herschel
Harmless
Posts: 4
Registered: 3-10-2015
Member Is Offline
Mood: No Mood
|
|
Diluting HCL produces heat
If I take 36% HCL and dilute it 50/50 with water, heat is produced. Why?
|
|
RocksInHead
Harmless
Posts: 39
Registered: 16-6-2016
Member Is Offline
Mood: Highly Nitrated
|
|
Because a reaction is taking place. While the H+ and Cl- ions are being dissolved in the water, water is taking some of those H+ ions to form a
complex- H3O+, a hydronium ion. This reaction is exothermic, hence why heat is produced when you dilute strong acid with water.
Hope this helps!
[Edited on 6-9-2016 by RocksInHead]
|
|
herschel
Harmless
Posts: 4
Registered: 3-10-2015
Member Is Offline
Mood: No Mood
|
|
Does this mean that in 36% HCL some of the HCL is dissolved without being dissociated?
|
|
vmelkon
National Hazard
Posts: 669
Registered: 25-11-2011
Location: Canada
Member Is Offline
Mood: autoerotic asphyxiation
|
|
No, when you dissolve HCl in water, it is 100% dissociated. It is considered a strong acid.
Adding more water probably causes a hydration reaction (Cl- gets surrounded by more H2O).
Signature ==== Is this my youtube page? https://www.youtube.com/watch?v=tA5PYtul5aU
We must attach the electrodes of knowledge to the nipples of ignorance and give a few good jolts.
Yes my evolutionary friends. We are all homos here.
|
|
DraconicAcid
International Hazard
Posts: 4334
Registered: 1-2-2013
Location: The tiniest college campus ever....
Member Is Offline
Mood: Semi-victorious.
|
|
Whenever you mix two liquids, there will be some heat absorbed or generated. You are breaking some intermolecular attractions between the original
liquids, and forming new ones between the two liquids. These will be of different strengths (unless it's an ideal solution), so some energy will be
lost or absorbed.
There doesn't have to be a reaction for this to take place- ethanol and water will have a measurable temperature change when mixed (I know this,
because I remember having my students measure it one year).
Please remember: "Filtrate" is not a verb.
Write up your lab reports the way your instructor wants them, not the way your ex-instructor wants them.
|
|
woelen
Super Administrator
Posts: 8014
Registered: 20-8-2005
Location: Netherlands
Member Is Offline
Mood: interested
|
|
I disagree with
vmelkon. In 36% HCl, some of the HCl indeed is not ionized and exists as molecules of HCl. The major part is ionized, but maybe 10% or so still exists
as HCl. This also is the reason why 36% HCl fumes heavily. Ionized HCl cannot escape the liquid, only neutral molecules of HCl can escape it.
The same is true for 65% nitric acid. Part of it exists as covalent molecules HNO3. That is why 65% nitric acid is such an energetic oxidizer. Nitrate
ions hardly are oxidizing in water, it is the molecule HNO3 which is.
|
|
j_sum1
Administrator
Posts: 6325
Registered: 4-10-2014
Location: At home
Member Is Offline
Mood: Most of the ducks are in a row
|
|
I think it is a lot less than 10%, woelen.
Based on a density of 1.1789 for 36% HCl I calculate a molarity of 11.64M
Given a pKa of -6.3, this works out to be a pH of -1.0659. Or more usefully, the concentration of hydrogen ions is 11.64 moles per litre.
These two 11.64 figures are not identical. There is a difference of some 6.8×10–5. Which effectively means 0.000068 moles of the HCl
is undissociated at that high concentration. This is 0.00058% of the HCl present.
Of course it is an equilibrium and so as the HCl gas escapes more molecular HCl is created to replace it.
I suspect that it is the rate of diffusion that is the limiting factor for the escape of HCl from the solution. I stand to be corrected on this.
(And I stand to be corrected on my calculations too.)
|
|
Metacelsus
International Hazard
Posts: 2539
Registered: 26-12-2012
Location: Boston, MA
Member Is Offline
Mood: Double, double, toil and trouble
|
|
I'd be wary of calculating the undissociated HCl concentration like that, because the solution will be very highly non-ideal. I wouldn't be surprised
if a few percent remained undissociated.
|
|
DraconicAcid
International Hazard
Posts: 4334
Registered: 1-2-2013
Location: The tiniest college campus ever....
Member Is Offline
Mood: Semi-victorious.
|
|
Quote: Originally posted by j_sum1 | I think it is a lot less than 10%, woelen.
Based on a density of 1.1789 for 36% HCl I calculate a molarity of 11.64M
Given a pKa of -6.3, this works out to be a pH of -1.0659. Or more usefully, the concentration of hydrogen ions is 11.64 moles per litre.
|
That pKa is for aqueous solution. If you've changed to 36% HCl, that's not aqueous. You've got, what? four molecules of water for every
hydronium/choride ion pair? The Ka will be different.
Please remember: "Filtrate" is not a verb.
Write up your lab reports the way your instructor wants them, not the way your ex-instructor wants them.
|
|
j_sum1
Administrator
Posts: 6325
Registered: 4-10-2014
Location: At home
Member Is Offline
Mood: Most of the ducks are in a row
|
|
Well, I did invite correction. Thanks.
How would you calculate an acid that concentrated?
|
|
woelen
Super Administrator
Posts: 8014
Registered: 20-8-2005
Location: Netherlands
Member Is Offline
Mood: interested
|
|
Indeed, the concept of pH and the use of pKz only works fine at low concentrations. Up to appr. 1 mol/l the approximations still are acceptable, but
at higher concentrations the error quickly grows with concentration.
There is no standard framework for doing this kind of calculations which works for all acids. Each acid has its own peculiarities and modes of
non-idealness. Some modes are:
- no splitting of acid molecule in ions
- formation of ion-pairs (electrostatic forces keep two ions of opposite charge close to each other, which makes them unavailable for reactions)
- formation of acid-specific complexes.
- dissociation in anhydride/oxide and water, which makes the acid unavailable (e.g. H2CO3, HNO2, H2SO3)
The higher the concentration, the stronger the effect of these non-ideal behaviors.
For most acids, the non-ideal behavior leads to less acidity than one would expect on the basis of pKz only. An exeption is HF. At high concentrations
this acid becomes stronger, a concentrated solution is more acidic than one would expect theoretically.
|
|