International Concrete Abstracts Portal

International Concrete Abstracts Portal

The International Concrete Abstracts Portal is an ACI led collaboration with leading technical organizations from within the international concrete industry and offers the most comprehensive collection of published concrete abstracts.

Showing 1-5 of 31692 Abstracts search results

Document: 

24-335

Date: 

July 10, 2025

Author(s):

Feyza Nur Sahan, W. Jason Weiss, O. Burkan Isgor

Publication:

Materials Journal

Abstract:

The role of limestone (LS) powder replacement and changes in C-S-H due to pozzolanic reactions on the acid resistance of cementitious pastes are studied using thermodynamic modeling. Simulations are performed under equilibrium conditions while hydration products were exposed to increasing levels of sulfuric acid. LS replacement doesn’t show sacrificial characteristics against sulfuric acid attack, and LS acidification starts only after full consumption of portlandite, and most C-S-H. Increased LS replacement causes the dilution of the formed portlandite and C-S-H volumes, which results in their full consumption at lower acid concentrations than mixtures without LS replacement. Pozzolanic reactions of SCMs result in C-S-H phases with lower Ca/Si than OPC-only counterparts, increasing acid resistance. However, highly reactive and/or high-volume SCM replacements might further decrease the available portlandite, reducing the buffer acid resistance capacity. This issue is particularly critical for portland limestone cement-based systems.

DOI:

10.14359/51749035


Document: 

24-434

Date: 

July 10, 2025

Author(s):

Justin Dickey, Kevin J. Folliard, Thanos Drimalas

Publication:

Materials Journal

DOI:

10.14359/51749036


Document: 

24-030

Date: 

July 1, 2025

Author(s):

Kwanwoo Yi and Thomas H.-K. Kang

Publication:

Structural Journal

Volume:

122

Issue:

4

Abstract:

This study used finite element analysis to examine how tendon configuration affects the temperature behavior of post-tensioned concrete structures during fire exposure. The thermal behavior of various tendon configurations was modeled, showing good agreement with experimental data. Parametric studies found that unbonded single-strand tendons (S) and prestressing (pretensioned) strands (R) had lower thermal resistance than bonded post-tensioned tendons (B), unbonded post-tensioned tendons (U), and grouted extruded-strand tendons (G). The S and R specimens stayed at or below the critical temperature for one-way slabs, validating current safety codes. The B, U, and G specimens remained well below critical temperatures, indicating that a thinner concrete cover might suffice. These findings highlight the need to consider tendon configuration in structural fire-resistance evaluation and incorporate heat resistance assessment to ensure the safety and efficiency of prestressed concrete structures during fires.

DOI:

10.14359/51745642


Document: 

23-212

Date: 

July 1, 2025

Author(s):

Benjamin Matthews, Alessandro Palermo, and Allan Scott

Publication:

Structural Journal

Volume:

122

Issue:

4

Abstract:

This paper proposes a series of empirical modifications to an existing three-step analytical model used to derive the cyclic shear capacity of circular reinforced concrete (RC) columns considering corrosive conditions. The results of 16 shear-critical RC columns, artificially corroded to various degrees and tested under quasistatic reversed cyclic loading, are used for model verification. The final model is proposed in a piecewise damage-state format relative to the measured damage of the steel reinforcement. New empirical decay coefficients are derived to determine the degraded material properties based on an extensive database of over 1380 corroded tensile tests. An additional database of 44 corroded RC circular piers is collected to assist in the modification of ductility-based parameters. Compared to the shear-critical test specimens, the model results indicate that the peak shear capacity can be predicted well across a range of deterioration severities (0 to 58.5% average transverse mass loss), with a mean predictive ratio of ±8.60%. As damage increases, the distribution of the corrosion relative to the location of the shear plane becomes a critical performance consideration, increasing predictive variance.

DOI:

10.14359/51745466


Document: 

23-359

Date: 

July 1, 2025

Author(s):

Aaron Nzambi, Denio Oliveira, and Joao Filho

Publication:

Structural Journal

Volume:

122

Issue:

4

Abstract:

This experimental study investigates the influence of flexuralcracks and punching shear failure inclination on double-headedstud anchorage within the critical perimeter. The research alsoexplored the technical feasibility of using synthetic coarse aggregatesfrom bauxite residue as a sustainable alternative in structuralconcrete production. The results showed that the overall structuralintegrity is impaired at 40 to 50% due to flexural cracks at thecritical perimeter of 2d (30 degrees); however, the perimeter of1.2d (45 degrees) enhanced the shear reinforcement activationand shear strength up 15%, providing a balanced failure withinthe strengthening zone. Thus, a concrete anchoring capacity (CAC)method was proposed to calculate the contribution of doubleheadedstuds in serviceability and ultimate limit states. In addition,synthetic aggregates performed similarly to natural aggregates,offering environmental benefits such as reducing the carbon footprint and production stages.

DOI:

10.14359/51745467


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