Difference between revisions of "The Science of Chocolate: interactive activities on phase transitions, emulsification, and nucleation"

From Soft-Matter
Jump to: navigation, search
Line 16: Line 16:
 
1) ''Phase Changes'': To frame this topic, the authors pose the question: "why does chocolate melt in your mouth and not in your hand?" Using their demonstration the authors show that dark chocolate melts 'slower' than milk chocolate. Dark chocolate has less cocoa butter (fat) and consequently melts at a higher temperature. Cocoa butter is a saturated fat (a straight chained molecule) that packs closely and crystallizes at temperatures below room temperature (which is about that of your hand). For a more complete discussion, the authors briefly describe that unsaturated fats are 'kinked' molecules that cannot as closely pack and therefore are liquids at room temperature (olive oil for example). It just so happens that the crystal structure of the saturated fat cocoa butter melts at about 97 degrees F which is approximately body temperature (the temperature in your mouth). Here is the fundamental idea of phase change. Given a constant concentration of a material--chocolate in this case--as temperature is varied, different phases (solid, liquid, vapor) are observed. The vapor phase of chocolate is not demonstrated or discussed... most people would consider this phase of chocolate to be too hot for any interest/use.
 
1) ''Phase Changes'': To frame this topic, the authors pose the question: "why does chocolate melt in your mouth and not in your hand?" Using their demonstration the authors show that dark chocolate melts 'slower' than milk chocolate. Dark chocolate has less cocoa butter (fat) and consequently melts at a higher temperature. Cocoa butter is a saturated fat (a straight chained molecule) that packs closely and crystallizes at temperatures below room temperature (which is about that of your hand). For a more complete discussion, the authors briefly describe that unsaturated fats are 'kinked' molecules that cannot as closely pack and therefore are liquids at room temperature (olive oil for example). It just so happens that the crystal structure of the saturated fat cocoa butter melts at about 97 degrees F which is approximately body temperature (the temperature in your mouth). Here is the fundamental idea of phase change. Given a constant concentration of a material--chocolate in this case--as temperature is varied, different phases (solid, liquid, vapor) are observed. The vapor phase of chocolate is not demonstrated or discussed... most people would consider this phase of chocolate to be too hot for any interest/use.
  
2) ''Surfactant/Emulsification'': Although the authors do not use these words per say, this is the subject they address by asking the question, "Why does chocolate feel smooth in your mouth?" While this texture may be partially a result of cocoa solid particulate size, much of it is due to the emulsification process. As discussed by the authors, cocoa powder and cocoa butter (the two main ingredients of chocolate) do not readily mix; however, as evident by the mixing of hot chocolate or as the authors mention, chocolate milk, cocoa powder mixes well with water. This is reminiscent of last week's topic and wiki entry: surfactants. The cocoa powder is hydrophilic which, as we have discussed, does not mix well with fats/oils (cocoa butter). The emulsifier used in may chocolates is soy lecithin which is amphiphilic and thus a stabilizes the cocoa powder in the cocoa butter. Much of lecture considered the the mixing of oil and water but we also discussed the solid-oil interaction with oil soluble surfactant (image from lecture slide below). Here, the surfactant is soy lecithin, the solid is cocoa powder particles, and the oil is cocoa butter. As Stone et al suggest and as we have discussed, the adsorption onto the surface of the solid (cocoa powder) is driven by high head group/solid affinity while the stabilization of the system results from the hydrocarbon chain affinity with oil.
+
2) ''Surfactant/Emulsification'': Although the authors do not use these words per say, this is the subject they address by asking the question, "Why does chocolate feel smooth in your mouth?" While this texture may be partially a result of cocoa solid particulate size, much of it is due to the emulsification process. As discussed by the authors, cocoa powder and cocoa butter (the two main ingredients of chocolate) do not readily mix; however, as evident by the mixing of hot chocolate or as the authors mention, chocolate milk, cocoa powder mixes well with water. This is reminiscent of last week's topic and wiki entry: surfactants. The cocoa powder is hydrophilic which, as we have discussed, does not mix well with fats/oils (cocoa butter). The emulsifier used in may chocolates is soy lecithin which is amphiphilic and thus a stabilizes the cocoa powder in the cocoa butter. Much of lecture considered the the mixing of oil and water but we also discussed the solid-oil interaction with oil soluble surfactant (image from lecture slide below). Here, the surfactant is soy lecithin, the solid is cocoa powder particles, and the oil is cocoa butter. As Stone et al suggest and as we have discussed, the adsorption onto the surface of the solid (cocoa powder) is driven by high head group/solid affinity while the stabilization of the system results from the hydrocarbon chain affinity with oil.
  
 
[[Image:Choc 1.jpg]]
 
[[Image:Choc 1.jpg]]
  
 
3)
 
3)

Revision as of 17:06, 29 October 2011

Entry by Andrew Capulli, AP225 Fall 2011

Reference

A. C. Rowat, K. A. Hollar, H. A. Stone, and D. Rosenberg, "The Science of Chocolate: Interactive Activities on Phase Transitions, Emulsification, and Nucleation," J. Chem. Educ. 88 (1), 29-33 (2011).

Introduction: Motivation

A change in a system being studied can be generally viewed as a phase change and although much of this sort of physics studied in academia seems like far-out irrelevant work, as we all know, its really not... in fact, it can be related to common materials and phenomena we see everyday (remember to Cheerios Effect!?... see a couple wiki entries ago). And what better, in terms of explaining 'science' than food? Stone et al. use chocolate as their 'everyday' material to explain some fundamental physics to the community (ages 6+); chocolate being a very complex food that deliciously illustrates the authors' points (discussed below). But even to the graduate student, the demonstrations used by the authors and the seemingly simple physics being covered is easily recognizable as an opening of the door to a far more complicated subject. In the past few weeks in Soft Matter we have covered some introductory material on surfactants and phase diagrams/transitions and this 'paper' addresses those subjects while further demanding more investigation of the reader. Because this paper is more so an instructive layout on how to teach/demo the subjects to a general audience, I'll focus my wiki not only on what the paper had to say, but some further investigation into the phases of chocolate.

Summary: Educational Points of the Paper

This paper, unlike the typical methods or experimental account we're used to reading and discussing, is an instructive summary on how to address some relatively simple but very important explanations (the physics) behind some common phenomena we see everyday. It should be noted that while the 'take homes' from the summarized demonstrations seem fundamental... even as graduate students we re-learn the concepts. The authors aim to address three main concepts:

  1. Phase Changes (Solid, Liquid, Vapor)
  2. Surfactant/Emulsification
  3. Crystallization (More Phase Change)


1) Phase Changes: To frame this topic, the authors pose the question: "why does chocolate melt in your mouth and not in your hand?" Using their demonstration the authors show that dark chocolate melts 'slower' than milk chocolate. Dark chocolate has less cocoa butter (fat) and consequently melts at a higher temperature. Cocoa butter is a saturated fat (a straight chained molecule) that packs closely and crystallizes at temperatures below room temperature (which is about that of your hand). For a more complete discussion, the authors briefly describe that unsaturated fats are 'kinked' molecules that cannot as closely pack and therefore are liquids at room temperature (olive oil for example). It just so happens that the crystal structure of the saturated fat cocoa butter melts at about 97 degrees F which is approximately body temperature (the temperature in your mouth). Here is the fundamental idea of phase change. Given a constant concentration of a material--chocolate in this case--as temperature is varied, different phases (solid, liquid, vapor) are observed. The vapor phase of chocolate is not demonstrated or discussed... most people would consider this phase of chocolate to be too hot for any interest/use.

2) Surfactant/Emulsification: Although the authors do not use these words per say, this is the subject they address by asking the question, "Why does chocolate feel smooth in your mouth?" While this texture may be partially a result of cocoa solid particulate size, much of it is due to the emulsification process. As discussed by the authors, cocoa powder and cocoa butter (the two main ingredients of chocolate) do not readily mix; however, as evident by the mixing of hot chocolate or as the authors mention, chocolate milk, cocoa powder mixes well with water. This is reminiscent of last week's topic and wiki entry: surfactants. The cocoa powder is hydrophilic which, as we have discussed, does not mix well with fats/oils (cocoa butter). The emulsifier used in may chocolates is soy lecithin which is amphiphilic and thus a stabilizes the cocoa powder in the cocoa butter. Much of lecture considered the the mixing of oil and water but we also discussed the solid-oil interaction with oil soluble surfactant (image from lecture slide below). Here, the surfactant is soy lecithin, the solid is cocoa powder particles, and the oil is cocoa butter. As Stone et al suggest and as we have discussed, the adsorption onto the surface of the solid (cocoa powder) is driven by high head group/solid affinity while the stabilization of the system results from the hydrocarbon chain affinity with oil.

Choc 1.jpg

3)