通过隔热膜轻松扩散二氧化碳以实现脱碳

DeCarbon Pub Date : 2024-07-14 DOI:10.1016/j.decarb.2024.100063

Gad Licht , Ethan Peltier , Simon Gee , Stuart Licht

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引用次数: 0

摘要

据推测和论证，隔热膜可有效阻隔热流，同时促进二氧化碳的有效扩散。脱碳技术通常需要一个二氧化碳浓缩系统，该系统通常基于胺结合或石灰反应，能耗高，碳足迹大。而 C2CNT 电解熔融碳酸盐脱碳技术则不需要二氧化碳预浓缩，还能从捕获的二氧化碳中提供有用的产品（石墨烯纳米碳）。开孔、低密度的隔热膜可促进高温脱碳过程中二氧化碳的有效扩散。经测量，选定的高温强隔热二氧化硅复合材料的孔隙率ε超过了 0.9（孔隙率达 90%），并且经扫描电子显微镜测量，显示出有利于二氧化碳扩散的大型开放通道。通过这些膜推导并经实验验证的二氧化碳扩散常数估计值为 DM-porous = ε3/2 DCO2，其中 DCO2 是空气中的扩散常数。DM-porous 适用于空气和 N2 中各种浓度的 CO2。CO2 扩散常数可转换为 CO2 的等效脱碳系统摩尔流入量，并显示其能够维持较高的 CO2 去除率。与 N2、O2 或 H2O 相比，该系统对 CO2 有很强的电解质亲和力，因此该系统包含一个无需预先浓缩 CO2 的脱碳框架。

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Facile CO2 diffusion for decarbonization through thermal insulation membranes

It is hypothesized and demonstrated that thermal insulation membranes can provide an effective barrier to heat flow and simultaneously facilitate effective CO₂ diffusion. Decarbonization technology often requires a CO₂ concentration system, often based on amine binding or lime reaction, which is energy intensive and carries a high carbon footprint. Alternatively, C2CNT electrolytic molten carbonate decarbonization does not require CO₂ pre-concentration and also provides a useful product (graphene nanocarbons) from the captured CO₂.

Here, a method of effective CO₂ diffusion is demonstrated that simultaneously thermally insulates the decarbonization source gas from the high-temperature C2CNT system. Open pore, low-density, thermal insulations are implemented as membranes that facilitate effective CO₂ diffusion for high-temperature decarbonization. Selected, high-temperature, strongly thermal insulating, silica composites are measured with porosities, $ε$ , exceeding 0.9 (>90% porosity), and which display, as measured by SEM, large open channels facilitating CO₂ diffusion. A derived and experimentally verified estimate for the CO₂ diffusion constant through these membranes is D_M-porous = $ε^{3 / 2}$ D_CO2, where D_CO2 is the diffusion constant in air. D_M-porous is applicable to a wide-range of CO₂ concentrations both in the air and N₂.

The CO₂ diffusion constant is translated to the equivalent decarbonization system mole influx of CO₂ and shown capable of sustaining high rates of CO₂ removal. Combined with the strong electrolyte affinity for CO₂ compared to N₂, O₂, or H₂O, the system comprises a framework for decarbonization without pre-concentration of CO₂.

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DeCarbon

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