市场调查报告书
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2030 年银奈米粒子市场预测:按类型、合成方法、应用和地区分類的全球分析Silver Nanoparticle Market Forecasts to 2030 - Global Analysis By Type (Spherical Silver Nanoparticles, Rod Shaped Silver Nanoparticles, Triangular Silver Nanoparticles and Other Types), Synthesis Method, Application and By Geography |
根据 Stratistics MRC 的数据,2023 年全球银奈米粒子市场规模为 24 亿美元,预计在预测期内将以 17.6% 的复合年增长率增长,到 2030 年达到 76 亿美元。
银奈米颗粒表现出独特的性能,如抗菌、导电和光学性能,使其在各种产品和工艺中广受欢迎。此外,奈米银颗粒因其抗菌特性而被用于纺织产品中,以增强医用纺织品和运动服布料的性能。这些奈米颗粒的尺寸通常为 1 至 100 奈米,由于尺寸小、表面积与体积比高,因此具有独特的物理和化学性质。
根据美国国家生物技术资讯中心 (NCBI) 2020 年 7 月的一篇报导,这些生物参与透过生物合成生产银奈米粒子,使得该过程经济且环保。
纺织业需求不断增长
银奈米粒子具有显着的抗菌性能,因此在各种纺织品应用中需求量大。随着消费者越来越重视卫生和健康产品,纺织业正在寻求创新的解决方案,将抗菌功能嵌入到织物中,从而增加其吸引力。银奈米粒子提供了一种多功能解决方案,可以生产抑制细菌和真菌生长、减少异味并促进清洁的抗菌纺织品。此外,将银奈米颗粒纳入纺织产品中可以防止微生物劣化,延长产品寿命,并透过减少废弃物为永续做出贡献。
製造成本高
银奈米粒子的合成通常涉及复杂且资源集中的过程,包括专用设备、原材料以及对温度和pH等反应参数的精确控制。高成本可能会阻碍潜在员工的聘用,尤其是在成本效益至关重要的行业。不断创新以提高生产效率和降低成本对于奈米银在各个领域的广泛采用至关重要。然而,确保奈米颗粒生产的品质和一致性会带来额外的复杂性和成本。
奈米科技的进步
奈米技术透过实现奈米级材料的精确操纵和工程,彻底改变了材料科学,其中银奈米粒子表现出独特的性能。奈米技术研究的不断进步促进了创新合成方法的发展,提高了银奈米颗粒的生产效率和可扩展性。这些进步已经生产出具有尺寸、形状和表面化学等客製化特性的银奈米颗粒,以优化其在各种应用中的性能。
集聚问题
银奈米颗粒容易聚集或结块,从而减少其表面积并损害其在各种应用中的有效性。在合成、储存、加工和掺入最终产品的过程中可能会发生聚集,导致实现均匀分散和稳定性的挑战。这些问题不仅影响银奈米颗粒的性能和功能,还会增加生产成本并阻碍其在整个产业的广泛普及。解决聚集问题需要创新策略,例如表面改质、功能化和封装,以提高稳定性并防止颗粒聚集。
最初,由于银奈米颗粒的抗菌特性,其需求激增,导致其在消毒剂、个人防护设备和医疗保健产品等各种医疗应用中使用。全球供应链和製造流程的中断给满足这种不断增长的需求带来了挑战。经济不确定性和消费者支出减少对市场产生了负面影响,特别是在电子和纺织等行业,银奈米粒子用于导电和抗菌性能。然而,儘管存在这些挑战,随着人们对银奈米粒子益处的认识不断增强以及新应用的出现,疫情也刺激了在新的抗病毒技术中利用银奈米粒子的研究和开发工作,促进了市场未来的潜在成长。
球形银奈米粒子段预计在预测期内达到最大值
球形银奈米粒子部分在预测期内出现了显着增长,因为它具有高表面积与体积比,提高了其在抗菌涂层、催化作用和医疗程序等各种应用中的有效性。它们均匀的形状可以精确控制尺寸、分散性和表面化学等特性,这使得它们对研究和商业应用都有吸引力。此外,合成技术的进步正在提高製造的可扩展性和成本效率,进一步推动市场成长。随着业界越来越认识到球形银奈米颗粒的好处并投资于研发,该细分市场将不断扩大,并为整个银奈米颗粒市场的成长和多样化做出重大贡献。
生物合成领域预计在预测期内复合年增长率最高
作为一种永续且环境友善的製造方法,生物合成领域预计将在预测期内实现高速成长。与传统化学方法相比,利用细菌、真菌、植物和藻类等生物实体合成银奈米颗粒具有多种优势。这些优点包括减少能源消费量、减少有毒化学物质的使用、利用自然机制形成奈米颗粒的能力以及更高的纯度和均匀性。此外,生物合成技术通常会产生具有独特性质和功能的奈米颗粒,从而在医学、农业和环境修復等领域开闢了潜在的应用前景。
由于中国、印度和韩国等国家的快速工业化和都市化增加了电子、医疗保健和纺织等各个行业对先进材料的需求,亚太地区将在预测期内继续增长。此外,该地区强大的研发基础设施和政府推广奈米技术的倡议进一步支持了市场扩张。此外,随着严格的法规鼓励使用安全和永续的包装解决方案,银奈米颗粒正在成为该地区对抗微生物污染和维持食品新鲜度的一个引人注目的选择。
随着消费者越来越重视食品安全和长寿,以及製造商寻求创新解决方案来延长保质期并确保产品完整性,欧洲地区预计在预测期内将出现可观的增长。在这一领域,银奈米粒子提供了一种强大的解决方案,因为它们的小尺寸提供了与病原体接触的大表面积,并有效抑制其生长和增殖。在监管限制内使用时,银奈米粒子对人体的毒性较低,这使其成为增强食品包装材料的有吸引力的选择。这些因素正在推动该地区的成长。
According to Stratistics MRC, the Global Silver Nanoparticle Market is accounted for $2.4 billion in 2023 and is expected to reach $7.6 billion by 2030 growing at a CAGR of 17.6% during the forecast period. Silver nanoparticles exhibit unique properties including antimicrobial, conductive, and optical characteristics, making them highly sought after for a range of products and processes. Additionally, they are utilized in textiles for their antibacterial properties, enhancing the performance of fabrics in medical textiles and sportswear. These nanoparticles typically range in size from 1 to 100 nanometers and possess unique physical and chemical properties due to their small size and high surface area-to-volume ratio.
According to the July 2020 article by the National Center for Biotechnology Information (NCBI), the involvement of these living organisms in the production of silver nanoparticles through biological synthesis makes the process economic and environmentally friendly.
Rising demand in textile industry
Silver nanoparticles possess remarkable antimicrobial properties, making them highly sought-after for various textile applications. As consumers increasingly prioritize hygiene and health-conscious products, the textile industry seeks innovative solutions to embed antimicrobial features in fabrics, thereby enhancing their appeal. Silver nanoparticles offer a versatile solution, enabling the production of antimicrobial textiles that inhibit the growth of bacteria and fungi, reducing odor and promoting cleanliness. Moreover, the incorporation of silver nanoparticles in textiles extends the lifespan of products by preventing microbial degradation, thereby contributing to sustainability efforts through reduced waste.
High production costs
The synthesis of silver nanoparticles often involves complex and resource-intensive processes, including specialized equipment, raw materials, and precise control over reaction parameters such as temperature and pH. High costs can deter potential adopters, especially in industries where cost-effectiveness is paramount. The need for continuous innovation to improve production efficiency and reduce costs is essential for the widespread adoption of silver nanoparticles across various sectors. However, ensuring quality and consistency in nanoparticle production adds further complexity and cost.
Advancements in nanotechnology
Nanotechnology has revolutionized material science by enabling precise manipulation and engineering of materials at the nanoscale, where silver nanoparticles exhibit unique properties. The continual progress in nanotechnology research has facilitated the development of innovative synthesis methods, enhancing the production efficiency and scalability of silver nanoparticles. These advancements have led to the creation of silver nanoparticles with tailored characteristics, such as size, shape, and surface chemistry, optimizing their performance in various applications.
Agglomeration issues
Silver nanoparticles have a propensity to agglomerate or clump together, reducing their surface area and compromising their effectiveness in various applications. Agglomeration can occur during synthesis, storage, processing, or integration into end products, leading to challenges in achieving uniform dispersion and stability. These issues not only affect the performance and functionality of silver nanoparticles but also increase production costs and hinder their widespread adoption across industries. Addressing agglomeration requires innovative strategies such as surface modification, functionalization, or encapsulation to enhance stability and prevent particle aggregation.
Initially, there was a surge in demand for silver nanoparticles due to their antimicrobial properties, which were utilized in various medical applications such as disinfectants, personal protective equipment, and healthcare products. Disruptions in the global supply chain and manufacturing processes led to challenges in meeting this heightened demand. Economic uncertainties and reduced consumer spending affected the market negatively, particularly in industries such as electronics and textiles, where silver nanoparticles are utilized for their conductive and antibacterial properties. However, despite these challenges, the pandemic also stimulated research and development efforts in utilizing silver nanoparticles for novel antiviral technologies, driving potential future growth in the market as awareness of their benefits increases and new applications emerge.
The Spherical Silver Nanoparticles segment is expected to be the largest during the forecast period
Spherical Silver Nanoparticles segment has been experiencing notable growth during the anticipated period as it offers high surface area-to-volume ratios, enhancing their efficacy in various applications such as antimicrobial coatings, catalysis, and medical treatments. Their uniform shape allows for precise control over properties like size, dispersibility, and surface chemistry, making them attractive for research and commercial applications alike. Additionally, advancements in synthesis techniques have made production more scalable and cost-effective, further driving market growth. As industries increasingly recognize the benefits of spherical silver nanoparticles and invest in research and development, this segment is poised for continued expansion, contributing significantly to the overall growth and diversification of the silver nanoparticle market.
The Biological Synthesis segment is expected to have the highest CAGR during the forecast period
Owing to its sustainable and environmentally friendly production methods, Biological Synthesis segment is estimated to witness enhanced growth throughout the overcast period. Utilizing biological entities such as bacteria, fungi, plants, and algae to synthesize silver nanoparticles offers several advantages over traditional chemical methods. These include lower energy consumption, reduced use of toxic chemicals, and the ability to harness natural mechanisms for nanoparticle formation, resulting in higher purity and uniformity. Moreover, biological synthesis techniques often produce nanoparticles with unique properties and functionalities, expanding their potential applications in fields such as medicine, agriculture, and environmental remediation.
Due to the rapid industrialization and urbanization across countries like China, India, and South Korea have led to increased demand for advanced materials in various sectors such as electronics, healthcare, and textiles, Asia Pacific region is poised to hold enormous growth during the prognostication period of time. Additionally, the region's robust research and development infrastructure coupled with government initiatives promoting nanotechnology further fuel the market expansion. Furthermore, with stringent regulations encouraging the use of safe and sustainable packaging solutions, silver nanoparticles emerge as a compelling choice for combating microbial contamination and preserving food freshness in the region.
As consumers increasingly prioritize food safety and longevity, manufacturers seek innovative solutions to extend shelf life and ensure product integrity, Europe region is estimated to gain considerable growth over the prognosis period. In this region, silver nanoparticles offer a potent solution, as their small size provides a large surface area for contact with pathogens, effectively inhibiting their growth and proliferation. Silver nanoparticles exhibit low toxicity to humans when used within regulatory limits, making them an attractive option for enhancing food packaging materials. These elements are boosting the regional growth.
Key players in the market
Some of the key players in Silver Nanoparticle market include Advanced Nano Products, Ames Goldsmith Corporation, Cima NanoTech Inc, Meliorumtechnologies, INC, Nanogap Sub-Nm-Powder, S.A, Nanografi Co. Inc, Nanoshel LLC, Prime Nanotechnology Co.,Ltd and Solaris Nanosciences Corporation.
In August 2022, Advanced Nano Products (ANP), a Korean supplier of carbon battery nanomaterials used in electric vehicle battery production, will locate in Hardin County with a $49.6 million investment creating 93 high-wage jobs to supply battery producers including BlueOvalSK Battery Park. To encourage investment and job growth in the community, the Kentucky Economic Development Finance Authority (KEDFA) preliminarily approved a 10-year incentive agreement with the company under the Kentucky Business Investment program. The performance-based agreement can provide up to $2.6 million in tax incentives based on the company's investment of $49.6 million
In May 2020, US-based company nanoComposix, which provides silver nanoparticles, has signed a deal to expand product distribution to customers across India. nanoComposix deals with multiple nanoparticle products which are used in anti-microbials, optical displays, drug delivery, among other applications, and through this agreement, more silver nanoparticles will be incorporated.
10.1 Advanced Nano Products
10.2 Ames Goldsmith Corporation
10.3 Cima NanoTech Inc
10.4 Meliorumtechnologies, INC
10.5 Nanogap Sub-Nm-Powder, S.A
10.6 Nanografi Co. Inc
10.7 Nanoshel LLC
10.8 Prime Nanotechnology Co.,Ltd
10.9 Solaris Nanosciences Corporation