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On September 4th, an asteroid was spotted heading towards Earth. Astronomers quickly determined that it would hit the planet in 10 hours. The island of Luzon in the Philippines was in the path of the asteroid, but thankfully, it was only a meter in size and harmless. Small asteroids like this strike the Earth regularly without causing any damage. However, larger asteroids pose a significant threat.

A 20-meter asteroid exploding in the sky could shatter windows and knock people off their feet. A 50-meter space rock could devastate a town, causing widespread damage and casualties. An asteroid measuring 140 meters would be catastrophic, destroying a city upon impact. For billions of years, Earth has faced these cosmic threats, but today there are measures in place to protect the planet.

Planetary defense is a field of applied science dedicated to safeguarding Earth from asteroid collisions. Scientists and engineers work tirelessly to detect and mitigate potential threats. One approach involves scanning the night sky to identify asteroids on a collision course with Earth. New telescopes are set to come online in the coming years, enhancing our ability to detect and track these space rocks.

There are two main strategies for planetary defense. The first involves deflecting or destroying incoming asteroids using technology. In 2022, NASA conducted the Double Asteroid Redirection Test (DART) mission, successfully deflecting a harmless asteroid. This experiment demonstrated that it is possible to alter the path of a potentially dangerous asteroid, protecting Earth from a catastrophic impact.

However, a key challenge in asteroid deflection is the need to accurately identify and track these objects. This is where the second aspect of planetary defense comes into play. While some teams focus on developing defense technologies, others are tasked with surveying the skies for near-Earth asteroids. Current optical astronomy methods have been effective in identifying larger asteroids but fall short in detecting smaller, potentially hazardous ones.

To address this limitation, new missions like NASA’s Near-Earth Object Surveyor (NEO Surveyor) and the Vera C. Rubin Observatory are being launched. These initiatives aim to enhance our asteroid detection capabilities using advanced technologies such as infrared imaging. By combining ground-based and space-based observatories, scientists hope to create a comprehensive catalog of near-Earth asteroids, reducing the risk of a catastrophic impact.

The NEO Surveyor mission, scheduled to launch within the next five years, will focus on identifying city-killer asteroids using infrared sensors. Meanwhile, the Rubin Observatory, equipped with a state-of-the-art digital camera, will scan the night sky for any celestial objects, including asteroids of various sizes.

By leveraging these cutting-edge technologies, researchers anticipate that by the 2040s, we will have a clearer understanding of potential asteroid threats to Earth. This proactive approach to planetary defense marks a significant shift in our relationship with space, empowering us to protect our planet from cosmic hazards.

As we continue to explore the universe and develop new technologies, we are taking proactive steps to ensure the safety and security of our planet. Planetary defense represents a crucial aspect of our efforts to make the cosmos a safer place for humanity. By staying vigilant and investing in advanced detection systems, we can mitigate the risks posed by asteroids and safeguard our planet for future generations.