空气驱动的膜电解技术促进硅灰石矿化CO2产白炭黑的研究

doi:10.11949/0438-1157.20230930

摘要/Abstract

摘要：

化石燃料燃烧排放的大量CO₂造成了全球气候变暖。CO₂矿化是近年来CO₂末端减排最有效的技术之一。CO₂矿化的本质是利用天然碱性矿物或工业碱性固废将酸性CO₂气体转化、固定为碳酸盐的过程，但目前所报道的技术大多仍面临高能耗、高成本的限制。提出一种安全、环保、低能耗的空气驱动的膜电解技术，可在低能耗下促使硅灰石有效矿化CO₂并产优质多孔白炭黑（二氧化硅）产品。核心技术为：电解条件下，阴极氧气还原反应（ORR）与阳极析氧反应（OER）同时进行实现低能耗下水的电离产生碱性和酸性液体。该电解技术比同电流密度下电解水低至少0.5 V的电解电压。电解所得酸性溶液溶解硅灰石后与电解所得碱性溶液混合可得优质多孔二氧化硅，CO₂通入后可被有效吸收并得到矿化产物碳酸钙，实现了高效矿化利用CO₂。

关键词: 二氧化碳捕集, 电解, 二氧化硅, 电化学, 催化剂, 二氧化碳减排

Abstract:

The large amount of CO₂emitted by the burning of fossil fuels contributes to global climate warming. CO₂ mineralization is one of the most effective technologies for CO₂ terminal emission reduction in recent years. CO₂ mineralization can use natural alkaline minerals or industrial alkaline solid waste for transforming acidic CO₂ gas into carbonate. Despite its promise, many reported CO₂ mineralization methods remain plagued by excessive energy consumption and cost. This study introduces an innovative, environmentally friendly, and energy-efficient air-driven membrane electrolysis technology, tailored for efficient CO₂ mineralization and the production of high-quality porous silica materials. The key advancement of this technology hinges on the simultaneous occurrence of the oxygen reduction reaction (ORR) and the oxygen evolution reaction (OER) at the anode and cathode, respectively, within the electrolytic environment. This unique feature results in low-energy water ionization, generating both alkaline and acidic solutions. Crucially, this developed electrolytic technology demonstrates a substantial reduction in electrolytic voltage, at least 0.5 V lower than conventional electrolytic processes under equivalent current densities. By combining the acidic solution from the anode with a moderately alkaline solution from the cathode to dissolve wollastonite, the resultant mixture yields high-quality porous silica. Subsequently, the filtrate and remaining alkaline solution at the cathode effectively absorb CO₂, yielding calcium carbonate as the mineralization product. This breakthrough technology offers a compelling pathway to efficient CO₂ utilization through mineralization, addressing both environmental concerns and energy efficiency challenges.

Key words: CO₂ capture, electrolysis, silica, electrochemistry, catalyst, CO₂ emission reduction

中图分类号:

TQ 151.1

高孝麟, 陈昌国. 空气驱动的膜电解技术促进硅灰石矿化CO₂产白炭黑的研究[J]. 化工学报, 2023, 74(11): 4739-4748.

Xiaolin GAO, Changguo CHEN. A study on production of silica from CO₂ mineralization by wollastonite promoted via air-driven membrane electrolysis technology[J]. CIESC Journal, 2023, 74(11): 4739-4748.

图/表 11

图1 CO2转化为其他含碳化合物的能量变化[12]

Fig.1 Gibbs energy change of CO2 translating into other carbon-containing compounds[12]

图2 氢气驱动的膜电解技术促进硅灰石矿化利用CO2产白炭黑工作原理[25]

Fig.2 The principle of silica production from CO2 mineralization by wollastonite promoted via H2-driven membrane electrolysis technology[25]

图3 电解水工艺（a）及锂-空气电池工艺(b)

Fig.3 The electrolysis of water technology (a) and lithium-air battery technology (b)

图4 空气驱动的膜电解技术促进硅灰石矿化CO2产白炭黑的原理

Fig.4 The principle of silica production from CO2 mineralization by wollastonite promoted via air-driven membrane electrolysis technology

图5 空气驱动的硅灰石矿化利用CO2联产白炭黑工艺路线

Fig.5 The process route of silica production from CO2 mineralization by wollastonite promoted via air-driven membrane electrolysis technology

图6 空气驱动的膜电解槽内部结构(a)及组装图(b)

Fig.6 The components (a) and assembly drawing (b) of the air-driven membrane electrolytic bath

图7 不同气体通入对膜电解的影响(a)及空气驱动的膜电解稳定性运行电压变化(b)

Fig.7 The effect of different gas injected on membrane electrolysis （a） and the voltage change of the air-driven membrane electrolysis stability test （b）

表1 电解过程阴阳极酸碱性变化及电解效率

Table 1 Changes of pH of anode and cathode and electrolytic efficiency in electrolytic process

电解时间/h	阴极理论碱浓度/(mol/L)	阴极实际碱浓度/（mol/L）	阴极pH	阴极电解效率/%	阳极理论酸浓度/(mol/L)	阳极实际酸浓度/(mol/L)	阳极pH	阳极电解效率/%
0	—	-0.0022	6.35	—	—	0.0022	6.35	—
1	0.0309	0.02977	8.24	96.34	0.0265	0.0263	1.86	99.25
2	0.0596	0.0564	8.54	94.63	0.0552	0.0537	1.17	97.28
3	0.0883	0.0804	8.69	91.05	0.0839	0.0770	1.02	93.78
4	0.1170	0.1009	8.83	86.24	0.1126	0.1002	0.95	88.99
5	0.1457	0.1150	8.92	78.93	0.1414	0.1182	0.77	83.59
6	0.1744	0.1218	9.01	69.84	0.1700	0.1293	0.69	76.06

图8 CaSiO3原料与SiO2产品XRD谱图对照（a）及不同pH下得到SiO2产品的BET吸脱附曲线（b）

Fig.8 XRD patterns of the product SiO2 and the raw material CaSiO3 (a) and the BET absorption-desorption curve of SiO2 prepared in different pH (b)

表2 不同pH下得到SiO2产品的比表面积、孔径和平均微粒尺寸

Table 2 The specific surface area， pore size and average particle size of SiO2 products obtained under different pH

制备过程pH	比表面积/(m²/g)	平均孔径/nm	平均微粒尺寸/nm
2	50	9.7	119.3
4	88	8.3	64.7
6	241	8.0	24.8
8	255	5.7	23.5

图9 CaCO3产品XRD谱图（a）与SEM图[(b)、(c)]

Fig.9 XRD pattern（a） and SEM images[(b)，(c)] of the mineralized product CaCO3

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空气驱动的膜电解技术促进硅灰石矿化CO₂产白炭黑的研究

A study on production of silica from CO₂ mineralization by wollastonite promoted via air-driven membrane electrolysis technology

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