Posts Tagged ‘Viscosity’

Practical molecular gastronomy, part 4

Saturday, March 17th, 2007


(Photo by vintage_patrisha at flickr.com)

4. Learn how to control the texture of food

Taste and flavour normally get more attention when food is discussed, but the texture of food is equally important and our tongue is very sensitive, not only to taste and temperature, but also to the texture of food. The texture of food determines it’s mouthfeel and it is related to many physical properties of the food. Wikipedia lists the following aspects of mouthfeel (click to see the full description of each aspect) which can be useful when analyzing food:

Adhesiveness, Bounce/Springiness, Chewiness, Coarseness, Cohesiveness, Denseness, Dryness, Fracturability, Graininess, Gumminess, Hardness, Heaviness, Moisture absorption, Moisture release, Mouthcoating, Roughness, Slipperiness, Smoothness, Uniformity, Uniformity of chew, Uniformity of bite, Viscosity, Wetness

I will barely scratch the surface of how texture can be controlled by highlighting a couple of topics and point you to further resources. Hopefully it will spark your interest and give some new ideas for you to play with in the kitchen. Those interested in a comprehensive review of food texture are referred to the CRC handbooks on food texture (volume 1: semi-solid foods, volume 2: solid foods).

What determines the texture of food?
Put very simple, it’s the relative amounts of air, liquid and solids that determines the texture of food. This is complicated by the fact that liquids have different viscosities. Furthermore the air, liquid and solid ratio is not necessarily constant. A liquid can solidify or evaporate, solids can melt or dissolve, and air bubbles can escape during cooking or storage. An elegant but quite abstract way of describing the complicated mixtures of air, liquids and solids found in food, is to use the CDS formalism (CDS = complex disperse systems), introduced by Hervé This.


(Photo by Subspace at flickr.com)

How can texture be controlled and changed?
Texture can be controlled by temperature, pH, air/liquid/solid ratio, osmosis, hydrocolloids and emulsifiers – to mention a few. Here’s some examples:

  • Heating induces a change in the structure of proteins referred to as coagulation or denaturation. Typical examples are the boiling of eggs and the cooking of meat. When proteins denature they contract and become firmer. There are several helpful tables relating the doneness of different meats to temperature.
  • At around 70 °C (160 °F) collagen, the connective tissue in meat, turns into gelatin. As a result the meat becomes more tender, which is desireable in stews and other slow cooked meats.
  • Heat causes air/gas to expand and water to evaporate to give a foamy/airy texture. For example, experiments have shown that it is mainly the evaporation of water that causes a soufflé to rise.
  • Heat will cause certain hydrocolloids to solidify (for exaple methyl cellulose) whereas it will cause others to melt (such as gelatin).
  • Brining meat can greatly improve it’s texture and juicyness. This is done by immersing the meat in a 3-6% salt solution from anyhere between a few hours to two days before cooking.
  • Frozen water in the form of tiny ice crystals are important for the smooth texture of sorbets and ice cream. Ice cream that has been partly melted and frozen again will grow larger ice crystals that impart a coarser texture to the ice cream.
  • Acidic solutions (low pH) can cause proteins to denature. This allows fish to be cooked without the use of any heat. An example is the use of lime juice in ceviche.
  • Emulsifiers, thickeners and gelling agents have almost become synonymous with molecular gastronomy for many. They can greatly alter the texture of foods and typically only a very small amount is required. Where gelatin was the only gelling agent videly available to cooks in Europe and America only a decade ago, this has changed with the advent of many internet suppliers of speciality ingredients.
  • Cooking under vacuum can create new and exciting textures. First of all it’s a way of removing excess water without having to raise the temperature all the way up to 100 °C. When the water is removed, this will create pockets of air in the food, and when the pressure is released, the liquid surrounding the food that is prepared will rush in and fill these pockets. There is a commercially available vacuum cooker, but a DIY version can be made from a pressure cooker and a vacuum pump.

  • (Photo by Trinity at flickr.com)

  • Green leaf vegetables such as lettuce loose water upon storage. As the pressure inside the cells drops, the leaf becomes softer. By immersing the leaves in cold water for 15-30 min, thanks to osmosis, water will enter into the cells again. As the pressure increases, the leaves become crisper.
  • Air bubbles can greatly modify textures, and foams really are ubiquitious (which becomes obvious if you read the book “Universal foam – from cappuccino to the cosmos”). Ferran Adria’s espumas have become very popular, as has his recent invention, the Espesso. Air bubbles are also very important for the texture of ice cream, in fact ice cream is nearly 50% air (just consider the fact that ice cream is sold by volume, not by weight!).
  • A very recent addition to the modern kitchen pantry is the enzyme transglutaminase. The enzyme acts like a meat glue and Chadzilla has nice blog post on his transglutaminase experiments.
  • There are also enzymatic counterparts of transglutaminase available: proteolytic enzymes also known as proteases. You can find them in pineapple (bromelain/bromelin), papaya (papain), figs (ficin) and kiwi (actinidin) – and they are capable of degrading proteins and muscle tissue. Despite this, they have only found limited use in marinades, as their action can be difficult to control (as Nicholas Kurti experienced, look for the “But the crackling is superb” link).
  • When mixing flour and water, glutenin and gliadin react to form gluten which gives bread it’s elasticity and plasticity. Addition of 1-2% salt to bread tightens the gluten network and increases the volume of the finished loaf. Similarly, addition of 1% oil to the dough (after the first kneading) can further increase the volume. Larger amounts of fat added before kneading will interfere with the formation of long gluten strands, hence the name shortening.
  • The no-knead bread that recently hoovered around in the blogosphere challenges the conventional wisdom that bread needs kneading to get a good texture.
  • Once bread is baked, the staling process starts. Staling does not necessarily involve loss of water from the bread and is caused by crystallisation (or retrogradation) of starch. In this process water molecules are trapped. The process proceeds fastest at 14 °C, but is halted below -5 °C. This is the reason why bread should be stored at room temperature. The staling process can be slowed down by addition of an emulsifier such as lecithin which is abundant in egg yolk.
  • A way of turning high fat foods and oils into powders is by the use of tapioca maltodextrin. Hungry in Hogtown has shown how Nutella can be turned into a powder.
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    Check out my previous blogpost for an overview of the tips for practical molecular gastronomy. The collection of books (favorite, molecular gastronomy, aroma/taste, reference/technique, food chemistry) and links (webresources, people/chefs/blogs, institutions, articles, audio/video) at khymos.org might also be of interest.

    Practical molecular gastronomy, part 3

    Monday, February 26th, 2007

    Get a basic understanding of heat transfer, heat capacity and heat conductance.

    Since a lot of cooking involves temperature manipulations, it’s a good idea to get a basic understandning of how heat is transferred and how well it is stored in different materials. “Heat” in this context does not imply high temperature since it also applies to the understanding of freezing/thawing.

    ceramic-stove-top.jpg
    Closeup of ceramic stove top

    Heat transfer

    Conduction: flow of heat through an object or between two objects in contact. Metals are typically good conducters whereas air is a poor heat conductor.

    Convection: heat transfer occurs because particles are moved from a warm region to a colder one. One can say that convection is a combination of conduction and mixing. For example, convection occurs when heating water since its density varies with temperature – warm water is lighter than cold water and will float. This video illustrates convection currents in water as a crystal of potassium permanganate dissolves (this salt is not edible).

    Radiation: in the kitchen we encounter two types of heat transfer by radiation corresponding to two different parts of the electromagnetic spectrum. The heat we feel from hot burning charcoal, a stove top or the sun are all a result of infrared radiation. The other type is microwave radiation. Heat transfer by radiation does not require a material for the heat to pass through (as a consequence, a blowing wind will not have any significant effect when grilling). Microwaves easily penetrate plastic, glass and wood, but not metal. Infrared radiation is blocked by opaque materials.

    Heat capacity and heat conductance

    Heat capacity: the heat requried to raise the temperature of the material. Water has a very high heat capacity, metals (shown in red) generally a low heat capacity.

    Heat conductance: how well heat flows through the material. Some metals (shown in red in the graph) are excellent heat conductors (silver, copper, aluminum), others less so (iron and stainless steel). All other materials (shown in blue) are generellay poor heat conductors.

    The heat capacity (or to be precise, the specific heat capacity – which means heat capacity per weight unit) and the heat conductance of materials encountered in the kitchen are plotted in the the graph below:

    heat-capacity-conductance.jpg
    (for the technically interested, the plot units are Wm-1K-1 for the heat conductance and Jg-1K-1 for the specific heat capacity)

    For a more extensive treatment of heat transfer, heat capacity and heat conductance (+ more on cooking methods and materials) in a gastronomical setting, I recommend the Gourmet Engineering Lecture Notes for a very interesting course given at Tufts University in Medford, MA, USA. Cooking for Engineers also has a nice post on heat transfer and browning of foods and one on common materials of cookware (with comprehensive comparisons of different materials used).

    Examples related to food preparation and handling

  • Convection ovens utilize fans to circulate hot air allowing reduced cooking times and temperatures. Because of efficient convection, two or more trays can be baked simultaneously.
  • In a steam oven water is introduced to increase the humidity (this can also be done by spraying water into the hot oven). Heat transfer is more efficient due to 1) the higher heat capacity of humid air and 2) the energy released when steam condenses onto the surface (it’s the energy it took to boil the water in the first place). For bread, the condesed water prevents the surface from drying out which facilitates the exapansion of the loaf. Furthermore, the hot surface causes starch to gelatinize and subsequently dry into a delicate crust.
  • Water will cool faster than the same volume of a thickened soup because of less resistance to the convection currents in water. The amount of convection decreases in the following order: water > chicken soup > creamy soup > thick onion soup > porridge. In the latter heat is transferred by conduction only from the interior to the exterior (where heat transfer proceeds mainly by radiation and conduction). This will also affect cooling times, which is of importance with regard to microbial safety (food should be cooled rapidly past the window from 30-60 °C where microorganism thrive).
  • For rapid defrosting, place the frozen food in cold water or on a metal object – this will allow an efficient transport of heat to the frozen food. Defrosting in a microwave is not easy because most of the water molecules are locked in rigid structure and even microwaves cannot make them move (they only melt by conduction of heat from melted neighbouring areas).
  • To freeze icecream or a parfait, use a metal container as this will allow a faster dissipation of the heat in the freezer.
  • When whipping cream, it’s essential to keep the temperature low (otherwise the fat will melt). Use a thick glas bowl and cool it in the freezer before whipping.
  • When cooking meat in a pan or on a grill, notice how the surface browns relatively fast compared to the time it takes for the interioir of the meat to heat up. Heat transfer to the surface by radiation or conduction is very efficient compared to conduction of heat through meat itself. Therefore it’s advisable to fry/grill the meat at high temperature first to get a nice browning, then let the meat rest for 5-10 min to allow for heat conduction to the interioir (cover with aluminum foil to reduce radiative heat loss), followed by a second frying/grilling at lower temperature until desired doneness.
  • In an oven, the heating caused by radiation can be increased by moving food closer to the walls or reduced by wrapping the food with reflective aluminum foil. For example, to caramellize sugar on a creme brulee if you don’t have gas burner, place them as high as possible in the oven, preferably using a grill element. Turkey legs stick out and easily get overdone – wrapping them with aluminum foil reduces heat radiation from the oven walls.
  • For a bain marie, always use a metal bowl as this gives you better temperature control. When making egg based sauces such as hollandaise or bernaise, use a thin metal bowl this allows rapid heating and cooling (if temperature gets to high, the metal bowl allows quick cooling which might save the sauce).
  • A pizza baking stone has a higher heat capacity than a metal plate/sheet – this ensures proper rising and gives a crispy crust.
  • Ever burnt your tongue on a pizza? Tomatoes (mostly water) retain heat far better than the crust (many air bubles, low heat capacity) and cheese topping (cools fast due to radiation from surface).
  • The vacuum in a thermos does not conduct heat by conduction or convection, only by radiation. The latter is minimized (in thermoses of glas) by a silver or aluminmum coating, creating a reflective mirror.
  • From the graph it doesn’t seem like cork is a particularly good insulator. This is because the heat conductance is plotted per weight unit. For a porous material such as cork, the effective heat conductance is much lower than for the same volume of other materials.
  • Lastly, just to illustrate how complex heat transfer and convection sometimes can be, take a look at the Mpemba effect: Believe it or not, under certain conditions, hot water freezes faster than cold water!
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    Check out my previous blogpost for an overview of the tips for practical molecular gastronomy. The collection of books (favorite, molecular gastronomy, aroma/taste, reference/technique, food chemistry) and links (webresources, people/chefs/blogs, institutions, articles, audio/video) at khymos.org might also be of interest.