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Beta Volta 电池市场 - 全球行业规模,份额,趋势,机会和预测,2018-2028 年按同位素类型,按形状,按最终用户行业,按地区,按竞争对手Betavoltaic Cell Market - Global Industry Size, Share, Trends, Opportunity and Forecasted, 2018-2028 By Isotopes Type, By Shape, By End User Industry, By Region, By Competition |
全球 BETA 伏打电池市场预计将稳步增长,并在 2023 年至 2028 年的预测期内以稳定的复合年增长率增长。
堆迭同位素层和能量转换层的设计已被纳入移动设备和移动应用的 BETA 电压电源中。 同位素层的半衰期为0.5~5年,发出能量为15~200keV的辐射。 Betavolta 电源旨在为便携式小工具提供足够的电力,使其在使用寿命内持续供电。 因此,随着人口的增加,移动终端的使用频率越来越高,对此类终端的需求也越来越大。 因此,预计未来太阳能电池市场将扩大并录得较大的复合年增长率。
医疗保健领域的显着采用极大地促进了贝塔伏打电池市场的扩张。 Betavoltaic 电池广泛用于外科和医疗保健应用。 除了起搏器和除颤器等心臟植入物,植入式医疗设备市场还提供多种选择。 几家医疗设备製造商已经表现出偏爱製造坚固,可扩展和便携式的低功耗设备,这些设备严重依赖贝塔伏特电池。 体内药物输送系统,神经刺激器,眼内/耳蜗植入物和输液泵的开发只是一些非常令人兴奋的领域。 体内电子医疗标籤和脑机接口系统也正在被BETA-伏特电池厂商考虑作为应用领域。 此外,在国防和军事领域也有很多应用前景。 BETA伏特电池有望在防篡改军事装备方面具有巨大的应用潜力。 该电池可以有效地为与国防领域 (FPGA) 相关的领域可编程门阵列的加密密钥供电。
我们继续鼓励人们对研究核电池和其他 BETA 伏打电池的新应用感兴趣。
核电池最大的行业问题是以随着时间的推移逐渐降低的速度提供能量。 此外,如果不使用产生的电力,它就会过期。 这是太阳能电池的薄弱环节,厂商一直不愿加紧发力。 因此,正在进行研究以通过提高太阳能电池的功率转换效率来最大限度地发挥太阳能电池的潜力。 这种电池作为一种将彻底改变小型设备市场的电池而受到越来越多的关注。 预计未来几年研发的进一步加强将支持这一转变。
2020 年 8 月,总部位于加利福尼亚州的 NDB 宣布了一种自充电核电池。 该电池据称具有惊人的 28,000 年寿命,特别是由于碳 14 核废料包裹在合成金刚石外壳中。 据 NDB 称,这种电池可以为各种小工具供电,包括电动汽车,相机,无人机,手机和其他移动设备,家用电器和医疗设备。
一家由布里斯託大学的学者创立的公司于 2020 年 9 月宣布了一项製造核金刚石 betavortic 电池的突破性战略。 借助 Arkenwright 旨在商业化的节能(基于钻石的)贝塔伏特电池技术,该设备的使用寿命可能长达数十年。 这种钻石 Betavoltaic 电池背后的想法是将放射性废物 Carbo-14 转化为一种自我维持的能源。 这种电池最终可能会取代直接供电设备的充电需求。
根据市场数据,TechSci Research 提供了一份根据公司特定需求定制的全球 Beta-Volta 电池市场报告。 该报告可以定制为:
Global Betavoltaic Cell Market is anticipated to grow at a steady pace in the forecast period, 2023-2028, and grow at a solid CAGR in the forecast period.
A betavoltaic device, also known as a betavoltaic cell or battery, is a form of nuclear battery that uses semiconductor junctions to convert beta particles (also known as electrons) generated from a radioactive source into electric current. Tritium, an isotope of hydrogen, is a frequent source. Betavoltaic systems employ a non-thermal conversion mechanism, turning the electron-hole pairs created by the ionization path of beta particles passing a semiconductor, comparing most nuclear power sources, which use nuclear radiation to generate heat which is then used to generate electricity. In low-power electrical applications, such as implanted medical devices or military and space applications, where longevity of the energy source is required, betavoltaic power sources (and the related technology of alpha voltaic power sources) are particularly compatible.
A stacked design of isotope layers and energy conversion layers is included in a betavoltaic power source for mobile devices and mobile apps. The half-lives of the isotope layers are between 0.5 and 5 years, and they produce radiation with energies ranging from 15 to 200 keV. The betavoltaic power source is set up to deliver enough power to run the portable gadget for the duration of its useful life. So, as the population grows, the need for mobile devices increases due to usage. Consequently, it is anticipated that the betavoltaic cell market will expand in the approaching year and register a significant CAGR in the projection.
Notable adoption by the healthcare sector has contributed significantly to the market expansion for betavoltaic cells. Betavoltaic batteries have a wide range of useful uses in the fields of surgery and healthcare. The market for implanted medical devices offers several options in addition to cardiac implantables like pacemakers and defibrillators. Several medical device manufacturing firms have shown a preference for creating robust, scalable, portable, low-power devices that rely heavily on betavoltaic cells. The development of in-vivo medication delivery systems, cerebral neurostimulators, intraocular and cochlear implants, and infusion pumps are only a few of the extremely appealing fields. Other possible application areas for betavoltaic battery manufacturers include in-vivo electronic medical tags and brain-to-computer interface systems. Additionally, there are many prospects in the fields of defense and military applications. Betavoltaic cells are anticipated to have a substantial potential application in tamper-proofing military equipment. These cells might effectively power the encryption keys in Realm Programmable Gate Arrays, which is relevant to the field of defense (FPGA).
Nuclear Batteries and Other New Applications for Betavoltaic Cells Continue to encourage interest in research.
The industry's biggest problem with nuclear batteries is that they provide energy at a rate that gradually decreases over time. Additionally, if the electricity created is not used, it expires. While this has always been the weak point of betavoltaic cells, manufacturers have had a difficult time upping the power. There has been significant, active research underway on improving the power conversion efficiency of betavoltaic batteries to meet this challenge and unlock the full application potential of these batteries. These cells are increasingly seen as the batteries that will bring a revolutionary change in the tiny device market. Further strengthening R&D initiatives are anticipated to support this transformation in the upcoming years.
In August 2020, the California-based NDB company released a nuclear battery that can recharge on its own. The battery supposedly lasts an astounding 28,000 years, especially with the carbon-14 nuclear waste that has been encapsulated in an artificial diamond casing. According to NDB, the battery can power a variety of gadgets, including electric cars, cameras, drones, cellphones, other mobile devices, household appliances, and medical devices.
A company founded by the University of Bristol academics presented a revolutionary strategy to produce nuclear diamond betavoltaic batteries in September 2020. A device's lifespan might possibly reach decades because of the energy-efficient (diamond-based) betavoltaic battery technology that Arkenlight Limited is working to commercialize. The idea behind this diamond betavoltaic battery is to turn the radioactive waste carbo-14 into a self-sustaining energy source. These batteries may eventually replace the necessity of the need for charging in directly powered devices.
The Global Betavoltaic Cell Market is divided by isotope type, shape, and end-user industry. Based on Isotopes Type, the market is divided into Tritium, Strontium, Krypton, Nickel, and Others. Based on Shape, the market is segmented into Rectangular and Cylindrical. Based on the End User Industry, the market is divided into Aerospace, Electronics & Communication, Healthcare, Defense, and Others.
Major market players in the Global Betavoltaic Cell Market are: Widetronix Inc, Qynergy Corporation, City Labs Inc, BetaBatt Inc, Arkenlight, Direct Kinetic Solutions, and NDB Inc.
In this report, the Global Betavoltaic Cell Market has been segmented into the following categories, in addition to the industry trends, which have also been detailed below:
Company Profiles: Detailed analysis of the major companies present in the Global Betavoltaic Cell Market.
Global Betavoltaic Cell market report with the given market data, TechSci Research offers customizations according to a company's specific needs. The following customization options are available for the report: