Calculate Moles: Na2CO3 Solution | Chemistry Problem Help

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In summary, the individual is seeking help with calculating moles in chemistry and is confused about the application of the formula. They provide an example of calculating moles correctly but then run into trouble with a question in their textbook, where they are asked to calculate the molarity of HCl. They show their calculation process and ask for clarification on the correct answer.
  • #1
repugno
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Hello everyone. I have a slight problem with my chemistry and was wondering if there is someone that could help me. Chemistry is not my strong point so please go easy. Thank you.
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The problem is that I have gotten mixed up with how to calculate moles. Now, I know that I should use the formula:

n= Mass (g)/ Mr

The problem is that this doesn’t seem to apply everywhere and I don’t know why. If I have 1.5g of Na2CO3 in 250cm^3 of solution. Then I know that,

n= 1.5g/ 106 = 0.014150943mol

So, there is 0.014mol of Na2CO3 in 250cm^3 of solution.
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Now, I did a question in my textbook where this method of calculating moles did not work.

“A solution of Na2CO3 contains 12.5g of anhydrous salt in 1000cm^3 of solution. When 25cm^3 of this solution was titrated with a solution of HCl using methyl orange indicator, 23.45cm^3 of the acid was required.”

Naturally I would then use the formula to work out the moles…
n= 12.5g/ 106 = 0.117924528mol
However, the book states that this gives the concentration, and to calculate the moles I will have to multiply it by the volume (i.e. 25cm^3).

What am I not understanding? Any help would be greatly appreciated, Thank you.:)
 
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  • #2


Originally posted by repugno
Hello everyone. I have a slight problem with my chemistry and was wondering if there is someone that could help me. Chemistry is not my strong point so please go easy. Thank you.
---------------------------------------------------------------------
The problem is that I have gotten mixed up with how to calculate moles. Now, I know that I should use the formula:

n= Mass (g)/ Mr

The problem is that this doesn’t seem to apply everywhere and I don’t know why. If I have 1.5g of Na2CO3 in 250cm^3 of solution. Then I know that,

n= 1.5g/ 106 = 0.014150943mol

So, there is 0.014mol of Na2CO3 in 250cm^3 of solution.
---------------------------------------------------------------------
Now, I did a question in my textbook where this method of calculating moles did not work.

“A solution of Na2CO3 contains 12.5g of anhydrous salt in 1000cm^3 of solution. When 25cm^3 of this solution was titrated with a solution of HCl using methyl orange indicator, 23.45cm^3 of the acid was required.”

Naturally I would then use the formula to work out the moles…
n= 12.5g/ 106 = 0.117924528mol
However, the book states that this gives the concentration, and to calculate the moles I will have to multiply it by the volume (i.e. 25cm^3).

What am I not understanding? Any help would be greatly appreciated, Thank you.:)

What is the question asking for? You calculated the number of moles correctly. But if the question is asking for the Molarity of the HCl solution than the volume of the HCl solution is essential.
 
  • #3
Thank you for your response.

The question is asking me to calculate the molarity of HCl. If I calculated to moles right, I should be able to then calculate the molarity.

Na2CO3 + 2HCl ==> 2NaCl + H2O + CO3

Ratio (1:2)
So, 0.117924528mol * 2 = 0.235849056mol of HCl reacting with Na2CO3

Knowing

c= n/ V

then,
c= 0.235849056mol/ 23.45cm^3
c= 0.0101mol cm^-3


This doesn’t seem to be the concentraton, the answer in the book says it is 2.516mol cm^-3

I’m completely mystified ...
 
  • #4
I kind of have a standard way of setting these things out. It helps me remember what comes next.

"A solution of Na2CO3 contains 12.5g of anhydrous salt in 1000cm^3 of solution. When 25cm^3 of this solution was titrated with a solution of HCl using methyl orange indicator, 23.45cm^3 of the acid was required."

Na2CO3 + 2HCl ==> 2NaCl + H2O + CO3

Code:
Number of moles of Na2CO3  = mass/Mr
                           = 12.5/106
                           = 0.118 mol

Molarity of Na2CO3         = moles/volume
                           = 0.118/1
                           = 0.118 mol dm^-3

Moles of Na2CO3 in 25 cm^3 = concentration*volume
                           = 0.118 * 25 * 10^-3
                           = 0.00295 mol

Number of moles of HCl     = 0.00295 * 2
                           = 0.00590 mol

Molarity of HCl            = moles/volume
                           = 0.00590/(23.45*10^-3)
                           = 0.251 mol dm^-3
 
  • #5
Originally posted by lavalamp


Number of moles of Na2CO3 = mass/Mr
= 12.5/106
= 0.118 mol

Molarity of Na2CO3 = moles/volume
= 0.118/1
= 0.118 mol dm^-3

Moles of Na2CO3 in 25 cm^3 = concentration*volume
= 0.118 * 25 * 10^-3
= 0.00295 mol

Number of moles of HCl = 0.00295 * 2
= 0.00590 mol

Molarity of HCl = moles/volume
= 0.00590/(23.45*10^-3)
= 0.251 mol dm^-3


Thank you very much, that certainly made it much clearer. :smile:
 
  • #6
Happy to help. :smile:
 
  • #7
Originally posted by lavalamp
I kind of have a standard way of setting these things out. It helps me remember what comes next.

"A solution of Na2CO3 contains 12.5g of anhydrous salt in 1000cm^3 of solution. When 25cm^3 of this solution was titrated with a solution of HCl using methyl orange indicator, 23.45cm^3 of the acid was required."

Na2CO3 + 2HCl ==> 2NaCl + H2O + CO3

Code:
Number of moles of Na2CO3  = mass/Mr
                           = 12.5/106
                           = 0.118 mol

Molarity of Na2CO3         = moles/volume
                           = 0.118/1
                           = 0.118 mol dm^-3

Moles of Na2CO3 in 25 cm^3 = concentration*volume
                           = 0.118 * 25 * 10^-3
                           = 0.00295 mol

Number of moles of HCl     = 0.00295 * 2
                           = 0.00590 mol

Molarity of HCl            = moles/volume
                           = 0.00590/(23.45*10^-3)
                           = 0.251 mol dm^-3
So methyl orange will indicate in the neutral solution but not the sodium bicarbonate solution?
 
Last edited:
  • #8
The solution starts off neutral, and the indicator will colour the solution yellow. As the acid is added, the pH lowers and when it reaches pH=4.4 the methyl orange will start to colour the solution orange, as the pH lowers the colour becomes more and more orange until it gets to pH=3.1 when the soloution will become red.
This means that you should stop the titration at the first hint of orange in the solution. The chances are that it will go straight from yellow to red on one drop, since the acid is a strong acid.

So to answer you question, it depends what you mean by "indicate".
 
  • #9
Originally posted by lavalamp
The solution starts off neutral, and the indicator will colour the solution yellow. As the acid is added, the pH lowers and when it reaches pH=4.4 the methyl orange will start to colour the solution orange, as the pH lowers the colour becomes more and more orange until it gets to pH=3.1 when the soloution will become red.
This means that you should stop the titration at the first hint of orange in the solution. The chances are that it will go straight from yellow to red on one drop, since the acid is a strong acid.

So to answer you question, it depends what you mean by "indicate".

A solution of sodium carbonate is neutral? I didn't know that.
 
  • #10
There are two ions that affect the pH, they are H+ ions (cause acidity) and OH- ions (cause alkalinity). Since sodium carbonate contains neither of these, the pH of the solution depends on the H+ ions provided by the water. Since water is neutral, the solution will be neutral.

Even though the solution is neutral, the pH will be slightly higher than 7 (at s.t.p.). This is because the Na2CO3 (s) that is added will actually increase the volume of the solution just very slightly, which causes a drop in the concentration of H+ ions, and so, although the pH will be above 7, it will probably be in the be of the order 7.0001.

So for all practicality, the solution will have a pH of 7 and overall it will be neutral, unless H+ or OH- ions are added (or removed).
 
  • #11
Originally posted by lavalamp
There are two ions that affect the pH, they are H+ ions (cause acidity) and OH- ions (cause alkalinity). Since sodium carbonate contains neither of these, the pH of the solution depends on the H+ ions provided by the water. Since water is neutral, the solution will be neutral.

Even though the solution is neutral, the pH will be slightly higher than 7 (at s.t.p.). This is because the Na2CO3 (s) that is added will actually increase the volume of the solution just very slightly, which causes a drop in the concentration of H+ ions, and so, although the pH will be above 7, it will probably be in the be of the order 7.0001.

So for all practicality, the solution will have a pH of 7 and overall it will be neutral, unless H+ or OH- ions are added (or removed).

So then in order to make a solution basic you need to add something with a hydroxide, like NaOH of K(OH)2? I didn't know that.
 
  • #12
To make solution less acidic or more alkaline then, yes, you could add something like those two alkalis.
There are also things called buffer solutions, these resist changes to their pH, so although when you add acid or alkali to them their pH does change, it only changes a little. These may be a little complicated to explain, but if you want I'll try.
To put it simply, they contain both the un-dissociated acid/alkali molecules and the acidic/alkaline salt ions in roughly equal proportions. They can only occur as a result of weak acids and bases because for strong acids and bases, all of the molecules dissociate.
 
  • #13
Originally posted by lavalamp
To make solution less acidic or more alkaline then, yes, you could add something like those two alkalis.
There are also things called buffer solutions, these resist changes to their pH, so although when you add acid or alkali to them their pH does change, it only changes a little. These may be a little complicated to explain, but if you want I'll try.
To put it simply, they contain both the un-dissociated acid/alkali molecules and the acidic/alkaline salt ions in roughly equal proportions. They can only occur as a result of weak acids and bases because for strong acids and bases, all of the molecules dissociate.

Let's not worry about buffers for now. What I want to know is, if you add something with hydroxide to water (say Ca(OH)2) it will become basic, but if it does not have hydroxide ions, such as KCO3 or butyl lithium, then it will remain neutral?
 
  • #14
Yep, you've got it twigged.
 
  • #15
Originally posted by lavalamp
Yep, you've got it twigged.

That's interesting. Because I thought butyl lithum was highly basic and would rip the proton off of water if it looked at it funny.
 
  • #16
Lol, very funny. OK, you laid a very good trap and I walked straight into it. Since you didn't want to know about buffer solutions, I assume that you also didn't want to know about Lowry-Bronsted acids and bases.
The definition of an LB acid is a proton donar, or a lone pair acceptor such as an H+ ion.
The definition of an LB alkali is a proton acceptor, or a lone pair donor such as an OH- ion.

However not all LB acids and alkalis affect the pH of a solution as some do not contain any H+ or OH- ions.

It seems that you've had a slightly higher chemistry education than you let on.
 
  • #17
Originally posted by lavalamp
Lol, very funny. OK, you laid a very good trap and I walked straight into it. Since you didn't want to know about buffer solutions, I assume that you also didn't want to know about Lowry-Bronsted acids and bases.
The definition of an LB acid is a proton donar, or a lone pair acceptor such as an H+ ion.
The definition of an LB alkali is a proton acceptor, or a lone pair donor such as an OH- ion.

However not all LB acids and alkalis affect the pH of a solution as some do not contain any H+ or OH- ions.

It seems that you've had a slightly higher chemistry education than you let on.

So that butyllithium or Na2CO3 will not effect the pH of water?
 
  • #18
Not that I know of, I just know that it isn't just H+ and OH- ions that cause acidity and alkalinity.
I don't think that Na2CO3 will affect the pH of the solution. I suppose that it could cause the water molecules to dissociate and that would affect the pH, (even though the solution would be neutral overall while at the same time being an acid or an alkali). But we haven't done how LB acids and bases affect pH.
 
  • #19
Originally posted by lavalamp
Not that I know of, I just know that it isn't just H+ and OH- ions that cause acidity and alkalinity.
I don't think that Na2CO3 will affect the pH of the solution. I suppose that it could cause the water molecules to dissociate and that would affect the pH, (even though the solution would be neutral overall while at the same time being an acid or an alkali). But we haven't done how LB acids and bases affect pH.

HCl is a Bronsted-Lowry acid. NaOH is a BL base. Butyllithium is a BL, it accepts a proton from H2O. Now, if you accept a proton from H2O, what have you got?
 
  • #20
Well water minus a proton leaves OH- ions. So I suppose the pH would change:

pH = 14 + log10[OH-]

Although I must say, I'm not familiar wuth butyl lithum, could you provide a structural formula for it please.

I'd never really connected those two dots about water losing a proton and the solution becomming alkaline before just now.
 
  • #21
Originally posted by lavalamp
Well water minus a proton leaves OH- ions. So I suppose the pH would change:

pH = 14 + log10[OH-]

Although I must say, I'm not familiar wuth butyl lithum, could you provide a structural formula for it please.

I'd never really connected those two dots about water losing a proton and the solution becomming alkaline before just now.

n-Butyl lithium: CH3CH2CH2CH2- Li+

Reacts with water to form butane (C4H10) and LiOH.

So what is the structure of sodium carbonate? What happens when you stick it in water?
 
  • #22
Over here we call that Lithium-1-Butane (or 1-Lithium-Butane, I can't quite remember).

I suppose that the CO3 ion could act as a proton acceptor but I don't know. The conversation has moved into an area that I don't have much experience in.
 
  • #23
Originally posted by lavalamp
Over here we call that Lithium-1-Butane (or 1-Lithium-Butane, I can't quite remember).

I suppose that the CO3 ion could act as a proton acceptor but I don't know. The conversation has moved into an area that I don't have much experience in.

Well that would be the IUPAC name, but I'm pretty sure most brits still use n-butyllithium. Or en-buely for short.

OK, so carbonate ion excepts a proton. What do you get.
 
  • #24
Ok, I see where you're going with this, I was wrong. I offered duff advice, sorry. What more do you want me to say?
 

1. What is the formula for calculating moles in a Na2CO3 solution?

The formula for calculating moles in a Na2CO3 solution is: moles = (mass of solute in grams / molar mass of solute) / volume of solution in liters.

2. How do I determine the molar mass of Na2CO3?

The molar mass of Na2CO3 (sodium carbonate) can be determined by adding the atomic masses of each element present in the compound. In this case, it would be 2 x (atomic mass of Na) + (atomic mass of C) + 3 x (atomic mass of O).

3. What is the relationship between molarity and moles?

Molarity (M) is a measure of the concentration of a solution, which is the amount of solute (in moles) dissolved in a specific volume of solvent (in liters). Therefore, the number of moles can be calculated by multiplying the molarity by the volume of the solution in liters.

4. How do I convert between moles and grams?

To convert from moles to grams, you can use the molar mass of the substance. Multiply the number of moles by the molar mass to get the mass in grams. To convert from grams to moles, divide the mass by the molar mass.

5. Can I use this formula for any type of solution?

Yes, this formula for calculating moles in a solution can be used for any type of solute, as long as the molar mass is known and the units are consistent (grams and liters). However, keep in mind that different substances may have different solubilities and may require different volumes of solvent to achieve a desired concentration.

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