Graphic depiction of Pellet-Beam Propulsion for Breakthrough Space Exploration.

Today, multiple space agencies are investigating cutting-edge propulsion ideas that will allow for rapid transits to other bodies in the Solar System. These include NASA’s Nuclear-Thermal or Nuclear-Electric Propulsion (NTP/NEP) concepts that could enable transit times to Mars in 100 days (or even 45) and a nuclear-powered Chinese spacecraft that could explore Neptune and its largest moon, Triton. While these and other ideas could allow for interplanetary exploration, getting beyond the Solar System presents some major challenges. 

As we explored in a previous article, it would take spacecraft using conventional propulsion anywhere from 19,000 to 81,000 years to reach even the nearest star, Proxima Centauri (4.25 light-years from Earth). To this end, engineers have been researching proposals for uncrewed spacecraft that rely on beams of directed energy (lasers) to accelerate light sails to a fraction of the speed of light. A new idea proposed by researchers from UCLA envisions a twist on the beam-sail idea: a pellet-beam concept that could accelerate a 1-ton spacecraft to the edge of the Solar System in less than 20 years. 

The concept, titled “Pellet-Beam Propulsion for Breakthrough Space Exploration,” was proposed by Artur Davoyan, an Assistant Professor of Mechanical and Aerospace Engineering at the University of California, Los Angeles (UCLA). The proposal was one of fourteen proposals chosen by the NASA Innovative Advanced Concepts (NIAC) program as part of their 2023 selections, which awarded a total of $175,000 in grants to develop the technologies further. Davoyan’s proposal builds on recent work with directed-energy propulsion (DEP) and light sail technology to realize a Solar Gravitational Lens.

Rocket Lab is scheduled to launch its Virginia Is For Launches mission later this evening. It will be the company’s first launch from Launch Complex 2 at Virginia Space’s Mid-Atlantic Regional Spaceport within NASA’s Wallops Flight Facility.

by Tim Sweezy 

While this will not be the first launch of Rocket Lab’s Electron booster, it will be the first time it will launch in the United States. Previously, the company launched 32 Electron missions from Launch Complex 1 in New Zealand. The company touts the fact that Electron is “the most frequently launched small orbital rocket globally, and now with two launch complexes combined, Rocket Lab can support more than 130 launch opportunities every year.”

Launch Complex 2 was designed to support up to 12 missions per year. Rocket Lab operates an Integration and Control Facility within NASA’s Wallops Research Park, which includes state-of-the-art payload integration cleanrooms, vehicle processing facilities, and a mission control center. The upcoming launch pad and production complex for the company’s large reusable Neutron launch vehicle will also be located at the Mid-Atlantic Regional Spaceport.

The rocket will reach supersonic speed within a minute of launch, with its main engine cutting off on the first stage around the two-and-a-half-minute mark. A few seconds later Stage 1 will separate from Stage 2, with Electron’s Stage 2 Rutherford engines igniting shortly after. The fairing will separate approximately three minutes post-launch, with the payload being deployed near the one-hour mark.