Comparing to different kinds of substance, the reason is different. But basicly because that between molecules of the acid, there is a force call hydrogen bond. It is not a chemical bond in the traditional sense, but more of a static electroforce. As the acetic acid base pulls electron from the hydrogen, electrons accumulate around the base making it a negative atmosphere- or a "pole". And the core of the hydrogen atom is exposed. As the core of any atom is positively charged, it becomes another "pole". the "-" pole of one molecule will attract "+" poles from different molecules. This makes molecules difficult to break away. Thus, the high boilling point.
Glacial acetic acid freezes at 16.7°C because it is a concentrated form of acetic acid (usually 99-100% pure). The high concentration of acetic acid molecules in glacial acetic acid lowers its freezing point compared to diluted acetic acid solutions.
Glacial acetic acid doesn't have water in it. Acetic acid ordinarily would be in a solution. Acetic acid is a weak acid, but it can be very concentrated. Glacial acetic acid is a acetic acid of a high purity more then 99.75 %
Acetic acid can be converted to ethane through decarboxylation, where acetic acid undergoes thermal decomposition to produce carbon dioxide and ethane. This process typically requires high temperatures and pressure.
No, sulfuric acid and hydrofluoric acid do not completely evaporate at high temperatures. Each acid has its own boiling point, and only when heated to that specific temperature will it fully evaporate. Additionally, the properties of the mixture may affect their evaporation behavior.
Pure Acetic Acid has a freezing point of 260 K or 16.5 degrees. Hence at room temperature it is often in a frozen state. This gives the look of ice like crystals to it, reminding us of glaciers found in cold mountaneous regions. Hence the name glacial acetic acid.
Glacial acetic acid freezes at 16.7°C because it is a concentrated form of acetic acid (usually 99-100% pure). The high concentration of acetic acid molecules in glacial acetic acid lowers its freezing point compared to diluted acetic acid solutions.
Because of its high freezing point.
The active ingredient in aspirin is acetyl salicylic acid. This is an ester, and boiling it will hydrolyze the bond and break it down into acetic acid and salicylic acid.
Glacial acetic acid doesn't have water in it. Acetic acid ordinarily would be in a solution. Acetic acid is a weak acid, but it can be very concentrated. Glacial acetic acid is a acetic acid of a high purity more then 99.75 %
The boiling point of metalloids is not so high.
high boiling point low melting point
Acetic acid can be converted to ethane through decarboxylation, where acetic acid undergoes thermal decomposition to produce carbon dioxide and ethane. This process typically requires high temperatures and pressure.
Chromium has a high boiling point as opposed to nonmetals. Metals tend to have high boiling points.
No, sulfuric acid and hydrofluoric acid do not completely evaporate at high temperatures. Each acid has its own boiling point, and only when heated to that specific temperature will it fully evaporate. Additionally, the properties of the mixture may affect their evaporation behavior.
Pure Acetic Acid has a freezing point of 260 K or 16.5 degrees. Hence at room temperature it is often in a frozen state. This gives the look of ice like crystals to it, reminding us of glaciers found in cold mountaneous regions. Hence the name glacial acetic acid.
No, 68 is a low boiling point.
Yes, pure acetic acid (100%) and household acetic acid (10-20%)