Just how close are scientists to building Star Trek’s U.S.S. Enterprise? The future is now!
Launched into space from the mind of creator Gene Roddenberry in the 1960s, the U.S.S Enterprise NCC-1701 was the very first Star Trek spacecraft to reach warp speed on television screens around the world. The time-travelling, ultra-fast and near-invisible “Constitution-class” starship was the most advanced spacecraft at the time of its launch in 2245.
Built-in space, the U.S.S Enterprise was a feat of fictional engineering. It’s estimated that the spacecraft would weigh around more than four million tonnes in weight and house a crew of 430. In comparison, the heaviest man-made object to venture into space is the International Space Station (ISS), which has a mass of around 419 tonnes. However, C̳h̳i̳n̳a̳ is reportedly researching the possibility of constructing a colossal spacecraft measuring up to 0.6 miles (0.96km) in length, the ISS is only 360 feet (110 meters) long.
Engineers still have 233 years until humankind reaches Roddenberry’s vision for space exploration and several scientific breakthroughs suggest that we might be heading towards a spaceship that’s reminiscent of the U.S.S. Enterprise.
As a Constitution-class Starfleet Federation starship, the main role of the Enterprise was to venture on intergalactic exploration and diplomatic missions. To assist them on their journeys of discovery, the Enterprise was equipped with an array of advanced scanners and sensors. Before descending upon foreign land, the crew aboard the Enterprise firstly flipped a few stitches and scanned the planet below for signs of life. It’s a pretty handy gadget to have when discovering new life, but one that seems unrealistic. However, scientists are one step closer to making the technology a reality.
One of the most iconic abilities of the Enterprise is its ability to zip from one end of the galaxy to the next in mere moments, using its fictitious warp drive. Currently, humankind is nowhere near advanced enough to replicate the Enterprise’s warp drive. However, the theory behind building one has been around since the early 1990s.
To achieve speeds faster than the speed of light, physics’ natural speed limit, theoretical physicist Miguel Alcubierre proposed that we must bend the fabric of space-time. Space-time can be imagined as a sheet of rubber on which all matter sits, creating dips in the rubber relative to their mass.
Alcubierre proposed that if space-time could be folded in front of a spaceship and then expanded behind it, the ship could travel much faster than the speed of light and achieve “warp speed”. This bending of space-time would theoretically continue to move in a wave and act as a conveyor belt carrying the spaceship along it.
To achieve such space-time manipulation, Alcubierre suggested that an enormous amount of negative mass, a phenomenon rarely created in laboratories and seen as vacuum energy in space. The amount of negative mass needed to facilitate Alcubierre’s warp drive would have to be equivalent to the mass of a massive star distributed in a ring around a spacecraft. This hypothetical ring of negative mass would create a “warp bubble” which would distort space-time and transport any spacecraft within it.
Although Alcubierre’s theory required negative mass, recent research out of Göttingen University, Germany, offers a new area of physics for researchers to explore potentials for warp power. In 2021, Physicist Erik Lentz hypothesised that positive mass and energy could also provide the necessary requirements to construct a warp bubble. Instead of a solid ring of negative mass detailed in Alcubierre’s theory, Lentz proposes that layering rings and risks of extremely dense fluid, similar to the composition of a neutron star’s interior, would yield the same result.
With the ability to bend space-time, those inside of the warp bubble could travel through space faster than the speed of light without breaking any physical laws. For example, much like the ability to walk freely in the belly of an airplane, the warp bubble would theoretically also allow a spaceship and its crew to move around without feeling the effects of warp speed.
There are several questions that remain unanswered about building a real-life warp capable vessel, such as how to control it’s direction and distance, as well as how do you exit a warp bubble?
In Star Trek, however, to fuel their warp drive and create enough energy to bend space-time, the U.S.S Enterprise uses the annihilation reaction between matter, in the form of deuterium (a real-world isotope of hydrogen), and antimatter, which is regulated by a fictional crystal called dilithium. The “electro-plasma” energy released from this reaction creates the necessary warp bubble to manipulate space-time and move.
The biggest hurdle to overcome in using annihilation reactions for energy is producing enough antimatter to power a warp drive.
As the name suggests antimatter is a mirrored and opposing version of matter, for example, an electron has a negative charge so its antimatter partner has the same mass but an opposite positive charge, called a positron. In order to create antimatter, particle accelerators, such as the Large Hadron Collider, which fire particles at one another to release antimatter.
However, there are several physical issues with antimatter as a fuel source. First, the yield of its production is very low. For example, the Fermi National Accelerator Laboratory (Fermilab) can only produce enough antimatter in an hour to power 1/1000 of a watt and therefore 100,000 Fermilabs would be required to power a single light bulb. Due to the fact that antimatter annihilates when it comes in contact with matter, storing it is near impossible as everything is made up of matter.
Researchers have also deduced ways to detect life forms on planets, allowing Star Trek’s scanning tech to also be brought from fiction to fact.
New research shows that light interacts differently with the biochemistry of living things compared to artificial material. This means that, while aboard a ship, scientists could observe how light interacts with the planet to theoretically identify if life is present.
Through this research and NASA’s recently announced Venus drones, sun-powered ships, and swarms of underwater micro-bots, the world of science fiction may be closer than we think.