer composites: Two merging worlds

Gemert

Czarnecki

Maultzsch

et al. 2005

Cement and Concrete Composites

124

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The search for durable and sustainable construction materials inspires the developments in the world of cement concrete, as well as in the world of concrete-polymer composites. Both worlds recognize, strive for and accept each other's contribution to the synergic effects that are realized by the combination of classical building materials and polymers. A better knowledge of materials behaviour, especially in the field of admixtures, and a better understanding of curing processes allowed the development of highly performing mineral or modified mineral concretes, mortars and grouts. CPC-science becomes an invaluable element in the development of sustainable construction materials. ICPIC organises practitioners and scientists, dealing with concrete-polymer composites in all industrial fields, but with emphasis on construction industry. The 11th International ICPIC Congress took place in Berlin, 2-4th June 2004. New trends and evolutions have been presented and discussed. The highlights of the Congress, and the synergies that emerge from the congress for the construction world in combination with cement concrete, will be presented and discussed in the paper.

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The Effect of Nanosilica on the Mechanical Properties of polymer-Cement Composites (PCC)

Sikora

Łukowski

Cendrowski

et al. 2015

Procedia Engineering

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Optimization of polymer concrete composites:

Czarnecki¹,

Garbacz²,

Łukowski³

et al. 1999

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Polymer-Cement Composites Containing Waste Perlite Powder

Łukowski

2016

Materials

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Polymer-cement composites (PCCs) are materials in which the polymer and mineral binder create an interpenetrating network and co-operate, significantly improving the performance of the material. On the other hand, the need for the utilization of waste materials is a demand of sustainable construction. Various mineral powders, such as fly ash or blast-furnace slag, are successfully used for the production of cement and concrete. This paper deals with the use of perlite powder, which is a burdensome waste from the process of thermal expansion of the raw perlite, as a component of PCCs. The results of the testing of the mechanical properties of the composite and some microscopic observations are presented, indicating that there is a possibility to rationally and efficiently utilize waste perlite powder as a component of the PCC. This would lead to creating a new type of building material that successfully meets the requirements of sustainable construction.

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P. Łukowski

A Review of Self‐Healing Concrete for Damage Management of Structures

Cement concrete and concrete–polymer composites: Two merging worlds

The Effect of Nanosilica on the Mechanical Properties of polymer-Cement Composites (PCC)

Optimization of polymer concrete composites:

Polymer-Cement Composites Containing Waste Perlite Powder

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