Toward Photoactive Wallpapers Based on ZnO-Cellulose Nanocomposites

IF 4.4 4区 综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES
Naveed Ul Hassan Alvi, Neha Sepat, Samim Sardar, Magnus Berggren, Isak Engquist, Xavier Crispin
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Abstract

The quest for eco-friendly materials with anticipated positive impact for sustainability is crucial to achieve the UN sustainable development goals. Classical strategies of composite materials can be applied on novel nanomaterials and green materials. Besides the actual technology and applications also processing and manufacturing methods should be further advanced to make entire technology concepts sustainable. Here, they show an efficient way to combine two low-cost materials, cellulose and zinc oxide (ZnO), to achieve novel functional and “green” materials via paper-making processes. While cellulose is the most abundant and cost-effective organic material extractable from nature. ZnO is cheap and known of its photocatalytic, antibacterial, and UV absorption properties. ZnO nanowires are grown directly onto cellulose fibers in water solutions and then dewatered in a process mimicking existing steps of large-scale papermaking technology. The ZnO NW paper exhibits excellent photo-conducting properties under simulated sunlight with good ON/OFF switching and long-term stability (90 minutes). It also acts as an efficient photocatalyst for hydrogen peroxide (H2O2) generation (5.7 × 10−9 m s−1) with an envision the possibility of using it in buildings to enable large surfaces to spontaneously produce H2O2 at its outer surface. Such technology promise for fast degradation of microorganisms to suppress the spreading of diseases.

Abstract Image

基于ZnO纤维素纳米复合材料的光活性壁纸。
寻求对可持续性具有预期积极影响的环保材料对实现联合国可持续发展目标至关重要。复合材料的经典策略可以应用于新型纳米材料和绿色材料。除了实际的技术和应用之外,还应该进一步推进加工和制造方法,使整个技术概念可持续发展。在这里,他们展示了一种有效的方法,将纤维素和氧化锌(ZnO)这两种低成本材料结合起来,通过造纸工艺实现新型功能性和“绿色”材料。而纤维素是从自然界中提取的最丰富、最具成本效益的有机材料。ZnO价格低廉,以其光催化、抗菌和紫外线吸收性能而闻名。ZnO纳米线在水溶液中直接生长在纤维素纤维上,然后在模仿大规模造纸技术现有步骤的过程中脱水。ZnO NW纸在模拟阳光下表现出优异的光传导性能,具有良好的ON/OFF开关和长期稳定性(90分钟)。它还可以作为一种有效的过氧化氢(H2O2)生成光催化剂(5.7×10-9 m s-1),并设想在建筑物中使用它的可能性,使大表面能够在其外表面自发产生H2O2。这种技术有望使微生物快速降解,以抑制疾病的传播。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Global Challenges
Global Challenges MULTIDISCIPLINARY SCIENCES-
CiteScore
8.70
自引率
0.00%
发文量
79
审稿时长
16 weeks
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