Enhancing Carbon Capture and Utilization in Concrete Through Partial Replacement With Zeolite

DOI : 10.17577/IJERTCONV12IS0405

Download Full-Text PDF Cite this Publication

Text Only Version

Enhancing Carbon Capture and Utilization in Concrete Through Partial Replacement With Zeolite

Dr. Raghu K

Assistant Professor, Department of Civil Engineering, RRIT, Bengaluru Email: raghu.k@rrit.ac.in

Abstract- The construction industry is a significant source of global CO2 emissions, primarily due to cement production. This study investigates the potential of enhancing carbon capture in concrete by partially replacing cement with high-quality industrial zeolite powder, a chemical absorbent known for its superior adsorption properties. Dynamic column breakthrough experiments were conducted to evaluate CO2 uptake in both normal concrete and concrete with 15% zeolite replacement. The results show a substantial increase in CO2 uptake for zeolite- enhanced concrete compared to normal concrete, suggesting that incorporating zeolite can effectively reduce the carbon footprint of construction materials.

Keywords- carbon capture, zeolite, concrete, CO2 uptake, sustainable construction, dynamic column breakthrough

  1. Introduction

    Concrete is the most widely used construction material, but its production is responsible for substantial CO2 emissions, mainly from cement manufacturing. Finding ways to reduce these emissions is crucial for sustainability in the construction industry. One promising approach is enhancing the carbon capture capabilities of concrete itself by using materials with high adsorption capacities. High-quality industrial zeolite powder, a chemical absorbent with high surface area and porosity, offers a potential solution. This research explores the effectiveness of partially replacing cement with zeolite to improve the CO2 uptake capacity of concrete. Ease of Use

  2. Materials and Methods

    The study utilized M20 grade concrete. Zeolite-enhanced concrete was prepared by replacing 15% of the cement content with high-quality industrial zeolite powder. Dynamic column breakthrough experiments were conducted to measure the CO2 uptake over 7, 14, and 28 days.

    A Materials

    • Cement: Ordinary Portland Cement (OPC) was used.

    • Zeolite: High-quality industrial zeolite powder, known for its chemical absorbent properties, replaced 15% of the cement by weight.

    • Aggregates: Fine and coarse aggregates conforming to IS standards.

    • Water: Potable water was used for mixing.

      B. Concrete Mix Design

      Two concrete mixes were prepared:

    • Normal Concrete: Standard M20 grade mix.

    • Zeolite-Enhanced Concrete: 15% replacement of cement with high-quality industrial zeolite powder.

      C. Experimental Procedure

      Dynamic column breakthrough experiments were conducted to measure the CO2 uptake of both concrete types at different curing periods (7, 14, and 28 days). The CO2 uptake was quantified using gas chromatography.

  3. Results and Discussion

    1. CO2 Uptake in Normal Concrete

      • Normal Concrete 7 days Sample Initial Flow 250 ml/min Operational Flow 225 ml/min Sample Weight 2 gram

        qb = = 0.649 ml/g = 1.272 mg/g

        tq = [(78.5 39) × 0.9] 30.4 = 38.25 30.4 = 7.85 s

        J

        qa = = 0.141 ml/g = 0.276 mg/g

        Relative CO2 Concentration (C/C0)

        1.0

        0.8

        0.6

        0.4

        0.2

        0.0

        0 50 100 150 200

        Time (seconds)

        Fig 1 Dynamic CO2 Breakthrough Curve for Normal Concrete 7 days Sample

        • Normal Concrete 14 days Sample Total Uptake = 1.548 mg/g

          Initial Flow 250 ml/min Operational Flow 220 ml/min Sample Weight 2 gram

          qb = = 0.676 ml/g = 1.325 mg/g

          tq = [(107 38.5) × 0.9] = 61.65 52.61 = 9.04 s

          qa = = 0.159 ml/g=0.311 mg/g Total Uptake = 1.636 mg/g

          Fig 2 Dynamic CO2 Breakthrough Curve for Normal Concrete 14 days Sample.

        • Normal Concrete 28 days Sample Initial Flow 260 ml/min Operational Flow 230 ml/min

          qb = = 0.582 ml/g = 1.14 mg/g tq = [(96.5 31.5) × 0.9] 48.37 = 10.13 s

          qa = = 0.187 ml/g = 0.37 mg/g Total Uptake = 1.14 + 0.37 = 1.51 mg/g

          1.0

          0.8

          C/C0

          0.6

          0.4

          0.2

          0.0

          0 50 100 150 200 250

          t (s)

          The CO2 uptake in normal concrete increased from 7 to 14 days, indicating active carbonation processes. The slight decrease at 28 days suggests that the formation of a dense calcium carbonate layer might be limiting further CO2 diffusion and reaction within the concrete matrix.

    2. CO2 Uptake in Zeolite-Enhanced Concrete

    • 15% Zeolite 7 days curing Initial Flow 260 ml/min Operational Flow 230 ml/min

      qb = = 0.609 ml/g = 1.194 mg/g tq = [(70 33) × 0.9] 25.85 = 7.45 s

      qa = = 0.137 ml/g = 0.27 mg/g Total Uptake = 1.19 + 0.27 = 1.46 mg/g

      1.0

      0.8

      C/C0

      0.6

      0.4

      0.2

      0.0

      0 50 100 150 200 250

      t (s)

      Fig 4 Dynamic CO2 Breakthrough Curve for 15% Zeolite 7- day curing Sample.

    • 15% Zeolite 14days curing Initial Flow 260 ml/min Operational Flow 230 ml/min

      qb = = 0.754 ml/g = 1.48 mg/g tq = [(286.5 41) × 0.9] 202.68 = 18.27 s

      qa = = 0.336 ml/g = 0.66 mg/g Total Uptake = 1.48 + 0.66 = 2.14 mg/g

      Fig 3 Dynamic CO2 Breakthrough Curve for Normal Concrete 28 days Sample

      1.0

      0.8

      C/C0

      0.6

      0.4

      0.2

      0.0

      0 50 100 150 200 250 300 350

      t (s)

  4. Discussion

    1. Using high-quality industrial zeolite powder in concrete significantly enhances its CO2 uptake capacity. Zeolite's high surface area and microporous structure provide ample sites for CO2 adsorption, leading to continuous and effective carbon capture. These results suggest that incorporating zeolite into concrete can improve immediate CO2 capture and sustain this capacity over a longer period, thus contributing to the reduction of the overall carbon footprint of concrete structures.

    2. Compressive Strength

    The compressive strength of the zeolite-enhanced concrete was measured to ensure structural integrity. At 28 days, the compressive strength was approximately 24.5 N/mm², achieving the target strength for M20-grade concrete.

    Fig 5 Dynamic CO2 Breakthrough Curve for 15% Zeolite 14 days curing Sample.

    • 15% Zeolite 28 days curing Initial Flow 260 ml/min Operational Flow 230 ml/min

      qb = = 0.967 ml/g = 1.9 mg/g tq = [(968.5 51.5) × 0.9] 640.9 = 184.4 s

      qa = = 3.464 ml/g = 6.79 mg/g Total Uptake = 1.9 + 6.79 = 8.69 mg/g

      Fig 6 Dynamic CO2 Breakthrough Curve for 15% Zeolite 28 days curing Sample.

      The zeolite-enhanced concrete exhibited significantly higher CO2 uptake compared to normal concrete. The higher initial uptake at 7 days can be attributed to the zeolite's superior adsorption capacity. The marked increase at 28 days demonstrates the sustained ability of zeolite to capture CO2, even as the primary hydration reactions slow down, indicating the long-term benefits of using zeolite for carbon capture.

  5. Conclusion

This study demonstrates that partial replacement of cement with high-quality industrial zeolite powder significantly increaes the CO2 uptake capacity of concrete. The zeolite- enhanced concrete shows a pronounced ability to capture and retain CO2 over an extended period, making it a viable option for sustainable construction practices. Future research should focus on optimizing the zeolite content and further examining the long-term durability and mechanical properties of zeolite- enhanced concrete to ensure it meets structural requirements for various construction applications.

References

  1. Madhav, D., Coppitters, T., Ji, Y., Thielemans, W., Desplentere, F., Moldenaers, P., Vandeginste, V. Amino acid promoted single-step carbon dioxide capture and mineralization integrated with polymer-mediated crystallization of carbonates. Journal of Cleaner Production. (2023); 623, Art.No. 137845.

  2. Qu, Z., Yu, Q., Ong, G.P., Cardinaels, R., Ke, L., Long, Y., Geng, G. 3D printing concrete containing thermal responsive gelatin: Towards cold environment applications. Cement & Concrete Composites, . (2023). 140, Art.No. 105029.

  3. Madhav, D., Buffel, B., Desplentere, F., Moldenaers, P., Vandeginste, V. Bio-inspired mineralization of CO2 into CaCO3: Single-step carbon capture and utilization with controlled crystallization. Fuel. (2023);. 345, Art.No. 128157.

  4. Lakshminarayana Kudinalli Gopalakrishna Bhatta, Seetharamu Subramanyam, Madhusoodana D. Chengala, Umananda Manjunatha Bhatta, Krishna Venkatesh and V. Raghavendra. Measurement of CO 2 Adsorption Using the Cost-Effective Dynamic Column Breakthrough Method. Current Science. (2017); VOL. 112, NO. 4. DOI:10.18520/CS/V112/I04/835-838.

  5. Yin, G., Liu, Z., Wu, W. and Liu, Q., Dynamic adsorption of CO2 over activated carbon error analysis and effect of N2. Chem. Eng. J. (2013);. 219, 380384.

  6. Maring, B. J. and Webley, P. A., A new simplified pressure/vacuum swing adsorption model for rapid adsorbent screening for CO2 capture applications.

    Int. J. Greenhouse Gas Control. (2013); 15, 1631

  7. Drage, T. C. et al., Materials challenges for the development of solid sorbents for post-combustion carbon capture. J. Mater. Chem. (2012); 22, 28152823.

  8. Garcia, S., Gil, M. V., Martin, C. F., Pis, J. J., Rubiera, F. and Pevida, C., Breakthrough adsorption study of a commercial activated carbon for pre- combustion CO2 capture. Chem. Eng. J. (2011); 171, 549556

  9. Konduru, N., Lindner, P. and Assaf-Anid, N. M., Curbing the greenhouse effect by carbon dioxide adsorption with zeolite 13X. AIChE J.(2007); 53, 31373143.

  10. Serna-Guerrero, R., Belmabkhout, Y. and Sayari, A., Further investigations of CO2 capture using triamine-grafted poreexpanded mesoporous silica. Chem. Eng. J. (2010); 158, 513519.