Cold or hot water. Video: which water freezes faster - hot or cold

Chemistry was one of my favorite subjects in school. Once a chemistry teacher gave us a very strange and difficult task. He gave us a list of questions that we had to answer in terms of chemistry. We were given several days for this task and were allowed to use libraries and other available sources of information. One of these questions concerned the freezing point of water. I don't remember exactly how the question sounded, but it was about the fact that if you take two wooden buckets of the same size, one with hot water, the other with cold water (at exactly the specified temperature), and place them in an environment with a certain temperature, which one will they freeze faster? Of course, the answer immediately suggested itself - a bucket of cold water, but it seemed to us too simple. But this was not enough to give a complete answer, we needed to prove it from a chemical point of view. Despite all my thinking and research, I could not draw a logical conclusion. On this day, I even decided to skip this lesson, so I never found out the solution to this riddle.

Years passed, and I learned a lot of everyday myths about the boiling point and freezing point of water, and one myth said: "hot water freezes faster." I looked at many websites but the information was too conflicting. And these were just opinions, unfounded from the point of view of science. And I decided to conduct my own experience. Since I couldn't find wooden buckets, I used a freezer, stovetop, some water, and a digital thermometer. I will talk about the results of my experience a little later. First, I will share with you some interesting arguments about water:

Hot water freezes faster than cold water. Most experts say that cold water will freeze faster than hot water. But one funny phenomenon (the so-called Memba effect), for unknown reasons, proves the opposite: Hot water freezes faster than cold water. One of several explanations is the evaporation process: if very hot water is placed in a cold environment, then the water will begin to evaporate (the remaining amount of water will freeze faster). And according to the laws of chemistry, this is not a myth at all, and most likely this is what the teacher wanted to hear from us.

Boiled water freezes faster than tap water. Despite the previous explanation, some experts argue that boiled water that has cooled to room temperature should freeze faster because boiling reduces the amount of oxygen.

Cold water boils faster than hot water. If hot water freezes faster, then cold water may boil faster! This is contrary to common sense and scientists argue that this simply cannot be. Hot tap water should actually boil faster than cold water. But by using hot water to boil, you don't save energy. You may use less gas or electricity, but the water heater will use the same amount of energy that is needed to heat cold water. (Solar power is a little different.) As a result of heating the water with a water heater, sediment may form, so the water will take longer to heat up.

If you add salt to water, it will boil faster. Salt increases the boiling point (and therefore lowers the freezing point - which is why some housewives add a little rock salt to ice cream). But in this case, we are interested in another question: how long will the water boil and whether the boiling point in this case can rise above 100 ° C). Despite what cookbooks say, scientists say that the amount of salt we add to boiling water is not enough to affect the time or temperature of the boil.

But here's what I got:

Cold water: I used three 100 ml glass beakers of purified water: one room temperature (72°F/22°C), one hot water (115°F/46°C), and one boiled (212 °F/100°C). I placed all three glasses in the freezer at -18°C. And since I knew that water would not immediately turn into ice, I determined the degree of freezing by the “wooden float”. When the stick, placed in the center of the glass, no longer touched the base, I believed that the water had frozen. I checked the glasses every five minutes. And what are my results? The water in the first glass froze after 50 minutes. Hot water froze after 80 minutes. Boiled - after 95 minutes. My Conclusions: Considering the conditions in the freezer and the water I used, I was unable to reproduce the Memba effect.

I also tried this experiment with previously boiled water cooled to room temperature. It froze in 60 minutes - it still took longer than cold water to freeze.

Boiled water: I took a liter of water at room temperature and put it on fire. She boiled in 6 minutes. Then I cooled it down to room temperature again and added it to the hot one. With the same fire, hot water boiled in 4 hours and 30 minutes. Conclusion: as expected, hot water boils much faster.

Boiled water (with salt): I added 2 large tablespoons of table salt to 1 liter of water. It boiled in 6 minutes 33 seconds, and as the thermometer showed it reached a temperature of 102°C. Undoubtedly, salt affects the boiling point, but not much. Conclusion: salt in water does not greatly affect the temperature and boiling time. I honestly admit that my kitchen is hard to call a laboratory, and perhaps my conclusions are contrary to reality. My freezer may freeze food unevenly. My glass glasses might be irregular, etc. But whatever happens in the laboratory, when it comes to freezing or boiling water in the kitchen, the most important thing is common sense.

link with interesting facts about waterall about water
as suggested on the forum.ixbt.com forum, this effect (the effect of freezing hot water faster than cold water) is called the "Aristotle-Mpemba effect"

Those. boiled water (chilled) freezes faster than "raw"

Which water freezes faster, hot or cold, is influenced by many factors, but the question itself seems a little strange. It is understood, and it is known from physics, that hot water still needs time to cool down to the temperature of comparable cold water in order to turn into ice. Cold water can skip this stage, and, accordingly, it wins in time.

But the answer to the question of which water freezes faster - cold or hot - on the street in frost, any inhabitant of the northern latitudes knows. In fact, scientifically, it turns out that in any case, cold water simply has to freeze faster.

So did the teacher of physics, who was approached by the schoolboy Erasto Mpemba in 1963 with a request to explain why the cold mixture of future ice cream freezes longer than a similar, but hot one.

"This is not world physics, but some kind of Mpemba physics"

At that time, the teacher only laughed at this, but Deniss Osborne, a professor of physics, who at one time went to the same school where Erasto studied, experimentally confirmed the existence of such an effect, although there was no explanation for this then. In 1969 a popular scientific journal published a joint article by the two men who described this peculiar effect.

Since then, by the way, the question of which water freezes faster - hot or cold, has its own name - the effect, or paradox, Mpemba.

The question has been around for a long time

Naturally, such a phenomenon has taken place before, and it was mentioned in the works of other scientists. Not only the schoolboy was interested in this question, but Rene Descartes and even Aristotle thought about it at one time.

Here are just approaches to solving this paradox began to look only at the end of the twentieth century.

Conditions for a paradox to occur

As with ice cream, it's not just ordinary water that freezes during the experiment. Certain conditions must be present in order to start arguing which water freezes faster - cold or hot. What influences this process?

Now, in the 21st century, several options have been put forward that can explain this paradox. Which water freezes faster, hot or cold, may depend on the fact that it has a higher evaporation rate than cold water. Thus, its volume decreases, and with a decrease in volume, the freezing time becomes shorter than if we take a similar initial volume of cold water.

Freezer has long been defrosted

Which water freezes faster, and why it does so, can be affected by the snow lining that may be present in the freezer of the refrigerator used for the experiment. If you take two containers that are identical in volume, but one of them will have hot water and the other cold water, the container with hot water will melt the snow under it, thereby improving the contact of the thermal level with the refrigerator wall. A cold water container can't do that. If there is no such lining with snow in the refrigerator, cold water should freeze faster.

Top - bottom

Also, the phenomenon of which water freezes faster - hot or cold, is explained as follows. Following certain laws, cold water starts to freeze from the upper layers, when hot water does it the other way around - it starts to freeze from the bottom up. It turns out that cold water, having a cold layer on top with ice already formed in some places, thus worsens the processes of convection and thermal radiation, thereby explaining which water freezes faster - cold or hot. A photo from amateur experiments is attached, and here it is clearly visible.

The heat goes out, tending upwards, and there it meets a very cool layer. There is no free path for heat radiation, so the cooling process becomes difficult. Hot water has absolutely no such barriers in its path. Which freezes faster - cold or hot, on which the probable outcome depends, you can expand the answer by saying that any water has certain substances dissolved in it.

Impurities in the composition of water as a factor influencing the outcome

If you do not cheat and use water with the same composition, where the concentrations of certain substances are identical, then cold water should freeze faster. But if a situation occurs when dissolved chemical elements are present only in hot water, while cold water does not possess them, then hot water has the opportunity to freeze earlier. This is explained by the fact that the dissolved substances in water create centers of crystallization, and with a small number of these centers, the transformation of water into a solid state is difficult. Even supercooling of water is possible, in the sense that at sub-zero temperatures it will be in a liquid state.

But all these versions, apparently, did not suit the scientists to the end, and they continued to work on this issue. In 2013, a team of researchers in Singapore said they had solved the age-old mystery.

A group of Chinese scientists claim that the secret of this effect lies in the amount of energy that is stored between water molecules in its bonds, called hydrogen bonds.

The answer from Chinese scientists

Further information will follow, for the understanding of which it is necessary to have some knowledge in chemistry in order to figure out which water freezes faster - hot or cold. As you know, it consists of two H (hydrogen) atoms and one O (oxygen) atom held together by covalent bonds.

But hydrogen atoms of one molecule are also attracted to neighboring molecules, to their oxygen component. These bonds are called hydrogen bonds.

At the same time, it is worth remembering that at the same time, water molecules act repulsively on each other. Scientists noted that when water is heated, the distance between its molecules increases, and this is facilitated by repulsive forces. It turns out that occupying one distance between molecules in a cold state, one can say that they stretch, and they have a greater supply of energy. It is this energy reserve that is released when water molecules begin to approach each other, that is, cooling occurs. It turns out that a larger supply of energy in hot water, and its greater release when cooled to sub-zero temperatures, occurs faster than in cold water, which has a smaller supply of such energy. So which water freezes faster - cold or hot? On the street and in the laboratory, the Mpemba paradox should occur, and hot water should turn into ice faster.

But the question is still open

There is only theoretical confirmation of this clue - all this is written in beautiful formulas and seems plausible. But when the experimental data, which water freezes faster - hot or cold, will be put in a practical sense, and their results will be presented, then it will be possible to consider the question of the Mpemba paradox closed.

The British Royal Society of Chemistry is offering a £1,000 reward to anyone who can scientifically explain why, in some cases, hot water freezes faster than cold water.

“Modern science still cannot answer this seemingly simple question. Ice cream makers and bartenders use this effect in their daily work, but no one really knows why it works. This problem has been known for millennia, philosophers such as Aristotle and Descartes have thought about it,” said the President of the British Royal Society of Chemistry, Professor David Philips, quoted in a press release from the Society.

How an African chef beat a British physics professor

This is not an April Fool's joke, but a harsh physical reality. Today's science, which easily operates on galaxies and black holes, building giant accelerators to search for quarks and bosons, cannot explain how elemental water "works". The school textbook unambiguously states that it takes more time to cool a hot body than to cool a cold body. But for water, this law is not always observed. Aristotle drew attention to this paradox in the 4th century BC. e. Here is what the ancient Greek wrote in the book "Meteorologica I": "The fact that the water is preheated contributes to its freezing. Therefore, many people, when they want to quickly cool hot water, first put it in the sun ... ”In the Middle Ages, Francis Bacon and Rene Descartes tried to explain this phenomenon. Alas, neither the great philosophers nor the numerous scientists who developed classical thermal physics succeeded in this, and therefore such an inconvenient fact was “forgotten” for a long time.

And only in 1968 they “remembered” thanks to the schoolboy Erasto Mpemba from Tanzania, far from any science. While studying at a cooking school, in 1963, 13-year-old Mpembe was given the task of making ice cream. According to the technology, it was necessary to 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 diligent student and hesitated. 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 all the rules.

When Mpemba shared his discovery with a physics teacher, he made fun of him in front of the whole class. Mpemba remembered the insult. Five years later, already a student at the University of Dar es Salaam, he was at a lecture by the famous physicist Denis G. Osborne. After the lecture, he asked the scientist a question: “If you take two identical containers with the same amount of water, one at 35 °C (95 °F) and the other at 100 °C (212 °F), and put them in the freezer, then water in a hot container will freeze faster. Why?" You can imagine the reaction of a British professor to a question from a young man from godforsaken Tanzania. He made fun of the student. However, Mpemba was ready for such an answer and challenged the scientist to a wager. Their argument culminated in an experimental test that proved Mpemba right and Osborne defeated. So the student-cooker inscribed his name in the history of science, and henceforth this phenomenon is called the "Mpemba effect". To discard it, to declare it as if "non-existent" does not work. The phenomenon exists, and, as the poet wrote, "not in the tooth with a foot."

Are dust particles and dissolved substances to blame?

Over the years, many have tried to unravel the mystery of freezing water. A whole bunch of explanations for this phenomenon have been proposed: evaporation, convection, the influence of solutes - but none of these factors can be considered definitive. A number of scientists devoted their entire lives to the Mpemba effect. James Brownridge, a member of the Department of Radiation Safety at the State University of New York, has been studying the paradox in his spare time for over a decade. After conducting hundreds of experiments, the scientist claims that he has evidence of the "guilt" of hypothermia. Brownridge explains that at 0°C, water only supercools, and begins to freeze when the temperature drops below. The freezing point is regulated by impurities in the water - they change the rate of formation of ice crystals. Impurities, and these are dust particles, bacteria and dissolved salts, have their characteristic nucleation temperature, when ice crystals form around the crystallization centers. When there are several elements in water at once, the freezing point is determined by the one with the highest nucleation temperature.

For the experiment, Brownridge took two samples of water at the same temperature and placed them in a freezer. He found that one of the specimens always freezes before the other - presumably due to a different combination of impurities.

Brownridge claims that hot water cools faster due to the greater temperature difference between the water and the freezer - this helps it reach its freezing point before cold water reaches its natural freezing point, which is at least 5°C lower.

However, Brownridge's reasoning raises many questions. Therefore, those who can explain the Mpemba effect in their own way have a chance to compete for a thousand pounds sterling from the British Royal Society of Chemistry.

Water is one of the most amazing liquids in the world, which has unusual properties. For example, ice - a solid state of liquid, has a specific gravity lower than water itself, which made the emergence and development of life on Earth in many ways possible. In addition, in the near-scientific, and indeed the scientific world, there are discussions about which water freezes faster - hot or cold. Whoever proves faster freezing of a hot liquid under certain conditions and scientifically substantiates his decision will receive an award of £1,000 from the British Royal Society of Chemists.

Background

The fact that, under a number of conditions, hot water is ahead of cold water in terms of freezing rate, was noticed back in the Middle Ages. Francis Bacon and René Descartes have put a lot of effort into explaining this phenomenon. However, from the point of view of classical heat engineering, this paradox cannot be explained, and they tried to bashfully hush it up. The impetus for the continuation of the dispute was a somewhat curious story that happened to the Tanzanian schoolboy Erasto Mpemba (Erasto Mpemba) in 1963. Once, during a dessert-making lesson at a cooking school, a boy, distracted by other things, did not have time to cool the ice cream mixture in time and put a solution of sugar in hot milk into the freezer. To his surprise, the product cooled somewhat faster than his fellow practitioners who observed the temperature regime for making ice cream.

Trying to understand the essence of the phenomenon, the boy turned to a physics teacher, who, without going into details, ridiculed his culinary experiments. However, Erasto was distinguished by enviable perseverance and continued his experiments no longer on milk, but on water. He made sure that in some cases hot water freezes faster than cold water.

Entering the University of Dar es Salaam, Erasto Mpembe attended a lecture by Professor Dennis G. Osborne. After graduation, the student puzzled the scientist with the problem of the rate of freezing of water depending on its temperature. D.G. Osborne ridiculed the very posing of the question, stating with aplomb that any loser knows that cold water will freeze faster. However, the natural tenacity of the young man made itself felt. He made a bet with the professor, offering to conduct an experimental test here, in the laboratory. Erasto placed two containers of water in the freezer, one at 95°F (35°C) and the other at 212°F (100°C). What was the surprise of the professor and the surrounding "fans" when the water in the second container froze faster. Since then, this phenomenon has been called the "Mpemba Paradox".

However, to date there is no coherent theoretical hypothesis explaining the "Mpemba Paradox". It is not clear what external factors, the chemical composition of water, the presence of dissolved gases and minerals in it, affect the rate of freezing of liquids at different temperatures. The paradox of the "Mpemba Effect" is that it contradicts one of the laws discovered by I. Newton, which states that the cooling time of water is directly proportional to the temperature difference between the liquid and the environment. And if all other liquids are completely subject to this law, then water in some cases is an exception.

Why does hot water freeze faster?t

There are several versions of why hot water freezes faster than cold water. The main ones are:

hot water evaporates faster, while its volume decreases, and a smaller volume of liquid cools faster - when water is cooled from + 100 ° С to 0 ° С, volume losses at atmospheric pressure reach 15%;
the intensity of heat exchange between the liquid and the environment is the higher, the greater the temperature difference, so the heat loss of boiling water passes faster;
when hot water cools, an ice crust forms on its surface, preventing the liquid from completely freezing and evaporating;
at a high temperature of water, its convection mixing occurs, reducing the freezing time;
gases dissolved in water lower the freezing point, taking energy for crystal formation - there are no dissolved gases in hot water.

All these conditions have been subjected to repeated experimental verification. In particular, the German scientist David Auerbach found that the crystallization temperature of hot water is slightly higher than that of cold water, which makes it possible to freeze the former more quickly. However, later his experiments were criticized and many scientists are convinced that the “Mpemba Effect” about which water freezes faster - hot or cold, can only be reproduced under certain conditions, which no one has been looking for and concretizing so far.

Hello, dear lovers of interesting facts. Today we will talk about. But I think that the question posed in the title may seem simply absurd - but should one always undividedly trust the notorious "common sense", and not a strictly set testing experience. Let's try to figure out why hot water freezes faster than cold water?

History reference

That in the issue of freezing cold and hot water “not everything is pure” was mentioned in the works of Aristotle, then similar notes were made by F. Bacon, R. Descartes and J. Black. In recent history, the name “Mpemba paradox” has been attached to this effect - after the name of a schoolboy from Tanganyika, Erasto Mpemba, who asked the same question to a visiting professor of physics.

The boy's question arose not from scratch, but from purely personal observations of the process of cooling ice cream mixtures in the kitchen. Of course, the classmates who were present there, together with the school teacher, laughed at Mpemba - however, after an experimental check by Professor D. Osborne personally, the desire to make fun of Erasto "evaporated" from them. Moreover, Mpemba, together with the professor, published a detailed description of this effect in Physics Education in 1969 - and since then the above name has been fixed in the scientific literature.

What is the essence of the phenomenon?

The setup of the experiment is quite simple: other things being equal, identical thin-walled vessels are tested, in which there are strictly equal amounts of water, differing only in temperature. The vessels are loaded into the refrigerator, after which the time is recorded before the formation of ice in each of them. The paradox is that in a vessel with an initially hotter liquid, this happens faster.

How does modern physics explain this?

The paradox has no universal explanation, since several parallel processes proceed together, the contribution of which may differ from specific initial conditions - but with a uniform result:

the ability of a liquid to supercool - initially cold water is more prone to hypothermia, i.e. remains liquid when its temperature is already below the freezing point
accelerated cooling - steam from hot water is transformed into ice microcrystals, which, when falling back, accelerate the process, working as an additional "external heat exchanger"
insulation effect - unlike hot water, cold water freezes from above, which leads to a decrease in heat transfer by convection and radiation

There are a number of other explanations (the last time the competition for the best hypothesis was held by the British Royal Society of Chemistry recently, in 2012) - but there is still no unambiguous theory for all cases of combinations of input conditions ...