The Space Travel of the Future?

EmDrive is at it again, it seems. Recently, Mike McCulloch, from Plymouth University in the U.K., unveiled a theory that aims to explain how this physics-breaking mode of travel could actually work. And his theory has some proponents of this method of transport rather excited.

But before we go into the newly proposed theory: A quick summary of what EmDrive actually is.

In short, EmDrive could allow us to explore our universe in ways that, today, we can only dream about…if it’s ever developed, that is. It works (or should work) thanks to microwaves. The claim is, you bounce microwaves back and forth inside a truncated cone, and the result will be a thrust toward the narrow end of the cone.

That seems simple enough, yes? After all, you are just converting kinetic energy into another form of energy.

Well, here is the kicker: The total momentum increases as the device begins to move. That is like placing yourself inside a box, pushing on the side, and generating thrust. Sounds silly, doesn’t it? Well, here is another kicker: To date, a number of teams around the world have built their own versions of the EmDrive. And they generate thrust…but only a tiny amount.

And, alas, we don’t know where this increased momentum comes from. Critics assert that this is a violation of the law of conservation of momentum (which is part of the fundamental physics that governs our universe). Moreover, scientists assert that there are other effects that could, in essence, be producing a false positive and generating this increased thrust.

To that end, a host of scientists have been trying to work out whether this is an anomaly or if it actually works (and if so, how). This is where McCulloch comes in.

A New idea

In short, the new theory is based on ideas regarding inertia and the way objects move under very small accelerations. It has to do with something called “the Unruh effect.” This asserts that an accelerating object experiences black body radiation, meaning that the universe warms up when you accelerate. And in this regard, according to McCulloch, inertia is the pressure the Unruh radiation exerts on an accelerating body.

As MIT notes, “at very small accelerations, the wavelengths of Unruh radiation become so large they can no longer fit in the observable universe. When this happens, inertia can take only certain whole-wavelength values and so jumps from one value to the next. In other words, inertia must quantized at small accelerations.”

Thus, the inertia of photons that are inside of the aforementioned truncated cone have to change as they bounce back and forth. And to conserve momentum, this must generate a thrust.

In an email interview, RIT astrophysicist Brian Koberlein summarizes:

The Unruh effect (basically) says that an accelerated object should see a thermal background due to background quantum fluctuations. The calculation of the Unruh effect is straightforward, and isn’t controversial. Unruh radiation is (basically) the idea that in the detection of this thermal background you can trigger the emission of real particles. In other words, can you create real radiation ‘out of the vacuum.’ So they are claiming Unruh radiation is real, and causing the EM effect.

So. Is this the solution we needed? Well, maybe not.