Electronic devices, single-board computer CPUs, and sensors that have been radiation-hardened and developed to be less prone to harm from radiation exposure and extremely high temperatures are known as rad-hard electronics. Radiation is undoubtedly a key design consideration for radiation-hardened electronics, but it is not the sole material for which radiation tolerance/survivability and radiation hardening testing are crucial.
Ordinary concrete is particularly vulnerable to neutron activation and radiation harm, and excessive radiation exposure can change the physical characteristics of concrete, rendering a concrete bunker structurally unsafe. Because of this risk, nuclear reactor facilities that won't be as vulnerable to high radiation levels must be designed and built using specialized radiation-tolerant concrete.
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| Radiation Hardened Electronics Market Size & Share Analysis Forecast, 2030 |
The market is being driven by the high demand for radiation-hardened components for airplanes, medical equipment, and nuclear power plants. This is why, the radiation-hardened electronics market is predicted to touch $2,104.2 million by 2030, progressing at a 3.5% CAGR from 2021 to 2030. Due to government efforts and investments made by entrepreneurs working in this domain internationally, the space industry is growing.
Get More Insights: Radiation Hardened Electronics Market Revenue Estimation and Growth Forecast Report
Reconfigurable radiation-hardened devices are in higher demand, which presents market opportunities for the participants. These tools enable satellite users to alter the scope of their operations while in orbit, significantly lowering the cost of reconfiguration. Top companies in the sector are involved in the creation of new software. electronics with specified radiation protection.
The demand for radiation-hardened electronics is mostly driven by the necessity of radiation-hardened electronics for space applications, and it will grow at the fastest pace in the coming years. This is mostly due to the growth in international ISR activities, which is pressuring companies to provide more durable and dependable electrical components for spacecraft. Additionally, the need for radiation-hardened electronics is being driven by the swelling data volume that is crowding the satellite spectrum due to the expanding worldwide internet user population.
The aerospace and defense industries are largely in need of radiation hardening and survival testing. Infrastructure and defense systems that must continue to operate in the wake of a nuclear explosion depend on radiation-hardened electronics because they must be tolerant of the high radiation levels caused by the explosion.
Additionally, such radiation-hardened electronics and systems must be free to operate in the case of secondary radiation impacts, including an electromagnetic pulse, which is a strong dosage of electromagnetic radiation. We need radiation-hardened electronics to be utilized in the design for that functionality to be sustained through an incident where such systems are exposed to high amounts of radiation.
The tremendous volumes of radiation that solar flares emit are one of the biggest risks to our aerospace and military satellite systems in orbit. Solar flares with sufficient energy can even damage electronics on Earth's surface, resulting in outages and system failures.
Due to the absence of an atmosphere to shield them, spacecraft like satellites, space stations, and shuttles are particularly susceptible to solar flares. Radiation hardening measures are essential for shielding human passengers from the effects of electromagnetic exposure to radiation as well as preventing damage to the electrical systems of spacecraft from space radiation.
