Experimenting with Supersaturated Solutions: Rock Candy Creation

 
ROCK CANDY
 
AKA the solubility of sucrose in water
depends upon the temperature.
 
Supersaturated solutions explained.
 
 
We have seen on table G that 120 grams
of KNO
3
 fit into 100 mL of solution at
65⁰C 
(the red arrow).
 
If the solution cools to just 10⁰C, this same
solution can only keep about 23 grams
dissolved 
(at the blue arrow).
 
The difference is what falls out of solution.
 
120 g – 23 g = 97 grams of precipitated KNO
3
at the bottom of the beaker.
 
This solution cannot keep all of this KNO
3
dissolved when cold.  
It can’t supersaturate
.
 
Strangely, sugar
can supersaturate.
 
You can start with a very concentrated HOT solution, and cool it
slowly, the extra sugar that should not be able to fit into the cold
solution stays dissolved.
 
It sort of tricks the water.
 
Sodium acetate can also do this (the reusable hand warmer salt).
 
If you make a super saturated solution of sugar, you can let it
slowly (about 6-7 days) crystalize onto a string, or a stick,
to make rock candy.
 
Rock candy is just crystalized sugar, that you can eat.
It’s pretty and it’s very sweet.
 
I started out with 50 mL of water,
room temperature about 22⁰C
 
I started adding sugar cubes…
         
 
etc.
 
I had no plan as to how much sugar might fit, but as it turns out,
I added 51.66 grams in total!
 
More sugar made the volume increase too.
The solution thickened up (it became more viscous).
 
 
 
As I heated it up, more sugar fit, and the solution clouded up some.
The volume rose to more than 100 mL.
 
 
 
At 93⁰C it held much more sugar (51.66 g + 64.55 g = 116.51 g !!)
 
The cold water held 51.66 grams of sugar when a few crystals
sat at the bottom.  Heated up to 93⁰C, I was able to add
64.55 MORE grams of sugar.
 
A total of 116.51 grams into 50 mL of water.  The volume
increased to more than 100 mL at this time.
 
I stuck some string tied to a pencil into the hot sugar
water.  I put the beaker away for safekeeping.  I will
photograph it over the next few days to see what
happens (fingers crossed).     
It cleared up a lot in 10 minutes
 
 
What was supposed to happen was my
sugar crystals were going to form
ON the string, which would encourage
more sugar to crystalize out of
solution, ONTO the crystals on the
string, and in a few days - they’d look
like this…
 
Who ever did this internet rock
candy picture used some red food
dye to make the candy pink, but
it’s the same idea.
 
One day in, not much to see.  The solution is clearing up.
 
 
The only way to get this much sugar into that water was to heat it
up quite a bit (over 90°C)
 
As the solution cooled down, you might think that the excess sugar
would drop out, like MOST compounds would.  50 mL of water can
only hold so much solute based upon temperature.
 
This solution “tricks” the water into staying over-full
as it cools down.
This is called being: SUPER-SATURATED.
This solution is holding more solute that should fit into this much water.
It works because we started out HOT, and then cooled it down slowly.
 
I think my beaker was not clean to start, so the crystals
formed (but not on the string).  They formed well on the
bottom – and the top of the beaker.  I ended up with a
solid top, and a solid bottom!
I will try again with this recipe, you should too.  Bob
makes science fun!  (it’s really a good recipe)
https://sciencebob.com/make-your-own-rock-candy/
 
You should try this, possibly using a popsicle stick, or wood skewer instead,
and IMPORTANTLY, “seed” the wet stick with crystal sugar and let the
crystals dry before putting it back into the supersaturated solution.
 
Making Rock Candy is harder than it looks, and this didn’t work well for me.
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Exploring the phenomenon of supersaturated solutions through an experiment creating rock candy. The solubility of sucrose in water is observed at different temperatures, showcasing how more sugar can dissolve in a hot solution than in a cold one. The process of supersaturation and crystallization is detailed, highlighting the changes in solubility as temperature varies.


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  1. ROCK CANDY AKA the solubility of sucrose in water depends upon the temperature. Supersaturated solutions explained.

  2. We have seen on table G that 120 grams of KNO3 fit into 100 mL of solution at 65 C (the red arrow). If the solution cools to just 10 C, this same solution can only keep about 23 grams dissolved (at the blue arrow). The difference is what falls out of solution. 120 g 23 g = 97 grams of precipitated KNO3 at the bottom of the beaker. This solution cannot keep all of this KNO3 dissolved when cold. It can t supersaturate.

  3. Strangely, sugar can supersaturate. You can start with a very concentrated HOT solution, and cool it slowly, the extra sugar that should not be able to fit into the cold solution stays dissolved. It sort of tricks the water. Sodium acetate can also do this (the reusable hand warmer salt). If you make a super saturated solution of sugar, you can let it slowly (about 6-7 days) crystalize onto a string, or a stick, to make rock candy. Rock candy is just crystalized sugar, that you can eat. It s pretty and it s very sweet.

  4. I started out with 50 mL of water, room temperature about 22 C I started adding sugar cubes etc.

  5. I had no plan as to how much sugar might fit, but as it turns out, I added 51.66 grams in total! More sugar made the volume increase too. The solution thickened up (it became more viscous).

  6. As I heated it up, more sugar fit, and the solution clouded up some. The volume rose to more than 100 mL.

  7. The cold water held 51.66 grams of sugar when a few crystals sat at the bottom. Heated up to 93 C, I was able to add 64.55 MORE grams of sugar. A total of 116.51 grams into 50 mL of water. The volume increased to more than 100 mL at this time. At 93 C it held much more sugar (51.66 g + 64.55 g = 116.51 g !!)

  8. I stuck some string tied to a pencil into the hot sugar water. I put the beaker away for safekeeping. I will photograph it over the next few days to see what happens (fingers crossed). It cleared up a lot in 10 minutes

  9. What was supposed to happen was my sugar crystals were going to form ON the string, which would encourage more sugar to crystalize out of solution, ONTO the crystals on the string, and in a few days - they d look like this Who ever did this internet rock candy picture used some red food dye to make the candy pink, but it s the same idea.

  10. One day in, not much to see. The solution is clearing up. The only way to get this much sugar into that water was to heat it up quite a bit (over 90 C) As the solution cooled down, you might think that the excess sugar would drop out, like MOST compounds would. 50 mL of water can only hold so much solute based upon temperature. This solution tricks the water into staying over-full as it cools down. This is called being: SUPER-SATURATED. This solution is holding more solute that should fit into this much water. It works because we started out HOT, and then cooled it down slowly.

  11. Making Rock Candy is harder than it looks, and this didnt work well for me. I think my beaker was not clean to start, so the crystals formed (but not on the string). They formed well on the bottom and the top of the beaker. I ended up with a solid top, and a solid bottom! I will try again with this recipe, you should too. Bob makes science fun! (it s really a good recipe) https://sciencebob.com/make-your-own-rock-candy/ You should try this, possibly using a popsicle stick, or wood skewer instead, and IMPORTANTLY, seed the wet stick with crystal sugar and let the crystals dry before putting it back into the supersaturated solution.

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