Don't like the second law of thermodynamics - that heat transfer has limits when trying to do work? Maybe you can just use a different one.

Rather than being an immutable fundamental law, researchers from University College London and the Universities of Gdansk, Singapore, and Delft write in Proceedings of the National Academy of Sciences that they have uncovered additional second laws of thermodynamics which complement the ordinary second law of thermodynamics, they are just not noticeable except on very small scales. 

The ordinary second law states that the universe is in a growing state of disorder. It tells us that a hot cup of tea in a cold room will cool down rather than heat up; that even the most efficient machines will lose some energy as heat; and more prosaically, that a house will gradually get messier over time rather than tidying itself.  But, they say, on very small scales there is actually a whole family of 'second laws', which can lead to unexpected and counterintuitive phenomena. 

"The traditional second law of thermodynamics is sometimes thought of as a statistical law that only holds when there is a vast numbers of particles that make up a system," said Professor Jonathan Oppenheim (UCL Physics&Astronomy), one of the authors of the study. "Even while individual parts of a system may become more ordered, the overall entropy of the total system (a measure of disorder) increases."

In a sense, the traditional second law only holds on average.


More of a guideline than a rule? Look for a new wave of perpetual motion, cold fusion, and Theory of Everything papers on the Internet. Image: Georgia State University

More recently, physicists have begun wondering whether the second law holds not just on average, for very large systems, but whether it holds for small individual systems, such as those with only a small number of particles. Surprisingly, the researchers found that not only does the second law hold at such small scales, but there are actually many other second laws at work. In other words, just like larger systems, small systems also tend to become more disordered. But there are additional second laws which constrain the way in which disorder can increase.

"These additional second laws, can be thought of as saying that there are many different kinds of disorder at small scales, and they all tend to increase as time goes on," said co-author Professor Michal Horodecki  of the University of Gdansk. 

The researchers found additional measures of disorder, all different to the standard entropy, which quantify different types of disorder. They showed that not only does entropy increase, but other types of disorder also have to increase.

"Statistical laws apply when we consider large numbers. For example, imagine we toss a coin thousands of times. In this case, we expect to see roughly equal numbers of heads as tails. However, this is not true when tossing the coin just a few times. It's possible we will find all the coins landing tails. Similar phenomena occur when considering systems made out of very few particles, instead of very many particles," said co-author Professor Stephanie Wehner of the University of Delft. "We can use tools from quantum information theory to understand the case when we don't have a large number of particles." 

Oppenheim added, "While a quantum house will get messier rather than tidier, like a normal house, our research shows that the ways in which it can get messier are constrained by a range of extra laws. Stranger still, the way these second laws interact with each other can even make it look like the traditional second law has been violated. For instance, a small system can spontaneously become more ordered when it interacts with another system which barely seems to change. That means some rooms in the quantum house may spontaneously become much tidier, while others only become messier but only imperceptibly."

The results of the study might give an improved understanding of how heat and energy is transformed on very small scales. This is expected to have wide applications in the design of small systems, including nanoscale devices, biological motors, and quantum technologies such as quantum computers.