Ceramic materials are ubiquitous in the world of construction. Building materials such as cement, bricks, tiles, or electrical insulators like porcelain are all ceramic products that we rely on in our daily lives. These ceramics are manufactured by a method called sintering—the process of turning powdery solids into a hardened mass by applying pressure or temperature. Most sintering processes involve temperatures beyond 1,000ºC, which makes this method very energy-hungry. Moreover, the high temperature also makes the sintering of raw materials such as carbonates and hydroxides difficult as they are prone to thermal decomposition at high temperatures.
Magnesium carbonate and hydroxides are emerging candidates for building materials owing to their thermodynamic stability and their ability to harden, or sinter, like slaked lime plaster. However, these materials cannot be sintered using the conventional sintering process as they undergo thermal decomposition. However, not much is known about how these materials react to a milder technique called cold sintering. To address this research gap, a team of researchers from Nagoya Institute of Technology, consisting of Prof. Shinobu Hashimoto and Mr. Keitaro Yamaguchi, investigated the mechanism by which Mg–C–O–H systems harden by the cold sintering process (or CSP). Their findings are summarized in a recent study made available online on April 21st, 2022, and published in Ceramics International on August 1, 2022.
The CSP gained popularity in recent years due to its low energy dependence. This process imitates the sedimentary rock formation process that occurs in the Earth’s crust, allowing solidification to occur under several hundred megapascals of pressure but at milder temperatures such as 300ºC or below. This makes the process less energy-intensive and ideal for manufacturing construction materials with low thermal decomposition temperatures.
“Basic magnesium carbonate, or magnesite, has been proposed for use as a carbon storage material alongside its usage as a structural material. But magnesite is difficult to produce as by conventional industrial methods due to the influence of hydration during production and high temperature pyrolysis of sintering process,” explains Prof. Hashimoto. “Our study aims to understand if Mg–C–O–H systems can undergo desirable solidification into construction ceramics via CSP.”
The team used magnesium hydroxide and basic magnesium hydroxide powders as the ceramic precursors and water as the solvent. They heated the former at 250ºC and the latter at 150ºC with 10 mass% water, under a pressure of 270 megapascals (MPa) for an hour each. They found that compressive strength and relative density values for solidified magnesium hydroxide were 121 MPa and 84%, respectively, whereas the values for solidified basic magnesium carbonate were 275 MPa and 88%, respectively. The team also discovered that the water played a significant role in promoting the dissolution-precipitation reaction that is necessary for the densification of powders during the CSP. This phenomenon ensured that the sintering to form solid masses occurred at lower temperatures.
The results of this study provide a fresh perspective on sintering, which is generally considered a high-temperature and high-energy process. The CSP not only allows ceramics manufacturing of materials susceptible to thermal decomposition but also ensures excellent results by controlling the microstructure of the solidified products.
“The construction industry is one of the major consumers of energy responsible for 38% of global energy-related CO2 broadcasts. Through our research, we aim to get a step closer to building a future where manufacturing building materials is more sustainable and greener,” concludes Prof. Hashimoto.
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Keitaro Yamaguchi et al, Cold sintering of the Mg–C–O–H system, Ceramics International (2022). DOI: 10.1016/j.ceramint.2022.04.162
Provided by Nagoya Institute of Technology
Quote: Mimicking the Earth’s crust: Examining solidification of building material candidates by cold sintering (2022, September 21) retrieved 21 September 2022 from https://phys.org/news/2022-09-mimicking-earth-crust-solidification-material. html
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