Trash to Treasure: Waste Carbon into Construction Materials

Ivy Wu; Irene Walker; Tami Olushina; Bob Bell; Kerry Rippy

doi:10.2172/3017151

Trash to Treasure: Waste Carbon into Construction Materials

Ivy Wu
, Irene Walker
, Tami Olushina
, Bob Bell
, Kerry Rippy

National Laboratory of the Rockies

Research output: NLR › Poster

Abstract

Mineralization of industrial waste and earth-abundant CO2 into value-added products is a powerful method of utilizing domestic resources to produce value from waste. Carbonate minerals formed from Ca and Mg rich waste streams are key constituents in cement and concrete, which are in demand at the gigaton-scale every year. While thermodynamically favorable, CO2 mineralization is hindered by slow kinetics, and traditional thermochemical routes are too expensive to scale. Here, we demonstrate the advantages of an electrochemical method of waste valorization, which eliminates this limitation and improves kinetics. We highlight this method's ability to initiate crystallization under favorable local conditions, producing carbonates from mining waste at mildly acidic pH. We highlight the effects of key constituents in mining waste on the mineralization process.

Original language	American English
Publisher	National Renewable Energy Laboratory (NREL)
Number of pages	1
DOIs	https://doi.org/10.2172/3017151
State	Published - 2025

Publication series

Name	Presented at NREL Cement & Concrete Critical Technologies, 9 June 2025, Golden, Colorado

NLR Publication Number

NLR/PO-5500-95107

Keywords

cement
mineralization
mining waste

Access to Document

10.2172/3017151

https://www.nlr.gov/docs/fy26osti/95107.pdf

Cite this

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title = "Trash to Treasure: Waste Carbon into Construction Materials",

abstract = "Mineralization of industrial waste and earth-abundant CO2 into value-added products is a powerful method of utilizing domestic resources to produce value from waste. Carbonate minerals formed from Ca and Mg rich waste streams are key constituents in cement and concrete, which are in demand at the gigaton-scale every year. While thermodynamically favorable, CO2 mineralization is hindered by slow kinetics, and traditional thermochemical routes are too expensive to scale. Here, we demonstrate the advantages of an electrochemical method of waste valorization, which eliminates this limitation and improves kinetics. We highlight this method's ability to initiate crystallization under favorable local conditions, producing carbonates from mining waste at mildly acidic pH. We highlight the effects of key constituents in mining waste on the mineralization process.",

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T1 - Trash to Treasure: Waste Carbon into Construction Materials

AU - Wu, Ivy

AU - Walker, Irene

AU - Olushina, Tami

AU - Bell, Bob

AU - Rippy, Kerry

PY - 2025

Y1 - 2025

N2 - Mineralization of industrial waste and earth-abundant CO2 into value-added products is a powerful method of utilizing domestic resources to produce value from waste. Carbonate minerals formed from Ca and Mg rich waste streams are key constituents in cement and concrete, which are in demand at the gigaton-scale every year. While thermodynamically favorable, CO2 mineralization is hindered by slow kinetics, and traditional thermochemical routes are too expensive to scale. Here, we demonstrate the advantages of an electrochemical method of waste valorization, which eliminates this limitation and improves kinetics. We highlight this method's ability to initiate crystallization under favorable local conditions, producing carbonates from mining waste at mildly acidic pH. We highlight the effects of key constituents in mining waste on the mineralization process.

AB - Mineralization of industrial waste and earth-abundant CO2 into value-added products is a powerful method of utilizing domestic resources to produce value from waste. Carbonate minerals formed from Ca and Mg rich waste streams are key constituents in cement and concrete, which are in demand at the gigaton-scale every year. While thermodynamically favorable, CO2 mineralization is hindered by slow kinetics, and traditional thermochemical routes are too expensive to scale. Here, we demonstrate the advantages of an electrochemical method of waste valorization, which eliminates this limitation and improves kinetics. We highlight this method's ability to initiate crystallization under favorable local conditions, producing carbonates from mining waste at mildly acidic pH. We highlight the effects of key constituents in mining waste on the mineralization process.

KW - cement

KW - mineralization

KW - mining waste

U2 - 10.2172/3017151

DO - 10.2172/3017151

M3 - Poster

T3 - Presented at NREL Cement & Concrete Critical Technologies, 9 June 2025, Golden, Colorado

PB - National Renewable Energy Laboratory (NREL)

ER -

Trash to Treasure: Waste Carbon into Construction Materials

Abstract

Publication series

NLR Publication Number

Keywords

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Cite this