1 / 12

ThermoChem Class #4 – Calorimetry

ThermoChem Class #4 – Calorimetry OB: how is energy in food measured? (It’s the “bomb”!) You will need a calculator and your thinking hat now.

bernie
Download Presentation

ThermoChem Class #4 – Calorimetry

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. ThermoChem Class #4 – Calorimetry OB: how is energy in food measured? (It’s the “bomb”!) You will need a calculator and your thinking hat now

  2. By Law, all food sold in the USA has to have a food Nutrition Label, with one of the “facts” being the Caloric Content, how much energy are you eating, put onto the package. It takes a special machine, and careful measurements, and fancy mathematics and conversions, to calculate this data. In our Dorito’s Lab tomorrow, we will attempt to measure the energy content in the chips, and compare it to the nutrition label on the package.

  3. Let’s Convert those 450. Calories (3 SF) into Joules now.

  4. Let’s Convert those 450. Calories (3 SF) into Joules now. 450. C1 X • 1000 cal1C = 450,000 cal 450,000 cal1 • 4.18 Joules1 cal X = 1,880,000 J An person emits about 100 Joules of energy/SECOND.You might imagine this: a WATT of energy is one Joule/second. A 100 Watt bulb uses 100 Joules/second.

  5. There is no easy way to directly measure the energy that is in food. An indirect way has been well figured out, using a machine called a calorimeter. The food is burned up in a sealed box containing oxygen, and the heat that it gives off, the energy that is inside the food, is used to heat pure water. This water is carefully measured, and the energy gained by the water changes its temperature. This temperature change is pushed through our q = mC∆T formula, and you can calculate the number of joules it took to heat up the water, and then convert the joules into cal, then into calories. It seems harder than it is, but it is easy enough to do tomorrow. In our Dorito’s Lab we will use a five cent calorimter machine. Real calorimeters are much more complex, and insulated. They measure all of the energy gain, we will “do” the same thing, but MOST of our energy will get lost to the air. We’ll do the same process, just get poor results. Terrible measuring, great learning!

  6. Let’s draw and label a calorimeter now. Picture on next slide.

  7. Food goes into the cup. It’s sealed in the “bomb” with oxygen. The electricity leads are attached. This is placed into a certain mass of pure water, at measured temperature. The stirrer moves the water around and makes sure it’s all at the same temperature. At some point you spark and burn the food. Heat is released into the water and the temperature rises. Using q = mC∆T, calculate the number joules required to make that temperature change, convert to cal, then Calories.

  8. Let’s assume that there is exactly 2120. mL of water in our bomb calorimeter and it’s at exactly 295.0 Kelvin. After burning up our food sample, the temperature of the water rises to 354.5 Kelvin. How many Calories of energy are in this food sample? To do this, start with the q = mC∆T formula. Solve for q.

  9. Let’s assume that there is exactly 2120. mL of water in our bomb calorimeter and it’s at exactly 295.0 Kelvin. After burning up our food sample, the temperature of the water rises to 354.5 Kelvin. How many Calories of energy are in this food sample? To do this, start with the q = mC∆T formula. Solve for q. q = mC∆T q = (2120. g)(4.18 J/g·K)(59.50 K) q = 527,265.2 J • 1 cal4.18 J 527,265.2 J1 X = 126,140 cal • 126,140 cal = 126.1 Calories (4 SF)

  10. In a different calorimeter you measure some food energy content. You have exactly 4005 mL of pure water at 274.2 Kelvin and it warms up to 365.4 Kelvin when you burn up 50.0 grams of chocolate delight dessert. What is the Calorie content of the dessert?

  11. In a different calorimeter you measure some food energy content. You have exactly 4005 mL of pure water at 274.2 Kelvin and it warms up to 365.4 Kelvin when you burn up 50.0 grams of chocolate delight dessert. What is the Calorie content of the dessert? • q = mC∆T • q = (4005. g)(4.18 J/g·K)(91.20 K) • q = 1,526,770.08 Joules • 1 cal4.18 J 1,526,770.08 J1 X = 365,256 cal • 365,256 cal = 365.3 Calories (4 SF)

  12. Due Tuesday ThermoChem HW #4 NUMBER FOUR not 2! Read your ThermoChem Diary (or else) Tomorrow, a really fun, stinky, and tasty lab!

More Related