So according to the paper you gave reference to, is the paradox resolved? Is the explanation accepted by scientists ?Nugatory said:That depends on exactly what you consider the "Mpemba effect" to be; there is no unambiguous and generally accepted definition of what it is. The wikipedia article on the Mpemba effect, along with its talk page (it is always wise to look at the talk page!) explains some of the issues here.
The original paper is here: http://arxiv.org/abs/1310.6514, and it's interesting in its own right.
As an aside, the Daily Mail is not in general an acceptable source here, and this article is an example of why. It's not even first-hand reporting; it's digesting without understanding (no competent science journalist could write a sentence that starts "The Mpemba Effect is the theory that...") a blog that in turn is trying to summarize the paper for a lay audience.
Did you read the first two words in Nugatory's response?Faiq said:So according to the paper you gave reference to, is the paradox resolved? Is the explanation accepted by scientists ?
Since there is no general agreement on if the effect even exists or if so, what it is, the closest you can get to a scientific community consensus is that when it occurs, it is probably an experimental artefact. In other word, it is something that shouldn't happen if starting temperature is the only difference, so when it happens it is because starting temperature isn't the only difference.Faiq said:So according to the paper you gave reference to, is the paradox resolved? Is the explanation accepted by scientists ?
Right. The link in the OP shows a temperature/time graph that clearly shows the cold water sub-cooling, which delays and slows the freezing. In order for the cold water to experience sub-cooling and the heated water not, something else must be different. For example, maybe heating the water drives off dissolved gases that interfere with the crystallization. In either case, if both are treated the same, ie, boiled first, and then stuck in the freezer at different temperatures, the effect would not occur.rootone said:This concept has never made sense to me.
The water which is originally hotter must at some stage cool to be at the same temperature as the originally cooler water.
From that point it would then continue to cool in the same manner as the originally cooler water had done.
So given that all other conditions are the same, the time taken for the hotter water to cool to some given temperature cannot possibly be less than the cooler water.
It can only be longer because it first has to cool to the temperature that the originally cooler water started at.
Thank you, that was very helpfulruss_watters said:Since there is no general agreement on if the effect even exists or if so, what it is, the closest you can get to a scientific community consensus is that when it occurs, it is probably an experimental artefact. In other word, it is something that shouldn't happen if starting temperature is the only difference, so when it happens it is because starting temperature isn't the only difference.
The Mpemba effect is a phenomenon where hot water can freeze faster than cold water under certain conditions. It was first observed by a Tanzanian student, Erasto Mpemba, in the 1960s.
There have been numerous studies conducted on the Mpemba effect, but there is still no consensus among scientists on whether it is a real phenomenon or just a result of experimental errors. Some studies have supported the effect, while others have not been able to replicate it. Therefore, it remains a topic of debate in the scientific community.
There are several proposed explanations for the Mpemba effect, including evaporation, dissolved gases, supercooling, and convection. However, none of these theories have been able to fully explain the phenomenon, and more research is needed to understand it better.
While there have been some anecdotal reports of the Mpemba effect in everyday situations, it is not a common occurrence. The conditions needed for the effect to be observed are very specific, and it is difficult to replicate them in real-life scenarios.
The Mpemba effect challenges our understanding of thermodynamics and the conventional belief that cold water should freeze faster than hot water. It highlights the complexities of heat transfer and the need for more research to fully understand these processes. It also reminds us not to dismiss unusual observations and to continue questioning and exploring the world around us.