Argthtjtr

I was given an interesting dilemma today. A co-worker saw me adding a liquid (Diisopropyl ethylamine AKA DIPEA) to a flask filled with another liquid (Tetrahydrofuran AKA THF). I needed to weigh out exactly 5 grams of DIPEA into the THF and so I zero'd the scale with the flask+THF on it, then proceeded to add the DIPEA until the scale said 5.000g. Since masses are additive I assumed this was fine.

My co-worker, however, stopped and told me that although masses of two liquids are additive, the combined weights would not be, and since the scale measures weight as opposed to mass I had apparently just added an incorrect amount of DIPEA. He explained the reasoning to me but I'm a chemist, not a physicist and certainly not skilled in fluid mechanics, so I would like someone to dumb it down for me a bit or tell me if I'm way off.

From what I understand, the scale measures weight which is a function of gravitational force. But gravitational force is a function of buoyant force (its less if the buoyant force is greater since the buoyant force pushed a liquid up). Finally, buoyant force is a function of density. This means that my THF (which had a density of .9 g/ml) had a greater buoyant force than my THF/DIPEA solution (DIPEA density is only .74 g/ml so the solution would be somewhere between .74 and .90). And this means that technically as I'm adding DIPEA, the added mass is not the only thing causing the weight to increase; but rather the decreased buoyant force is also causing that.

And so, when the scale finally read 5.000g, I had possibly only added 4.950 or maybe 4.990 etc (something less than 5.000). Is my reasoning correct? Any help is appreciated.

Of course, by common sense, if you put together two objects with masses $m_1$ and $m_2$, and nothing comes out, then you end up with mass $m_1 + m_2$.

Weights are a little more complicated because of buoyant forces. All objects on Earth continuously experience a buoyant force from the volume of the air they displace. This doesn't matter as long as volume is conserved: if you stack two solid blocks their weights add because the total buoyant force is the same as before. But when you mix two liquids the total buoyant force can change, because the volume of the mixed liquid might not be equal to the sum of the individual volumes.

To estimate this effect, let's say (generously) that mixing two liquids might result in a change of total volume of $10%$. The density of air is about $0.1%$ that of a typical liquid. So the error of this effect will be, at most, around $0.01%$, which is irrelevant. Thus we can conclude that, rather than trying to help, your coworker just wanted to feel smug for a second.

@knzhou supplied a good answer. I’m going to offer a couple of other interpretations.

The first has nothing to do with the fact that you’re mixing liquids—it’s just that there are difficulties is determining mass precisely by measuring weight. As already pointed out, there is the buoyancy of the air—that produces a mass error of about $-0.0013$ g/l at sea level, or about $-0.14$% in the case of a substance with a density of $0.9$ g/l. Then, the gravitational acceleration varies by location by up to half a percent, largest near the poles and smallest near the equator (also smaller at high elevation). So if your scale measures force (uses springs or load cells rather than counterbalancing mass) and is calibrated for use in Paris, you’ll get an additional ~$ -0.1$% error if you weigh your sample in Mexico City. Of course, these errors would be the same if you weighed each liquid separately as if you weigh the mixture.

Second, I don’t know any chemistry, but if your two liquids react and produce gas which escapes from the top of the container, that is obviously lost mass. If this is not the case, then your buddy is pretty much full of crap, because the only other effect I can imagine which would produce a difference based on weight pre- or post-mixing is the one already alluded to:

In oceanography it’s called cabbeling. Two substances mixed together don’t necessarily have exactly the density you’d compute from a weighted average of the densities of each. For liquids I’m familiar with, the discrepancy is far less than $10$%: more like $1$% at most, which, when combined with air buoyancy makes for an error of 0.001%. You might as well worry about the error caused by the tidal force from the moon.

Based on your question I assume the precision is very important in your lab. If so, then yes, your colleague is right. At least to some degree.

There are main three possibilities why this may happen. From your description the reason is purely physical, so option 1 on my list and I will explain it in more details. The other two are added just for completeness of the answer.

Why adding weights doesn't produce the sum of weights?

Consider these options.

1. If the substances mix (i.e. a result is a solution of the two substances) the volume of resultant solution is smaller than volumes of ingredients. The masses remain the same though. I'll explain this phenomenon in a bit. The reason is purely physical.


2. If the substances react and some of the resulting substances leaves the solution (usually it will be a gas that evaporates) the mass will reduce by the mass of removed substance. Usually the volume will also be smaller since on one hand some of the substance is removed and the resultant solution with whatever remains should follow the same principle as in 1. But the newly formed particles could in theory prevent that and cause the volume to actually increase. I can't think of any examples (or even if there exists some). The reason is mixed chemical and physical.


3. If the substances react and as a result you get a soluble substance you end up with a solution of a new substance. In most (if not all) cases you have less particles to pack so your volume will drop with the mass remaining the same.If additionally the solvents mix you end up with added effect as in one so the difference can be even higher. This is a mix of chemical and physical reasons.

So what happens?

Your colleague refers specifically to point 1 on my list so I'll focus on it only.

In general the main reason is that the particles in solutions might have different size (and sometimes to a degree also shape, but usually it's less important factor) and as a result they can "pack" more densely so in the same volume you can fit more particles and as a result - more mass. The most extreme case is that the substances that are solvents themselves mix well with a significant volume reduction and the solved substance have just a tiny impact on the overall density.

As a result you end up with a mass being sum of masses but volume noticeably smaller than sum of volumes. And here enters the buoyancy on stage. The difference in volume causes a difference in weight. It's not big but if you need a huuuge precision it might make you fail meeting it.

So how big an impact can be?

In general the bigger the difference in particles size the stronger effect you'll notice.

I know nothing about the substances you're referring to but let's use something well known to most people. And something you can easily test yourself (and then consume the by-products to cool down your head a bit after thinking it all over ;-) ). There are two popular good solvents that mix rather easily - water and ethanol. I'll make a perfect case scenario where we mix pure water with pure ethanol. If you want to make an experiment you'll actually use some kind of solutions where those are solvents but the results will be noticeable for sure.

First let's calculate how much volume are we going to loose. Based on this water-ethanol mixtures density we'll calculate the difference for 40% alcohol solution (popularly known as vodka).

Pure water has a density of $0.998202 text{ g}/text{cm}^3$

Pure ethanol has a density of $0.79074 text{ g}/text{cm}^3$

40% ethanol in water solution (calculated by weight) has a density of $0.93684 text{ g}/text{cm}^3$

Those densities are based normalised atmosphere so weight based.

So let's take (by weight) $60 text{ g}$ water and $40 text{ g}$ ethanol.
The volumes are respectively $60/0.998202 = 60.108074text{ cm}^3$ of water and $40/0.79074 = 50.585527text{ cm}^3$ ethanol.

A common sense would suggest we are going to have $100 text{ g}$ of solution with a volume of $60.108074 + 50.585527 = 110.693601text{ cm}^3$. Then we realise the density is going to be different, so $100 text{ g}$ of solution that measures $100/0.93684 = 106.741813text{ cm}^3$. But neither of those is correct.

To have accurate results we need to go through masses.

The density of air is $0.001204 text{ g}/text{cm}^3$

The experienced weight loss for water is $60.108074 cdot 0.001204 = 0.07237text{ g}$ and the mass of water is $60.07237text{ g}$

The experienced weight loss for ethanol is $50.585527 cdot 0.001204 = 0.060905text{ g}$ and the mass of ethanol is $40.060905text{ g}$

The mass of resultant solution is $60.07237 + 40.060905 = 100.137275text{ g}$

To calculate accurately the weight let's use proportion.

If we had $100text{ g}$ of $40%$ ethanol its volume would be $106.741813text{ cm}^3$ calculated earlier.

The experienced weight loss from buoyancy would be $106.741813 cdot 0.001204 = 0.128517 text{ g}$

The mass of it would be $100.128517text{ g}$

So the weigh of solution, which mass is $100.137275 text{ g}$ is going to be
$100/100.128517cdot100.137275 = 100.008747 text{ g}$

i.e. higher by $0.008747$ (or $0.008747%$) than expected.

If we applied this result to your case, for $5text{ g}$ you'd end up with $5.000437 text{ g}$.

The difference seems to be less than your precision. If it's acceptable or not - you need to decide yourself. Also your case might get more extreme.

Oh, just for reference - the volume of our solution would be $106.741813/100.128517cdot100.137275 = 106.751149 text{ cm}^3$

It's still significantly less than the sum of volumes, which as we've calculated was $110.693601 text{ cm}^3$.

What can you do to avoid that

Assuming the difference is significant enough to bother you, you have two options.

1. Mix the solution first and then measure the requested amount


2. Experimentally check the actual change of weight and calculate amounts to use. Note though that you risk a rounding errors this way.

Test volume loss yourself!

If you want to check it yourself take neutral spirit and water (I think apple juice will do and will add colour to better see the difference). Pour water into glass tube. Then carefully pour spirit so that it doesn't mix with water (tilt the glass tube and slowly pour it on the tube's side). Mark the current volume. Now stir or shake until both liquids mix well and wait until it settles.

The resultant mixture is safe to consume ;-)

You may also check this video.

I just adhere to the scenario you have described.

Just put a container filled with water on a scale. Weight reads W1.
Put a floating object of mass w. Reads is now W1 + w.

Repeat with a fluid having different density on which the above object is still floating. If the weight of vessel and fluid is now W2 ask your colleague about the reading he/she expects after dropping in the floater of weigh w.......