Long-term performance of novel high-calcium one-part alkali-activated cement developed from thermally activated lime kiln dust

Alkali-activated materials: the role of molecular-scale research and lessons from the energy transition to combat climate change

RILEM Technical Letters ◽

10.21809/rilemtechlett.2019.98 ◽

2020 ◽

Vol 4 ◽

pp. 110-121 ◽

Cited By ~ 1

Author(s):

Claire White

Keyword(s):

Portland Cement ◽

Financial Incentives ◽

Field Performance ◽

Energy Transition ◽

Combat Climate Change ◽

Long Term Performance ◽

Term Performance ◽

Alkali Activated

Alternative (i.e., non-Portland) cements, such as alkali-activated materials, have gained significant interest from the scientific community due to their proven CO2 savings compared with Portland cement together with known short-term performance properties. However, the concrete industry remains dominated by Portland cement-based concrete. This Letter explores the technical and non-technical hurdles preventing implementation of an alternative cement, such as alkali-activated materials, in the concrete industry and discusses how these hurdles can be overcome. Specifically, it is shown that certain technical hurdles, such as a lack of understanding how certain additives affect setting of alkali-activated materials (and Portland cement) and the absence of long-term in-field performance data of these sustainable cements, can be mitigated via the use of key molecular- and nano-scale experimental techniques to elucidate dominant material characteristics, including those that control long-term performance. In the second part of this Letter the concrete industry is compared and contrasted with the electricity generation industry, and specifically the transition from one dominant technology (i.e., coal) to a diverse array of energy sources including renewables. It is concluded that financial incentives and public advocacy (akin to advocacy for renewables in the energy sector) would significantly enhance uptake of alternative cements in the concrete industry.

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Steel corrosion in reinforced alkali-activated materials

RILEM Technical Letters ◽

10.21809/rilemtechlett.2017.39 ◽

2017 ◽

Vol 2 ◽

pp. 33-39 ◽

Cited By ~ 16

Author(s):

Shishir Mundra ◽

Susan A. Bernal ◽

Maria Criado ◽

Petr Hlaváček ◽

Gino Ebell ◽

...

Keyword(s):

Corrosion Behaviour ◽

Steel Corrosion ◽

Threshold Value ◽

Steel Reinforcement ◽

Solution Chemistry ◽

Phase Assemblage ◽

Long Term Performance ◽

Term Performance ◽

Alkali Activated

The development of alkali-activated materials (AAMs) as an alternative to Portland cement (PC) has seen significant progress in the past decades. However, there still remains significant uncertainty regarding their long term performance when used in steel-reinforced structures. The durability of AAMs in such applications depends strongly on the corrosion behaviour of the embedded steel reinforcement, and the experimental data in the literature are limited and in some cases inconsistent. This letter elucidates the role of the chemistry of AAMs on the mechanisms governing passivation and chloride-induced corrosion of the steel reinforcement, to bring a better understanding of the durability of AAM structures exposed to chloride. The corrosion of the steel reinforcement in AAMs differs significantly from observations in PC; the onset of pitting (or the chloride ‘threshold’ value) depends strongly on the alkalinity, and the redox environment, of these binders. Classifications or standards used to assess the severity of steel corrosion in PC appear not to be directly applicable to AAMs due to important differences in pore solution chemistry and phase assemblage.

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Performance of Asphalt and Clay Liners as a Uranium Mill Tailings Leachate Barrier

MRS Proceedings ◽

10.1557/proc-6-489 ◽

1981 ◽

Vol 6 ◽

Author(s):

James Buelt ◽

Steve Barnes

Keyword(s):

Pacific Northwest ◽

Elevated Temperatures ◽

Thin Layers ◽

Clay Liners ◽

Mill Tailings ◽

High Calcium ◽

Long Term Performance ◽

Term Performance ◽

Uranium Mill Tailings

ABSTRACTPacific Northwest Laboratory is evaluating the long-term effectiveness of various asphalt and clay liner materials as a radionuclide and process chemical barrier from uranium mill tailings. A field test is being conducted by monitoring asphalt and clay liners installed at the Grand Junction, Colorado tailings site. In addition eight prospective liners have undergone three months exposure to accelerated conditions to predict their behavior over a 1000 year period. High calcium leachates have been forced through thin layers of clay to determine the ability of the clay to resist ion exchange, which reduces its swelling capabilities. Asphalt liners have been exposed to elevated temperatures and increased strengths of oxidizing agents to accelerate their aging process. The permeability coefficients measured during this exposure were then used to predict each liners stability with time. The analyses thus far show that clay soils with bentonite amendments and most asphalt compositions have good long-term performance characteristics.

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