Scientists develop laser guided system that could send a spacecraft to Mars in 45 days

NASA predicts it would take about 500 days for humans to reach the Red Planet, but Canadian engineers say a laser-based system could cut that journey to just 45 days.

The US space agency is planning to send a crew to the Red Planet in the middle of the 2030s, around the same time China also plans to land humans on Mars. 

Engineers from McGill University, in Montreal, Canada, say they have developed a ‘laser-thermal propulsion’ system, where lasers are used to heat hydrogen fuel.

It is directed-energy propulsion, using large lasers fired from Earth to deliver power to photovoltaic arrays on a spacecraft, that generate electricity, and in turn thrust.

The spacecraft accelerates very quickly while near Earth, then races towards Mars over the next month, releasing the main vehicle to land on the Red Planet and returning the rest of the vehicle to Earth to be recycled for the next launch.

Reaching Mars in just six weeks is something previously only thought possible using nuclear fission powered rockets, which present increased radiation risks.

Speaking to Universe Today, the team behind the study said this system could allow for rapid transport within the solar system.

Directed-energy propulsion isn’t a new idea, it has hit the headlines recently with Breakthrough Starshot, a project aiming to use lasers to send tiny lightsail probes to the nearest star system, Proxima Centauri at relativistic speeds.

The system uses laser beams to propel a spacecraft into deep space, at relativistic speeds – a fraction of the speed of light – with the more powerful the laser, the faster the spacecraft can be accelerated. 

Some research predicts it could send a 200lb satellite to Mars in just three days, with a more massive spacecraft requiring about a month to six weeks.

The concepts require a gigawatt-power laser array on Earth, that can be fired into space, directed at a light sail attached to a spacecraft to accelerate it to rapid speeds – at a fraction of the speed of light.

Emmanuel Duplay, a McGill graduate and MSc Aerospace Engineering student at TU Delft, published a paper suggesting this could be applied to a trip to Mars.

He told Universe Today: ”The ultimate application of directed-energy propulsion would be to propel a lightsail to the stars for true interstellar travel, a possibility that motivated our team that did this study. 

‘We were interested in how the same laser technology could be used for rapid transit in the solar system, which will hopefully be a nearer-term steppingstone that can demonstrate the technology.’

The hypothetical spacecraft the team created would require a 32ft diameter, 100 megawatt array of lasers, to be built somewhere on the Earth.

This would, given the current trend in the development of photonic laser technology, be enough to power a spacecraft headed for Mars.

It works by focusing the laser into a hydrogen heating chamber via an inflatable reflector – the hydrogen propellent is exhausted through a nozzle to drive it forward.

‘Our approach would use a much more intense laser flux on the spacecraft to directly heat propellant, similar to a giant steam kettle,’ said Duplay. 

‘This permits the spacecraft to accelerate rapidly while it is still near earth, so the laser does not need to focus as far into space.’ 

‘Our spacecraft is like a dragster that accelerates very quickly while still near Earth,’ Duplay explained,’ and the approach could help get it back from Mars, where there won’t be a large laser array, ready to send it on its way. 

‘We believe we can even use the same laser-powered rocket engine to bring the booster back into earth orbit, after it has thrown the main vehicle to Mars, enabling it to be quickly recycled for the next launch,’ he told Universe Today. 

The inflatable reflector is key to the technology working properly, as it would be designed to be very reflective so it can sustain a greater laser power per unit area than a photovoltaic panel.

This is what makes the mission feasible with a relatively modest – 32 ft diameter – laser array on the Earth. 

By reducing time in space, astronauts face lower levels of radiation, which could make a trip to Mars and back considerably safer.

All of the new elements would be required to allow spacecraft to get to Mars in six weeks – significantly less than the nine months predicted by NASA. 

‘Arrays of fiber-optic lasers that act as a single optical element, inflatable space structures that can be used to focus the laser beam when it arrives at the spacecraft into the heating chamber,’ is essential, said Duplay.

Also ‘the development of high-temperature materials that allow the spacecraft to break against the Martian atmosphere upon arrival.’

Being able to break against the atmosphere is the trick that will allow for return.  

The problem is that many of these technologies are still in their infancy, and haven’t been tested in the real world – raising questions over its viability by 2035. 

‘The laser heating chamber is likely the most significant challenge,’ Duplay told Universe Today, questioning whether hydrogen gas could be contained.

Asking whether it could be contained as ‘it is being heated by the laser beam to temperatures greater than 10,000 K while at the same time keeping walls of the chamber cool?’

‘Our models say this is feasible, but experimental testing at full scale is not possible at present because we have not yet built the 100 MW lasers needed.’  

Professor Andrew Higgins from McGill, who supervised the work of Duplay, said: ‘The ability to deliver energy deep into space via laser would be a disruptive technology for propulsion and power. 

‘Our study examined the laser thermal approach, which looks encouraging, but the laser technology itself is the real game changer.’

The findings have been published in pre-print on  arXiv.