新加坡、英国和中国研究人员开发了一种新型复合材料，其从电子垃圾中提取黄金的效率是以前吸附剂的 10 倍。这种环保的复合材料由氧化石墨烯和一种称为壳聚糖的天然生物聚合物制成，它在没有外部电源的情况下过滤黄金，使其成为传统更耗能技术的更有吸引力的替代方案。从电子垃圾中提取黄金的效率更高，原因有两个。除了减少电子垃圾的体积外，它还可以减少我们对开采和精炼新黄金的依赖，而开采和精炼新黄金涉及环境有害物质，如活性炭和氰化物。然而，电子废物管理是一个相对较新的领域，现有的技术，如电解，既耗时又需要大量能量。

🤔 研究人员选择石墨烯和壳聚糖是因为它们都具有金提取的理想特性。石墨烯具有高表面积，使其成为吸附离子的理想材料，而壳聚糖充当天然还原剂，催化将离子金转化为固体金属形式。

🤩 为了制造这种复合材料，研究人员让一维壳聚糖大分子在二维氧化石墨烯薄片上自组装。这种组装过程会触发形成结合金离子的位点。复合材料增强的提取能力来自于离子结合是协同的，这意味着在一个位点结合的离子允许其他离子也结合。

🚀 研究人员在 SG Recycle Group SG3R, Pte, Ltd. 提供的真实废物混合物上测试了这种材料。使用这种混合物，其中金的残留浓度仅为 3 ppm，他们表明该复合材料可以从溶液中提取近 17g/g 的 Au3+ 离子，以及略高于 6 g/g 的 Au+，该数值是现有金吸附剂的 10 倍。该材料的提取效率也超过 99.5% 的重量 (wt%)，突破了目前的 75 wt% 的限制。最重要的是，离子提取过程非常快，大约只需要 10 分钟，而其他石墨烯基吸附剂则需要几天时间。

✨ 研究人员表示，该复合材料结构的多维结构意味着不需要施加电压来吸附和还原金离子。相反，该技术完全依赖于金离子在异质氧化石墨烯/壳聚糖纳米约束通道上的化学吸附动力学以及在多个结合位点的化学还原。因此，这种新工艺为从电子垃圾中回收黄金提供了一种更清洁、更高效和环保的方法。

🌎 除了电子垃圾之外，这项技术还可以应用于更广泛的环境清洁工作，例如从污染的水源或工业废水中过滤重金属。“因此，它为减少生态系统中的金属污染提供了解决方案。”

A new type of composite material is 10 times more efficient at extracting gold from electronic waste than previous adsorbents. Developed by researchers in Singapore, the UK and China, the environmentally-friendly composite is made from graphene oxide and a natural biopolymer called chitosan, and it filters the gold without an external power source, making it an attractive alternative to older, more energy-intensive techniques.

Getting better at extracting gold from electronic waste, or e-waste, is desirable for two reasons. As well as reducing the volume of e-waste, it would lessen our reliance on mining and refining new gold, which involves environmentally hazardous materials such as activated carbon and cyanides. Electronic waste management is a relatively new field, however, and existing techniques like electrolysis are time-consuming and require a lot of energy.

A more efficient and suitable recovery process

Led by Kostya Novoselov and Daria Andreeva of the Institute for Functional Intelligent Materials at the National University of Singapore, the researchers chose graphene and chitosan because both have desirable characteristics for gold extraction. Graphene boasts a high surface area, making it ideal for adsorbing ions, they explain, while chitosan acts as a natural reducing agent, catalytically converting ionic gold into its solid metallic form.

While neither material is efficient enough to compete with conventional methods such as activated carbon on its own, Andreeva says they work well together. “By combining both of them, we enhance both the adsorption capacity of graphene and the catalytic reduction ability of chitosan,” she explains. “The result is a more efficient and suitable gold recovery process.”

High extraction efficiency

The researchers made the composite by getting one-dimensional chitosan macromolecules to self-assemble on two-dimensional flakes of graphene oxide. This assembly process triggers the formation of sites that bind gold ions. The enhanced extracting ability of the composite comes from the fact that the ion binding is cooperative, meaning that an ion binding at one site allows other ions to bind, too. The team had previously used similar methods in studies that focused on structures such as novel membranes with artificial ionic channels, anticorrosion coatings, sensors and actuators, switchable water valves and bioelectrochemical systems.

Once the gold ions are adsorbed onto the graphene surface, the chitosan catalyses the reduction of these ions, converting them from their ionic state into solid metallic gold, Andreeva explains. “This combined action of adsorption and reduction makes the process both highly efficient and environmentally friendly, as it avoids the use of harsh chemicals typically employed in gold recovery from electronic waste,” she says.

The researchers tested the material on a real waste mixture provided by SG Recycle Group SG3R, Pte, Ltd. Using this mixture, which contained gold in a residual concentration of just 3 ppm, they showed that the composite can extract nearly 17g/g of Au³⁺ ions and just over 6 g/g of Au⁺ from a solution – values that are 10 times larger than existing gold adsorbents. The material also has an extraction efficiency of above 99.5 percent by weight (wt%), breaking the current of limit of 75 wt%. To top it off, the ion extraction process is ultrafast, taking around just 10 minutes compared to days for other graphene-based adsorbents.

No applied voltage required

The researchers, who report their work in PNAS, say that the multidimensional architecture of the composite’s structure means that no applied voltage is required to adsorb and reduce gold ions. Instead, the technique relies solely on the chemisorption kinetics of gold ions on the heterogenous graphene oxide/chitosan nanoconfinement channels and the chemical reduction at multiple binding sites. The new process therefore offers a cleaner, more efficient and environmentally-friendly method for recovering gold from electronic waste, they add.

While the present work focused on gold, the team say the technique could be adapted to recover other valuable metals such as silver, platinum or palladium from electronic waste or even mining residues. And that is not all: as well as e-waste, the technology might be applied to a wider range of environmental cleaning efforts, such as filtering out heavy metals from polluted water sources or industrial effluents. “It thus provides a solution for reducing metal contamination in ecosystems,” Andreeva says.

Other possible applications areas, she adds, include sustainable decarbonization and hydrogen production, low-dimensional building blocks for embedding artificial neural networks in hardware for neuromorphic computing and biomedical applications.

The Singapore researchers are now studying how to regenerate and reuse the composite material itself, to further reduce waste and improve the process’s sustainability. “Our ongoing research is focusing on optimizing the material’s properties, bringing us closer to a scalable, eco-friendly solution for e-waste management and beyond,” Andreeva says.

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