In this article, we will look at why hot water freezes faster than cold water.

Heated water freezes much faster than cold water! This amazing property of water, the exact explanation for which scientists still cannot find, has been known since ancient times. For example, even in Aristotle there is a description of winter fishing: fishermen inserted fishing rods into holes in the ice, and so that they would freeze faster, they poured warm water on the ice. The name of this phenomenon was named after Erasto Mpemba in the 60s of the XX century. Mnemba noticed the strange effect while making ice cream and turned to his physics teacher, Dr. Denis Osborn, for an explanation. Mpemba and Dr. Osborne experimented with water at different temperatures and concluded that almost boiling water begins to freeze much faster than water at room temperature. Other scientists have carried out their own experiments and each time they have obtained similar results.

Explanation of a physical phenomenon

There is no generally accepted explanation as to why this is happening. Many researchers suggest that it's all about the supercooling of a liquid, which occurs when its temperature drops below freezing. In other words, if water freezes at a temperature below 0°C, then supercooled water can have a temperature of, for example, -2°C and still remain liquid without turning into ice. When we try to freeze cold water, there is a chance that it will become supercooled at first, and will only harden after some time. In heated water, other processes take place. Its faster transformation into ice is associated with convection.

Convection- This is a physical phenomenon in which the warm lower layers of the liquid rise, and the upper, cooled ones, fall.

Many researchers have put forward and are putting forward their own versions as to why hot water freezes faster than cold water. It would seem a paradox - after all, in order to freeze, hot water first needs to cool down. However, the fact remains, and scientists explain it in different ways.

Major Versions

At the moment, there are several versions that explain this fact:

1. Since evaporation in hot water is faster, its volume decreases. A smaller amount of water of the same temperature freezes faster.
2. The freezer compartment of the refrigerator has a snow lining. A container containing hot water melts the snow underneath. This improves thermal contact with the freezer.
3. Freezing of cold water, unlike hot, begins from above. In this case, convection and heat radiation, and, consequently, heat loss worsen.
4. In cold water there are centers of crystallization - substances dissolved in it. With a small content of them in water, icing is difficult, although at the same time, its hypothermia is possible - when it has a liquid state at sub-zero temperatures.

Although in fairness it can be said that this effect is not always observed. Cold water often freezes faster than hot water.

At what temperature does water freeze

Why does water freeze at all? It contains a certain amount of mineral or organic particles. These, for example, can be very fine particles of sand, dust or clay. As the air temperature drops, these particles become centers around which ice crystals form.

The role of crystallization nuclei can also be performed by air bubbles and cracks in a container containing water. The rate of the process of turning water into ice is largely influenced by the number of such centers - if there are many of them, the liquid freezes faster. Under normal conditions, with normal atmospheric pressure, water passes into a solid state from liquid at a temperature of 0 degrees.

The essence of the Mpemba effect

The Mpemba effect is understood as a paradox, the essence of which is that, under certain circumstances, hot water freezes faster than cold water. This phenomenon was noticed by Aristotle and Descartes. However, it was not until 1963 that Erasto Mpemba, a schoolboy from Tanzania, determined that hot ice cream freezes in a shorter time than cold ice cream. He made such a conclusion while performing the task of cooking.

He had to dissolve sugar in boiled milk and, after cooling it, place it in the refrigerator to freeze. Apparently, Mpemba did not differ in special diligence and began to carry out the first part of the task late. Therefore, he did not wait for the milk to cool, and put it in the refrigerator hot. He was very surprised when it froze even faster than that of his classmates, who did the work in accordance with the given technology.

This fact interested the young man very much, and he began experiments with plain water. In 1969, the journal Physics Education published the results of research by Mpemba and Professor Dennis Osborn of the University of Dar es Salaam. The effect they described was given the name Mpemba. However, even today there is no clear explanation for the phenomenon. All scientists agree that the main role in this belongs to the differences in the properties of chilled and hot water, but what exactly is unknown.

Singapore version

Physicists from one of Singapore's universities were also interested in the question, which water freezes faster - hot or cold? A team of researchers led by Xi Zhang explained this paradox precisely by the properties of water. Everyone still knows the composition of water from school - an oxygen atom and two hydrogen atoms. Oxygen to some extent draws electrons from hydrogen, so the molecule is a certain kind of "magnet".

As a result, certain molecules in water are slightly attracted to each other and are united by a hydrogen bond. Its strength is many times lower than the covalent bond. Singaporean researchers believe that the explanation of the Mpemba paradox lies precisely in hydrogen bonds. If water molecules are placed very closely together, then such a strong interaction between molecules can deform the covalent bond in the middle of the molecule itself.

But when water is heated, the bound molecules move slightly away from each other. As a result, relaxation of covalent bonds occurs in the middle of the molecules with the return of excess energy and the transition to the lowest energy level. This leads to the fact that hot water begins to cool rapidly. At least, this is what the theoretical calculations carried out by Singaporean scientists show.

Instant Water Freeze - 5 Incredible Tricks: Video

The phenomenon of hot water solidifying at a faster rate than cold water is known in science as the Mpemba effect. Such great minds as Aristotle, Francis Bacon and Rene Descartes pondered over this paradoxical phenomenon, but for millennia no one has yet been able to offer a reasonable explanation for this phenomenon.

Only in 1963, a schoolboy from the Republic of Tanganyika, Erasto Mpemba, noticed this effect on the example of ice cream, but none of the adults gave him an explanation. Nevertheless, physicists and chemists seriously thought about such a simple, but so incomprehensible phenomenon.

Since then, different versions have been expressed, one of which was as follows: part of the hot water simply evaporates at first, and then, when a smaller amount remains, the water solidifies faster. This version, due to its simplicity, became the most popular, but scientists were not completely satisfied.

Now a team of researchers from the Nanyang Technological University in Singapore, led by chemist Xi Zhang, says they have solved the age-old mystery of why warm water freezes faster than cold water. As Chinese experts found out, the secret lies in the amount of energy stored in hydrogen bonds between water molecules.

As you know, water molecules are made up of one oxygen atom and two hydrogen atoms held together by covalent bonds, which at the particle level looks like an exchange of electrons. Another well-known fact is that hydrogen atoms are attracted to oxygen atoms from neighboring molecules - this forms hydrogen bonds.

At the same time, water molecules as a whole repel each other. Scientists from Singapore noticed that the warmer the water, the greater the distance between the molecules of the liquid due to the increase in repulsive forces. As a result, hydrogen bonds are stretched, and therefore store more energy. This energy is released when the water cools - the molecules approach each other. And the return of energy, as you know, means cooling.

As the chemists write in their article, which can be found on the arXiv.org preprint site, hydrogen bonds are stretched more strongly in hot water than in cold water. Thus, it turns out that more energy is stored in the hydrogen bonds of hot water, which means that more of it is released when cooled to sub-zero temperatures. For this reason, freezing is faster.

To date, scientists have solved this riddle only theoretically. When they present convincing evidence of their version, then the question of why hot water freezes faster than cold water can be considered closed.

Mpemba effect or why does hot water freeze faster than cold water? The Mpemba Effect (Mpemba Paradox) is a paradox that states that hot water under certain conditions freezes faster than cold water, although it must pass the temperature of cold water in the process of freezing. This paradox is an experimental fact that contradicts the usual ideas, according to which, under the same conditions, a hotter body needs more time to cool down to a certain temperature than a cooler body to cool down to the same temperature. This phenomenon was noticed at the time by Aristotle, Francis Bacon and Rene Descartes, but only in 1963, the Tanzanian schoolboy Erasto Mpemba found that a hot ice cream mixture freezes faster than a cold one. Erasto Mpemba was a student at Magambin High School in Tanzania doing practical cooking work. He had to make homemade ice cream - boil milk, dissolve sugar in it, cool it to room temperature, and then put it in the refrigerator to freeze. Apparently, Mpemba was not a particularly diligent student and procrastinated on the first part of the assignment. Fearing that he would not be in time by the end of the lesson, he put the still hot milk in the refrigerator. To his surprise, it froze even earlier than the milk of his comrades, prepared according to a given technology. After that, Mpemba experimented not only with milk, but also with ordinary water. In any case, already being a student at Mkwawa High School, he asked Professor Dennis Osborne from the University College in Dar es Salaam (invited by the director of the school to give a lecture on physics to students) about water: "If you take two identical containers with equal volumes of water so that in one of them the water has a temperature of 35 ° C, and in the other - 100 ° C, and put them in the freezer, then in the second the water will freeze faster. Why? Osborne became interested in this issue and soon in 1969, together with Mpemba, they published the results of their experiments in the journal "Physics Education". Since then, the effect they discovered is called the Mpemba effect. Until now, no one knows exactly how to explain this strange effect. Scientists do not have a single version, although there are many. It's all about the difference in the properties of hot and cold water, but it is not yet clear which properties play a role in this case: the difference in supercooling, evaporation, ice formation, convection, or the effect of liquefied gases on water at different temperatures. The paradox of the Mpemba effect is that the time during which the body cools down to the ambient temperature must be proportional to the temperature difference between this body and the environment. This law was established by Newton and since then has been confirmed many times in practice. In the same effect, water at 100°C cools down to 0°C faster than the same amount of water at 35°C. However, this does not yet imply a paradox, since the Mpemba effect can also be explained within known physics. Here are a few explanations for the Mpemba effect: Evaporation Hot water evaporates faster from a container, thereby reducing its volume, and a smaller volume of water at the same temperature freezes faster. Water heated to 100 C loses 16% of its mass when cooled to 0 C. The effect of evaporation is a double effect. First, the mass of water required for cooling is reduced. And secondly, the temperature decreases due to the fact that the heat of evaporation of the transition from the water phase to the vapor phase decreases. Temperature difference Due to the fact that the temperature difference between hot water and cold air is greater - hence the heat exchange in this case is more intense and hot water cools faster. Subcooling When water is cooled below 0 C, it does not always freeze. Under certain conditions, it can undergo supercooling while continuing to remain liquid at temperatures below the freezing point. In some cases, water can remain liquid even at a temperature of -20 C. The reason for this effect is that in order for the first ice crystals to begin to form, centers of crystal formation are needed. If they are not in liquid water, then supercooling will continue until the temperature drops enough that crystals begin to form spontaneously. When they start to form in the supercooled liquid, they will start to grow faster, forming an ice slush that will freeze to form ice. Hot water is most susceptible to hypothermia because heating it eliminates dissolved gases and bubbles, which in turn can serve as centers for the formation of ice crystals. Why does hypothermia cause hot water to freeze faster? In the case of cold water, which is not supercooled, the following occurs. In this case, a thin layer of ice will form on the surface of the vessel. This layer of ice will act as an insulator between the water and cold air and will prevent further evaporation. The rate of formation of ice crystals in this case will be less. In the case of hot water undergoing subcooling, the subcooled water does not have a protective surface layer of ice. Therefore, it loses heat much faster through the open top. When the supercooling process ends and the water freezes, much more heat is lost and therefore more ice is formed. Many researchers of this effect consider hypothermia to be the main factor in the case of the Mpemba effect. Convection Cold water begins to freeze from above, thereby worsening the processes of heat radiation and convection, and hence the loss of heat, while hot water begins to freeze from below. This effect is explained by an anomaly in the density of water. Water has a maximum density at 4 C. If you cool water to 4 C and put it at a lower temperature, the surface layer of water will freeze faster. Because this water is less dense than water at 4°C, it will stay on the surface, forming a thin cold layer. Under these conditions, a thin layer of ice will form on the surface of the water for a short time, but this layer of ice will serve as an insulator protecting the lower layers of water, which will remain at a temperature of 4 C. Therefore, further cooling will be slower. In the case of hot water, the situation is completely different. The surface layer of water will cool more quickly due to evaporation and a greater temperature difference. Also, cold water layers are denser than hot water layers, so the cold water layer will sink down, lifting the warm water layer to the surface. This circulation of water ensures a rapid drop in temperature. But why does this process not reach the equilibrium point? To explain the Mpemba effect from this point of view of convection, it would be assumed that the cold and hot layers of water are separated and the convection process itself continues after the average water temperature drops below 4 C. However, there are no experimental data that would confirm this hypothesis, that cold and hot water layers are separated by convection. Gases Dissolved in Water Water always contains gases dissolved in it - oxygen and carbon dioxide. These gases have the ability to lower the freezing point of water. When the water is heated, these gases are released from the water because their solubility in water at high temperature is lower. Therefore, when hot water is cooled, there are always fewer dissolved gases in it than in unheated cold water. Therefore, the freezing point of heated water is higher and it freezes faster. This factor is sometimes considered as the main one in explaining the Mpemba effect, although there are no experimental data confirming this fact. Thermal Conductivity This mechanism can play a significant role when water is placed in a freezer refrigerator in small containers. Under these conditions, it has been observed that the container with hot water melts the ice of the freezer underneath, thereby improving thermal contact with the wall of the freezer and thermal conductivity. As a result, heat is removed from the hot water container faster than from the cold one. In turn, the container with cold water does not melt snow under it. All these (as well as other) conditions have been studied in many experiments, but an unequivocal answer to the question - which of them provide a 100% reproduction of the Mpemba effect - has not been obtained. So, for example, in 1995, the German physicist David Auerbach studied the influence of supercooling of water on this effect. He discovered that hot water, reaching a supercooled state, freezes at a higher temperature than cold water, and therefore faster than the latter. But cold water reaches the supercooled state faster than hot water, thereby compensating for the previous lag. In addition, Auerbach's results contradicted earlier data that hot water is able to achieve more supercooling due to fewer crystallization centers. When water is heated, the gases dissolved in it are removed from it, and when it is boiled, some salts dissolved in it precipitate. So far, only one thing can be asserted - the reproduction of this effect essentially depends on the conditions under which the experiment is carried out. Precisely because it is not always reproduced. O. V. Mosin

It seems clear that cold water freezes faster than hot water, since under equal conditions hot water takes longer to cool and subsequently freeze. However, thousands of years of observations, as well as modern experiments, have shown that the opposite is also true: under certain conditions, hot water freezes faster than cold water. Science channel Sciencium explains this phenomenon:

As explained in the video above, the phenomenon where hot water freezes faster than cold water is known as the Mpemba effect, named after Erasto Mpemba, a student from Tanzania who made ice cream as part of a school project in 1963. The students had to bring the mixture of cream and sugar to a boil, let it cool, and then put it in the freezer.

Instead, Erasto set his mixture at once, hot, without waiting for it to cool. As a result, after 1.5 hours, his mixture was already frozen, but the mixtures of other students were not. Intrigued by the phenomenon, Mpemba began to study the issue with physics professor Denis Osborn, and in 1969 they published a paper saying that warm water freezes faster than cold water. This was the first peer-reviewed study of this kind, but the phenomenon itself is mentioned in the papers of Aristotle dating back to the 4th century BC. e. Francis Bacon and Descartes also noted this phenomenon in their studies.

The video lists several options for explaining what is happening:

1. Frost is a dielectric, and therefore frosty cold water stores heat better than a warm glass that melts ice in contact with it.
2. Cold water has more dissolved gases than warm water, and the researchers speculate that this may play a role in the rate of cooling, although it is not yet clear how.
3. Hot water loses more water molecules through evaporation, leaving fewer to freeze
4. Warm water can cool faster due to increased convective currents. These currents occur because the water in the glass first cools on the surface and sides, causing the cold water to sink and the hot water to rise. In a warm glass, convective currents are more active, which can affect the rate of cooling.

However, in 2016, a carefully controlled study was conducted, which showed the opposite: hot water froze much more slowly than cold water. At the same time, scientists noticed that a change in the location of a thermocouple - a device that determines temperature differences - by just a centimeter leads to the appearance of the Mpemba effect. A study of other similar work showed that in all cases when this effect was observed, there was a displacement of the thermocouple within a centimeter.