Ultra-high-performance cementitious composites with enhanced mechanical and durability characteristics

Concrete is the most widely used construction material. It offers a desirable balance of cost, strength, moisture barrier qualities, and dimensional and chemical stability. The rising costs of aging infrastructure systems, however, point to the need for further improvements in concrete properties. C...

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Bibliographic Details
Published in:SN applied sciences 2021-06, Vol.3 (6), p.676-16, Article 676
Main Authors: Sadiq, Muhammad M., Soroushian, Parviz, Bakker, Martin G., Balachandra, Anagi M.
Format: Article
Language:English
Subjects:
Abrasion
Abrasion resistance
Applied and Technical Physics
Carbon
Carbon fibers
Cement
Chemistry/Food Science
Concrete
Concrete properties
Construction materials
Dimensional stability
Ductility
Earth Sciences
Energy absorption
Engineering
Environment
Experimental methods
Flexural strength
Fractions
Graphene
Humidity
Low weight
Materials Science
Mechanical properties
Moisture barrier qualities
Moisture effects
Moisture resistance
Multi wall carbon nanotubes
Nanocomposites
Nanofibers
Nanomaterials
Nanotechnology
Nanotubes
Particle size
Research Article
Research methodology
Surface functionalized carbon nanomaterials
Tensile strength
Toughness
Ultra-high-performance cementitious matrices
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Summary:Concrete is the most widely used construction material. It offers a desirable balance of cost, strength, moisture barrier qualities, and dimensional and chemical stability. The rising costs of aging infrastructure systems, however, point to the need for further improvements in concrete properties. Carbon-based nanomaterials (CBNs) are predicted to have excellent mechanical properties, and so are attractive candidates for addressing these issues. However, the relatively high cost of CBNs, means that only low weight fractions in cement matrices will be economically viable, which presents a significant challenge. The research presented here investigated various surface functionalization techniques for improving the compatibility of carbon nanomaterials (multi-walled carbon nanotubes, carbon nanofiber and graphene nanoplatelets) with cementitious materials in fresh and hardened state. The effects of surface functionalization on the contributions of CBNs to the performance characteristics of ultra-high-performance cementitious matrices (UHPCM) were evaluated. Functionalized multi-walled carbon nanotubes at 0.03% weight fraction increased the flexural strength by 30%, doubled the energy absorption capacity, and tripled the ductility of UHPCM. The moisture barrier qualities, abrasion resistance and toughness characteristics of UHPCM benefited significantly from introduction of CBNs at less than 0.1% weight fraction. This study demonstrates that the low weight fraction of CBNs can effectively enhance the key engineering properties of UHPCM at a viable cost. Thus, this approach has both performance advantages and economic benefits. Article highlights Surface functionalization of multiwalled CNTs improved dispersion in cementitious matrices at low weight fractions. 0.03 wt.% multiwalled CNT addition increased the flexural strength and the flexural toughness of UHPCM. Abrasion resistance and moisture barrier qualities improved. These improvements are achieved at viable cost.
ISSN:2523-3963
2523-3971
DOI:10.1007/s42452-021-04628-y