Why Add Salt Increase Boiling Point Water?

The usual sign we notice when boiling water is bubbly bubbles in the water. The bubble is formed when the water is heated to boiling.

Have you ever asked what is contained in bubbles in boiling water? Are bubbles formed in other boiling liquids other than water?

Bubble Composition formed when boiling water.

When it first begins to boil water, the bubbles that are seen are basically air bubbles. Technically, this is a bubble formed from dissolved gases that come out of the water, so that if the water is in a different atmosphere, the bubbles will consist of these gases.

Under normal conditions, the first bubble is mostly nitrogen with oxygen and less argon and carbon dioxide.

As the water continues to heat, the molecules get enough energy to transition from the liquid phase to the gas phase. This bubble is water vapor. The water vapor bubbles begin to form on the nucleation sites, which often appear like tiny air bubbles, so the water begins to boil and produces bubbles consisting of a mixture of water vapor and air.

Both air bubbles appear and the vapor bubbles become widespread, they rise on the surface because there is little pressure that drives them. You can also see that this bubble bubble gets bigger from time to time.

The bubbles are much larger by the time they reach the surface. As temperatures get higher and more and more water molecules change from solid to gas.

While air bubbles begin to appear and enlarge, these air bubbles will also shrink as water vapor changes become liquid again. This can be seen before the water is boiling and the water surface.

At the boiling surface of the water, this bubble can also break and will release water vapor molecules into the air or if the temperature is very low, then the number of air bubbles that change becomes liquid again and more.

The temperature in the crown may be much lower than the bottom part because the heat energy will be absorbed by water molecules as the phase changes from liquid to gas. This change takes place on the surface of boiling water.

If you let the boiling water cool again and then boil it back, it will not be able to see the air bubbles formed because the water has no more chance to dissolve the gas gas into it. This can raise the risk of safety when boiling water because the absence of air bubbles causes no overheating of water.

One misconception when boiling water is the resulting bubble containing hydrogen gas and oxygen. What really happens is when we boil water, there will only be a phase change from liquid to gas only while the chemical bond remains. The only oxygen present in the bubbles comes from the oxygen of air dissolved in the water.

Composition of bubbles in other liquids that boil. If boiling liquid other than water, the same effect will occur. The initial bubble will consist of any dissolved gas. As the temperature gets closer to the boiling point of the liquid, the bubbles will become the vapor phase of the substance.

Like salt, If the salt is added to boiling water, the boiling point of water will appear to increase. Temperature needs to be increased by about one and a half degrees Celsius for every 58 grams of dissolved salt per kilogram of water. This is an example of boiling point elevation. The property is not exclusive to water, it happens anytime to add a non-volatile solute (eg salt) to a solvent (eg water).

Boiling water is a molecule capable of overcoming the air vapor pressure around it to move from the liquid phase to the gas phase.

Several different processes occur when adding solutes that increase the amount of energy (heat) needed for water to make the transition.

When the salt is added to the water, sodium chloride dissociates into sodium and chlorine ions. In addition to affecting hydrogen bonds between water molecules, there are ion-dipole interactions to consider. Each water molecule is a dipole, which means one side (oxygen side) is more negative and the other side (hydrogen side) is more positive. Positively charged sodium ions parallel to the oxygen side of the water molecule, while the chlorine ion is negatively charged to the hydrogen side of the water molecule. The ion-dipole interactions are stronger than hydrogen bonds between water molecules, so more energy is needed to move water from the ion and enter the vapor phase.

Even without solutes, adding particles to water increases the boiling point because some of the solution pressure given to the atmosphere now comes from dissolved particles, not just solvent molecules (water). Water molecules require more energy to produce enough pressure to avoid fluid boundaries.

The more salts (or solutes) are added to water, the water will increase the boiling point. This phenomenon depends on the number of particles formed in the solution. The freezing point of depression is another colligative property that works in the same way, so if adding salt to water can lower the freezing point and also boost its boiling point as well.

• Salt

Salt is sodium chloride with the formula NaCl. Salt is present in seawater with considerable amounts so that salt can be obtained by evaporation from sea water. In some places, salt can be obtained from the soil, to purify it then the process of separation of the mixture. In addition to NaCl a lot of salt compounds used in daily chemical products such as soaps, fertilizers, drugs even as food additives.

Salt is formed from the reaction between the acid compound with the basic compound. This acid and base reaction is then called salting reaction. Salt is neutral so it has pH = 7.

• Properties of salt

Sodium chloride does not change the color of the red litmus to blue or the blue litmus to red, meaning the salt solution is neutral. In the laboratory salt can be made from the reaction between acid and base. The salt forming reaction of acids and bases is called: neutralization or neutralization reaction. The properties of salt include the following:

• Has a salty taste

• Can conduct electrical current

• Do not change the color of red and blue litmus paper

• Has a neutral pH of about 7

• Formed from acid residue with residual base

• Compounds comprising metal and nonmetallic elements, eg NaCl where sodium (Na) includes metal and cloride (CI) including nonmetallic elements.