Home Science & TechSecurity NASA Designed Electric Propulsion System Primed to Make Planetary Exploration Possible

NASA Designed Electric Propulsion System Primed to Make Planetary Exploration Possible

by ccadm


NASA has recently announced improvements in existing propulsion technology. Named the NASA-H71M sub-kilowatt Hall-effect thruster, the primary innovation lies in its miniaturization and integration of advanced high-power solar electric propulsion technologies into a low-power system suitable for small spacecraft aimed at enhancing planetary exploration. This news has quickly become a matter of discussion among both the research fraternity and space technology enthusiasts. 

The new NASA-H71M is a timely improvement to concurrent technology and has the potential to significantly accelerate small spacecraft adoption. Looking at the bigger picture, this innovation could help NASA regain its hegemony over space technology. It would enable NASA to commercialize its technological capabilities while collaborating with private players.

Interestingly, this news arrives at a crucial time in space technology as the push for smaller, more versatile spacecraft is growing significantly. This improved thruster could significantly lower the barriers to entry for space missions. Upon adoption, it will enable the execution of more complex missions using smaller spacecraft with tighter budgets and timelines

In this article, we will review the NASA-H71M sub-kilowatt Hall-effect thruster and its impact on space exploration and the spacecraft of the future.

The NASA-H71M Breakthrough

As evident, the H71M thruster’s capabilities are at the core of this innovation. This new electric propulsion system is designed for small spacecraft and aims to revolutionize two major aspects: planetary exploration and the extension of satellites’ operational lives. But in order to truly appreciate it, one needs to first understand what a Hall-effect thruster is.

Put simply, it’s a type of ion thruster that uses an electric field to accelerate ions to generate thrust. Unlike chemical rockets, Hall-effect thrusters rely on electricity—often from solar—panels and a propellant like xenon gas.  This method is highly efficient, providing more thrust per amount of propellant than traditional rockets. Also, this isn’t a new technology but a tried and tested tool for maintaining satellite orbits and positioning for decades. Therefore, this innovation is more of an incremental betterment as opposed to a new discovery. 

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The Defining Leap In Technology

The NASA-H71M is designed to operate on less than a kilowatt of power while handling an impressive amount of propellant over its lifetime. This capability enables the thruster to perform high-delta-v maneuvers—changes in velocity required for challenging missions, like escaping Earth’s orbit or slowing down to orbit another planet.

Small Spacecraft Will Lead The Way To Future Deep Space Missions

Traditionally, missions to the Moon or Mars have required large, heavy spacecraft launched by powerful rockets due to the need for high-delta-v maneuvers, crucial for escaping Earth’s gravity well and adjusting trajectories mid-mission. However, the NASA-H71M thruster will enable small probes to propel from low Earth orbit (LEO) to these destinations, facilitating in-depth scientific research and exploration. 

The H71M  will allow smaller spacecraft to undertake these missions independently, which is crucial, as it means that future missions can be more frequent and less costly, opening up new opportunities for scientific discovery. For instance, a small probe could change its course to study a passing comet or asteroid. 

Additionally, the spacecraft will also be able to maneuver to target specific scientific interests, ranging from sampling lunar water ice to exploring Martian geology. This capability can provide valuable data on the solar system’s origins and evolution.

Adding to it, the improvised propellant efficiency and operational duration of the H71M will allow for prolonged missions. This will, in turn, extend beyond the perceived use case of understanding celestial bodies. It includes improving our capabilities in remote robotic operations, something instrumental for future human-crewed missions.

Commercializing Space Innovation

The adoption of the H71M thruster in space exploration missions is set to disrupt the commercial space sector. Its high efficiency and longevity make it ideal for satellite operators who require reliable, long-duration orbital adjustments and station-keeping capabilities. This technology is also expected to reduce the cost and complexity of satellite maintenance. These factors will significantly improve the economic viability of satellites, especially in geosynchronous and medium Earth orbits.

Northrop Grumman NGHT-1X engineering model Hall-effect thruster

Companies like Northrop Grumman, through its subsidiary SpaceLogistics, are set to leverage NGHT-1X Hall-effect thrusters based on the NASA-H71M sub-kilowatt Hall-effect thruster developed at NASA Glenn Research Center to develop their Mission Extension Pods. These Pods will be designed to attach to older satellites to extend their operational lives, correcting their orbits and boosting them to higher altitudes as needed. This use case stands as a testament to the H71 M’s commercial potential. 

These developments are set to create a new service model for satellite operators—a model that boosts the sustainability of space infrastructures.

Notably, the commercialization of such technologies often accelerates innovation by linking incentives to outcomes. More space companies are likely to evolve and develop new business models based on the improved capabilities of the smaller spacecraft. If successful, this advancement will be a major success for NASA’s efforts to encourage collaboration between space exploration and private industry. 

As companies innovate, they will contribute to the increasingly competitive space technology marketplace, which can drive down costs and create more opportunities for space access.

Fostering Collaborative Ecosystems

In a way, this development is a reflection of NASA’s strategic shift towards integrating commercial sector capabilities into its mission architectures. It aims to approach industry partners through licensing agreements and joint development initiatives.

This partnership model will accelerate the development of advanced technologies like the H71M and bolster the industrial complex, ensuring a national presence in space. The resultant collaborative ecosystem ensures that the benefits of NASA’s groundbreaking innovations permeate beyond the agency’s walls, catalyzing progress on a global scale.

These collaborations are also critical for testing and refining new technologies. Based on the news, we can conclude that NASA aims to leverage private sector efficiencies and innovative thinking to drive better technological outcomes. These partnerships will also help NASA achieve its broader strategic goals, which include creating and nurturing a sustainable economic environment in low-earth orbit space missions and beyond.

This mutually beneficial arrangement is set to accelerate the technology’s maturation by providing invaluable real-world data to inform further advancements. Ultimately, we are slated to experience an environment where public and private entities can leverage each other’s strengths to push the boundaries of what’s possible in space.

Redefining Space Exploration Roadmaps

The operational capabilities of the H71M thruster are set to redefine NASA’s roadmaps for space exploration. With this technology, NASA can plan more flexible and diverse mission profiles. Small spacecraft equipped with the H71M will be able to undertake independent missions to study celestial bodies like planets, moons, and asteroids at a more economical cost structure.

This flexibility will also allow NASA to respond quickly to unique scientific opportunities. These include applications like intercepting interstellar objects passing through our solar system or deploying targeted missions to investigate solar phenomena. Thus, the rapid, economical responses facilitated by the H71M will ensure that NASA remains at the forefront of space science and exploration, capable of capitalizing on transient scientific events.

Summing Up

As evident, the H71M Hall-effect thruster will set new standards for what is achievable in space exploration for a bigger variety of stakeholders. 

However, what makes this innovation special is the fact that NASA’s collaborative approach will democratize space access and extend it to a diverse range of stakeholders, from academic institutions to private enterprises. 

It will equally benefit parties exploring both scientific inquiry and commercial exploitation, allowing them to coexist in a harmonious, mutually beneficial ecosystem.

More than an engineering enhancement, the H71M thruster represents the human curiosity that has been enchanted by the limitless expanse of the universe since time immemorial. 

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