Comparative Analysis of Pedestrian Bridge Alternatives Using Steel, Ordinary Portland Concrete, and Geopolymer Concrete for Structural, Environmental, and Economic Performance

Johan Sudario-Suarez; Natividad García-Troncoso; Juan Molina-Cedeño; Alejandra Borbor-Bajaña; Henry Ponce-Pineda; David Valverde-Burneo; Eva O.L. Lantsoght

doi:10.2749/ghent.2025.0873

Comparative Analysis of Pedestrian Bridge Alternatives Using Steel, Ordinary Portland Concrete, and Geopolymer Concrete for Structural, Environmental, and Economic Performance

Johan Sudario-Suarez
, Natividad García-Troncoso^*
, Juan Molina-Cedeño
, Alejandra Borbor-Bajaña
, Henry Ponce-Pineda
, David Valverde-Burneo
, Eva O.L. Lantsoght

^*Corresponding author for this work

Escuela Superior Politécnica del Litoral
Delft University of Technology

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

The accelerated population growth in Guayaquil has increased the demand for pedestrian infrastructure, emphasizing the need for sustainable, cost-effective materials. This study evaluates three alternatives for pedestrian bridges: A36 structural steel, conventional concrete (OPC), and geopolymer concrete (GPC). These solutions are compared using structural analysis in SAP2000, life cycle assessment (LCA), and cost evaluation through BIM modelling in Revit. Both A36 steel and Ordinary Portland Concrete (OPC) demonstrated superior structural performance, whereas GPC displayed increased deflections due to a lower modulus of elasticity. However, GPC offered significant environmental advantages, with CO₂ emissions up to 67% lower than OPC and potential cost savings of up to 11% at higher strengths. The findings underscore GPC's promise as a sustainable alternative, offering reduced carbon footprint and competitive costs.

Original language	English
Title of host publication	IABSE Congress Ghent 2025
Subtitle of host publication	The Essence of Structural Engineering for Society, Proceedings
Editors	Davide Leonetti, Bert Snijder, Bart De Pauw, Bart De Pauw, Sander van Alphen
Publisher	International Association for Bridge and Structural Engineering (IABSE)
Pages	873-882
Number of pages	10
ISBN (Electronic)	9783857482106
DOIs	https://doi.org/10.2749/ghent.2025.0873
State	Published - 2025
Event	2025 International Association for Bridge and Structural Engineering, IABSE 2025 - Ghent, Belgium Duration: 27 Aug 2025 → 29 Aug 2025

Publication series

Name	IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings

Conference

Conference	2025 International Association for Bridge and Structural Engineering, IABSE 2025
Country/Territory	Belgium
City	Ghent
Period	27/08/25 → 29/08/25

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy
SDG 12 Responsible Consumption and Production

Keywords

BIM modelling
Geopolymer concrete
life cycle assessment
pedestrian bridge
structural analysis

Access to Document

10.2749/ghent.2025.0873

Cite this

Sudario-Suarez, J., García-Troncoso, N., Molina-Cedeño, J., Borbor-Bajaña, A., Ponce-Pineda, H., Valverde-Burneo, D., & Lantsoght, E. O. L. (2025). Comparative Analysis of Pedestrian Bridge Alternatives Using Steel, Ordinary Portland Concrete, and Geopolymer Concrete for Structural, Environmental, and Economic Performance. In D. Leonetti, B. Snijder, B. De Pauw, B. De Pauw, & S. van Alphen (Eds.), IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings (pp. 873-882). (IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings). International Association for Bridge and Structural Engineering (IABSE). https://doi.org/10.2749/ghent.2025.0873

Sudario-Suarez, Johan ; García-Troncoso, Natividad ; Molina-Cedeño, Juan et al. / Comparative Analysis of Pedestrian Bridge Alternatives Using Steel, Ordinary Portland Concrete, and Geopolymer Concrete for Structural, Environmental, and Economic Performance. IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings. editor / Davide Leonetti ; Bert Snijder ; Bart De Pauw ; Bart De Pauw ; Sander van Alphen. International Association for Bridge and Structural Engineering (IABSE), 2025. pp. 873-882 (IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings).

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title = "Comparative Analysis of Pedestrian Bridge Alternatives Using Steel, Ordinary Portland Concrete, and Geopolymer Concrete for Structural, Environmental, and Economic Performance",

abstract = "The accelerated population growth in Guayaquil has increased the demand for pedestrian infrastructure, emphasizing the need for sustainable, cost-effective materials. This study evaluates three alternatives for pedestrian bridges: A36 structural steel, conventional concrete (OPC), and geopolymer concrete (GPC). These solutions are compared using structural analysis in SAP2000, life cycle assessment (LCA), and cost evaluation through BIM modelling in Revit. Both A36 steel and Ordinary Portland Concrete (OPC) demonstrated superior structural performance, whereas GPC displayed increased deflections due to a lower modulus of elasticity. However, GPC offered significant environmental advantages, with CO2 emissions up to 67\% lower than OPC and potential cost savings of up to 11\% at higher strengths. The findings underscore GPC's promise as a sustainable alternative, offering reduced carbon footprint and competitive costs.",

keywords = "BIM modelling, Geopolymer concrete, life cycle assessment, pedestrian bridge, structural analysis",

author = "Johan Sudario-Suarez and Natividad Garc{\'i}a-Troncoso and Juan Molina-Cede{\~n}o and Alejandra Borbor-Baja{\~n}a and Henry Ponce-Pineda and David Valverde-Burneo and Lantsoght, \{Eva O.L.\}",

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series = "IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings",

publisher = "International Association for Bridge and Structural Engineering (IABSE)",

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Sudario-Suarez, J, García-Troncoso, N, Molina-Cedeño, J, Borbor-Bajaña, A, Ponce-Pineda, H, Valverde-Burneo, D & Lantsoght, EOL 2025, Comparative Analysis of Pedestrian Bridge Alternatives Using Steel, Ordinary Portland Concrete, and Geopolymer Concrete for Structural, Environmental, and Economic Performance. in D Leonetti, B Snijder, B De Pauw, B De Pauw & S van Alphen (eds), IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings. IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings, International Association for Bridge and Structural Engineering (IABSE), pp. 873-882, 2025 International Association for Bridge and Structural Engineering, IABSE 2025, Ghent, Belgium, 27/08/25. https://doi.org/10.2749/ghent.2025.0873

Comparative Analysis of Pedestrian Bridge Alternatives Using Steel, Ordinary Portland Concrete, and Geopolymer Concrete for Structural, Environmental, and Economic Performance. / Sudario-Suarez, Johan; García-Troncoso, Natividad; Molina-Cedeño, Juan et al.
IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings. ed. / Davide Leonetti; Bert Snijder; Bart De Pauw; Bart De Pauw; Sander van Alphen. International Association for Bridge and Structural Engineering (IABSE), 2025. p. 873-882 (IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Comparative Analysis of Pedestrian Bridge Alternatives Using Steel, Ordinary Portland Concrete, and Geopolymer Concrete for Structural, Environmental, and Economic Performance

AU - Sudario-Suarez, Johan

AU - García-Troncoso, Natividad

AU - Molina-Cedeño, Juan

AU - Borbor-Bajaña, Alejandra

AU - Ponce-Pineda, Henry

AU - Valverde-Burneo, David

AU - Lantsoght, Eva O.L.

PY - 2025

Y1 - 2025

N2 - The accelerated population growth in Guayaquil has increased the demand for pedestrian infrastructure, emphasizing the need for sustainable, cost-effective materials. This study evaluates three alternatives for pedestrian bridges: A36 structural steel, conventional concrete (OPC), and geopolymer concrete (GPC). These solutions are compared using structural analysis in SAP2000, life cycle assessment (LCA), and cost evaluation through BIM modelling in Revit. Both A36 steel and Ordinary Portland Concrete (OPC) demonstrated superior structural performance, whereas GPC displayed increased deflections due to a lower modulus of elasticity. However, GPC offered significant environmental advantages, with CO2 emissions up to 67% lower than OPC and potential cost savings of up to 11% at higher strengths. The findings underscore GPC's promise as a sustainable alternative, offering reduced carbon footprint and competitive costs.

AB - The accelerated population growth in Guayaquil has increased the demand for pedestrian infrastructure, emphasizing the need for sustainable, cost-effective materials. This study evaluates three alternatives for pedestrian bridges: A36 structural steel, conventional concrete (OPC), and geopolymer concrete (GPC). These solutions are compared using structural analysis in SAP2000, life cycle assessment (LCA), and cost evaluation through BIM modelling in Revit. Both A36 steel and Ordinary Portland Concrete (OPC) demonstrated superior structural performance, whereas GPC displayed increased deflections due to a lower modulus of elasticity. However, GPC offered significant environmental advantages, with CO2 emissions up to 67% lower than OPC and potential cost savings of up to 11% at higher strengths. The findings underscore GPC's promise as a sustainable alternative, offering reduced carbon footprint and competitive costs.

KW - BIM modelling

KW - Geopolymer concrete

KW - life cycle assessment

KW - pedestrian bridge

KW - structural analysis

UR - https://www.scopus.com/pages/publications/105021077320

U2 - 10.2749/ghent.2025.0873

DO - 10.2749/ghent.2025.0873

M3 - Contribución a la conferencia

AN - SCOPUS:105021077320

T3 - IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings

SP - 873

EP - 882

BT - IABSE Congress Ghent 2025

A2 - Leonetti, Davide

A2 - Snijder, Bert

A2 - De Pauw, Bart

A2 - van Alphen, Sander

PB - International Association for Bridge and Structural Engineering (IABSE)

T2 - 2025 International Association for Bridge and Structural Engineering, IABSE 2025

Y2 - 27 August 2025 through 29 August 2025

ER -

Sudario-Suarez J, García-Troncoso N, Molina-Cedeño J, Borbor-Bajaña A, Ponce-Pineda H, Valverde-Burneo D et al. Comparative Analysis of Pedestrian Bridge Alternatives Using Steel, Ordinary Portland Concrete, and Geopolymer Concrete for Structural, Environmental, and Economic Performance. In Leonetti D, Snijder B, De Pauw B, De Pauw B, van Alphen S, editors, IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings. International Association for Bridge and Structural Engineering (IABSE). 2025. p. 873-882. (IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings). doi: 10.2749/ghent.2025.0873

Comparative Analysis of Pedestrian Bridge Alternatives Using Steel, Ordinary Portland Concrete, and Geopolymer Concrete for Structural, Environmental, and Economic Performance

Abstract

Publication series

Conference

UN SDGs

Keywords

Access to Document

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