It’s the height of ice cream season and as good a time as any to take a look at some of the science behind the scoop.
I’m obsessed with ice cream’s inner workings, and a little technical know-how can help us perfect our frozen creations. What follows is a brief primer on key factors to consider with ice cream: how to properly balance a formula, mastering just the right consistency, building proper structure and controlling the size of ice crystals.
Formula
While there may not be one “ideal” ice cream formula, one can assemble a formula much like an algebraic equation based on the desired end result. The key to success is knowing which components are proportionally fairly static and which are variable. Then it’s about knowing how your ingredients supply these basic components.
One can very generally place ice cream formulas and their constituent components within the following ranges:
- Milk fat: 10–16%
- Egg yolk solids: 0–2%
- Nonfat milk solids: 9–12%
- Sweeteners: 12–16%
- Stabilizers and emulsifiers: 0–1%
- Water: 55–64%
There are, of course, exceptions. Gelato-style products often have a fat content in the 7-8% range and soft serve products may contain 5% fat or less, though such products cannot commercially be called ice cream, which is defined by U.S. law as containing a minimum of 10% milk fat.
Crucial to understanding how to build an ice cream formula is knowing the composition of your ingredients. I think this basic information is important no matter the preparation at hand. With knowledge of an ingredient’s composition, structure and function comes true power for the cook. For example, rather than thinking of milk as simply “milk,” one must look at it as a system of water, fat, protein and sugar; its structure is at once an emulsion, a suspension and a solution. We can examine every ingredient we use in an ice cream under the same figurative microscope.
Consistency
The amount of solutes in the unfrozen water phase determines volume of ice crystals that form. Water containing dissolved solids such as salt and sweeteners are affected by something we refer to as colligative properties. These solutes will raise the boiling point of water on the high end of the temperature range, and at the low end, they lower the freezing point of water. It is this very property of freeze point depression that makes ice cream possible at all – served below water’s freezing point it is soft enough to scoop and chew.
Different solutes — for the sake of our discussion, sweeteners — will lower the freezing point of water to different degrees. The measurement that we use to correlate freeze point depression is a sweetener’s molecular weight: The lower the molecular weight, the greater the effect of freeze point depression. Sucrose, for example, has a molecular weight of about 342. Dextrose is lower at 180 and glucose is slightly higher at 428. What does this mean for an ice cream maker? Dextrose can produce a softer product at colder temperatures, while glucose will firm up an ice cream at warmer temperatures. Simply put, we can use multiple sweeteners to modify the freezing point — the relative firmness or softness — of an ice cream.
Also interesting to consider is the idea of freeze concentration: as a solution freezes, only pure water crystallizes in to ice, which means the concentration of solutes in the remaining unfrozen water increases, which also means that the freezing point of that water continues to drop as more water turns into ice. Thus, even at a temperature of about 3 F/-16 C (below the typical serving temperature of ice cream) only about 72% of the total water in a base mix is frozen as ice. The rest remains unfrozen as a very concentrated sugar solution, thus giving a soft scoop-able consistency.
Structure
In addition to supplying creamy mouthfeel, the milk fat content of ice cream will determine its basic physical structure. The best way to understand the structure of ice cream is to step back and consider first the structure of whipped cream. As we whip heavy cream, we can begin to visualize individual fat particles swirling around the continuous phase of water, slamming into each other almost as if in a mosh pit (my favorite way to describe it). With help from some of the milk proteins, these partially coalesced fat particles begin to form a kind of “scaffolding” — a solid structure — that traps the air bubbles that are incorporated into the cream as it is being whipped. Though the composition of ice cream is more complex, this same type of structure is being created in the freezing and churning process.
Size
Ice cream is made up of a lot of ice. Obviously, right? Ice defines its nature, yet improper formulation or handling can result in the ice emerging as a negative attribute — too much ice or in too large a crystal size. The rate and speed of freezing the base mix determines crystal size — the lower the temperatures, the faster the base freezes to produce the smallest possible ice crystal. These ice crystals will always be at their greatest number and smallest size the moment they are extracted from the machine; they can never get smaller.
How do we keep those ice crystals as small as possible for a smooth and creamy texture? It’s all about speed and temperature. A high-end batch freezer that can process ice cream in a few minutes will make better ice cream than lower-end methods that may take much longer to freeze. It’s a classic example of getting what you pay for. Spin your ice cream as quickly as possible and store it as cold as possible to minimize the size and growth of ice crystals.
Below is one of my standard well-balanced formulas for classic vanilla ice cream. Still hungry for more ice cream knowledge? My two-day Ice Cream and Sorbet Technology class in August will offer a deeper dive into these topics and much more!
Ingredients
- 970 grams whole milk
- 2 vanilla beans, split and scraped
- 97 grams nonfat dry milk
- 200 grams sucrose (1)
- 85 grams glucose powder
- 80 grams sucrose (2)
- 8 grams ice cream stabilizer blend
- 60 grams pasteurized egg yolks
- 360 grams heavy cream
Directions
- Place the milk and vanilla in a sauce pot. Whisk in dry milk to rehydrate, followed by the first measurement of sucrose (1) and glucose. Bring to a boil.
- Meanwhile, combine the sucrose (2) and stabilizer. Whisk into egg yolks.
- Temper the hot milk into the egg yolk mixture. Return to low heat and cook, stirring, to 85 C/185 F.
- Remove from heat, whisk in heavy cream, and homogenize with an immersion blender. Chill in an ice water bath. Allow the mix to mature under refrigeration for at least 12 hours.
- Process in a batch freezer; extract the mix at -5 C/23 F. Alternatively, transfer to PacoJet canisters and completely freeze; process as needed.
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