Read Cooking for Geeks: Real Science, Great Hacks, and Good Food Online
Authors: Jeff Potter
Tags: #COOKING / Methods / General
One of the more common uses of industrial chemicals in food is to form colloids. A colloid is any mixture of two substances — gas, liquid, or solid — where one is uniformly dispersed in the other, but they are not actually dissolved together. That is, the two compounds in the mixture don’t form chemical bonds, but the overall structure appears uniform to the naked eye.
Common colloids in the kitchen are whole milk and chocolate. In milk, solid particles of fat are dispersed throughout a water-based solution. In chocolate, particles of cocoa solids are dispersed throughout a solid medium of cocoa fat and other ingredients.
The following table shows the different combinations of particles and media, along with examples of foods for each colloid type. The medium of a colloid is called the
continuous phase
(it’s the watery liquid in milk); the particles are known as the
dispersed phase
(for milk, the fat droplets).
| Gas particles | Liquid particles | Solid particles |
Gas medium | (N/A: gas molecules don’t have a collective structure, so gas/gas combinations either mix to create a solution or separate out due to gravity) | Liquid aerosols
| Solid aerosols
|
Liquid medium | Foams
| Emulsions
| Sols and suspensions
|
Solid medium | Solid foams
| Gel
| Solid sols
|
Some of these colloid types might remind you of various dishes served at more experimental restaurants. |
One of the surprises of this table is the relatively broad swath of techniques that it captures. Foams, spherifications, and gelled foods are all colloids. Even some of the more recent novel dishes are colloids from the gas medium category. Chef Grant Achatz (Alinea, in Chicago) has used solid aerosols by infusing a pillow with smoke and then placing the dish on top of the pillow, forcing the air containing the aerosol to leave the pillow and diffuse into the diner’s environment.
Chef Achatz uses smoke-infused “pillows” to present a pleasant olfactory experience while avoiding the taste sensation for items such as mace and lavender.
Other luxury restaurants have created courses that involve liquid aerosols (by spraying a perfume), and one company (Le Whif) is working on a kitchen gadget that creates solid aerosols from foods such as chocolates.
Some food additives can be used in more than one type of colloid. For example, guar gum can act as an emulsifier (by preventing droplets of oil from coalescing) and as a stabilizer (by preventing solids from settling). Methylcellulose is both a gelling agent and an emulsifier. Don’t think of food additives as directly mapping onto the colloids they create, but it’s a handy framework for thinking about the types of effects you can achieve.
The food industry uses gels to thicken liquids, to emulsify sauces, to modify texture (“improve mouth-feel,” as they say), and to prevent crystal formation in products such as candies (sugar crystals) and ice cream (ice crystals and sugar crystals). Gels are also found in traditional home cooking: both gelatin (see the section on
Filtration
in
Chapter 7
) and pectin (see the sidebar
Make Your Own Pectin
in
Chapter 4
) are used in many dishes to improve mouth-feel, and they also help preserve items such as jams.
From the perspective of modernist cuisine, thickeners and gels are used primarily to create dishes in which foods that are typically liquid are converted into something that is thick enough to hold its shape (this is what pectin does in jam), or even completely solid.
Gels can also be formed “around” liquids to create a gelatinous surface in a technique known as
spherification
, originally discovered by Unilever in the 1950s and brought to the modernist cuisine movement by Chef Ferran Adrià of elBulli. For our purposes, gels in foods can be classified into two general types: soft gels and brittle gels (true gels).
You can think of a
soft gel
as a thicker version of the original liquid: it has increased viscosity (it’s “thicker”), but it retains its ability to flow. Soft gels can exhibit a phenomenon termed
shear thinning
, which is when a substance holds its shape but will flow and change shape when pressure is applied. Substances like ketchup and toothpaste exhibit shear thinning: squeeze the bottle or tube, and it flows easily, but let go, and it holds its shape.
Iota carrageenan (left, 2% concentration) creates a flexible brittle gel, while kappa carrageenan (right, 2% concentration) creates a firm brittle gel. These two samples are resting on top of a narrow bar.
While a soft gel can be described as a “thicker” version of the original liquid, a
brittle gel
can be thought of as a solid. Brittle gels — foods like cooked egg whites and Jell-O — have a tightly interconnected lattice that prevents them from flowing at all. With sufficient quantities of the gelling agent, this type can form a block or sheet that you can pick up, slice into blocks or strips, and stack as a component in a dish, and it has a “memory” of its cast shape, meaning that it will revert to that shape when no other forces are in play.
In the consumer kitchen, cornstarch is the standard traditional gelling agent. In industrial cooking, carrageenan is commonly used in gelling applications. (Try finding cream cheese that doesn’t have carrageenan in it.) Iota carrageenan is used when a thickening agent is needed, while kappa carrageenan and agar yield firm, brittle gels. While the gelling agents used to create flexible and rigid gels are generally different, you can create a flexible gel with a gelling agent typically used in rigid, brittle applications by carefully controlling the quantity of gelling agent used.
Starches are used as thickeners in everything from simple roux to pie filling. They’re easy, plentiful, and exist in almost all of the world’s cuisines: cornstarch, wheat flour, tapioca starch, and potato “flour” (not actually a flour) being the most common. While there are differences among these starches — size of the starch granules, length of the molecular structure, and variations on the crystalline structure — they all act essentially the same. Expose to water, heat up, then cool down, and they thicken up.
Gelatinization temperature of common starches.
Starch is composed of repeating units of amylopectin and amylose that form crystalline structures. The gelatinization temperature — the temperature at which these crystalline structures melt and then absorb water and swell — can vary, depending upon the ratio of amylopectin and amylose groups. We’ll examine cornstarch here, but as you play with the others, keep in mind that the gelatinization temperature can vary.
Instructions for use. |
Uses. |
Origin and chemistry. |
Technical notes | |
---|---|
Gelatinization temperature | 203°F / 95°C; maximum thickness at 212°F / 100°C. |
Gel type | Thixotropic. (This means it becomes less viscous when pressure is applied. Think ketchup: it holds its shape, but flows under pressure.) |
Syneresis (“weeping”) | Extensive if frozen and then thawed. |
Thermoreversible | No — after gelatinizing, the amylose is leached out from the original starch molecules. |
Like many savory foods in which multiple discrete components are combined to create the dish, lemon meringue pie is the combination of three separate components: pie dough, a meringue, and a custard-like filling. We’ve already covered pie dough ( in
Chapter 5
) and meringues (
French and Italian Meringue
in
Chapter 5
), so the only thing left for making a lemon meringue pie is the filling itself. Flip to those recipes for instructions on how to make the pie dough and meringue topping.
To make the lemon custard, place in a saucepan off heat and whisk together:
Add 3 cups (700g) of water, whisk together, and place over medium heat. Stir until boiling and the cornstarch has set. Remove from heat.
In a separate bowl, whisk together:
Save the whites for making the meringue. Make sure not to get any egg yolk in the whites! The fats in the yolk (nonpolar) will prevent the whites from being able to form a foam when whisked.
Slowly add about a quarter of the cornstarch mixture to the egg yolks while whisking continuously. This will mix the yolks into the cornstarch mixture without cooking the egg yolks (tempering). Transfer the entire egg mixture back into the saucepan, whisk in the following ingredients, and return to medium heat and cook until the eggs are set, about a minute:
Transfer the filling to a prebaked pie shell. Cover with Italian meringue made using the six egg whites (double the recipe in
French and Italian Meringue
in
Chapter 5
, which is for three whites), and bake in a preheated oven at 375°F / 190°C for 10 to 15 minutes, until the meringue begins to turn brown on top. Remove and let cool for at least four hours — unless you want to serve it in soup bowls with spoons — so that the cornstarch has time to gel.
To create decorative peaks on the meringue, use the back of a spoon: touch the surface of the unbaked meringue and pull upward. The meringue will stick to the back of the spoon and form peaks.
Gelling agents typically come as a powdered substance that is added to water or whatever other liquid you are working with. Upon mixing with the liquid, and typically after heating, the gelling agent rehydrates and as it cools forms a three-dimensional lattice that “traps” the rest of the liquid in suspension. By default, add your gelling agent to a cold liquid and heat that up. Adding gelling agents to hot liquid usually results in clumps because the outer layer of the powder will gel up around the rest of the powder.