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Does the Scent of a Candle Affect the Amount of Energy Released?

Does the Scent of a Candle Affect the Amount of Energy Released?. Hannah Sisk Academy of Notre Dame. Hypothesis. The scent of a candle will affect the amount of energy released. Scented candles will produce more energy than un-scented candles.

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Does the Scent of a Candle Affect the Amount of Energy Released?

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  1. Does the Scent of a Candle Affect the Amount of Energy Released? Hannah Sisk Academy of Notre Dame

  2. Hypothesis • The scent of a candle will affect the amount of energy released. • Scented candles will produce more energy than un-scented candles. • Scented candles include more ingredients than un-scented candles, therefore containing more substances to be released while burning.

  3. Materials • 4 unscented candles (“white”) • 4 Vanilla Cookie (“yellow”) scented candles • 4 Pomegranate (“red”) scented candles • 4 Mid-Summer’s Night (“black”) scented candles • Can (large enough to hold 400. mL of liquid) • Larger can ( 15 ½ cm diameter), open at both ends • Duct tape • 6.40 x 103 mL distilled water • Temperature probe (or thermometer) • Ring stand • Candle lighter

  4. Procedure • Wrap duct tape around both cans until completely covered for insulation. • Measure 400.mL distilled water • Pour into smaller can. • Place can in ring stand. • Place temperature probe into water and record the temperature. • Place an un-scented candle below the suspended can so that, when lit, the candle’s flame will be about 2 cm below the can. • Take the larger can and place around the suspended can and un-scented candle for insulation. • Light the candle using the “candle lighter” • Continue to record the rising temperature for 10 minutes (recording the temperature every 15 seconds). • After the ten minutes of burning, blow out candle • Record the final temperature. • Repeat 1-11 for each candle (4 candles of each scent, so 4 times for each different scent).

  5. Apparatus

  6. Calculations • Heat transferred in a reaction is equal in magnitude, but opposite in sign to the heat absorbed by the surroundings qsur = m x C x (Tf – Ti) qsur - heat absorbed by surroundings m – mass of water (g) C – specific heat of water (1 calorie/g.oC) Tf – final temperature of water (oC) Ti – initial temperature of water (oC) • Joule Conversion 1 joule =(number of calories)(4.184)

  7. T-Test Results This table shows the results from the T-tests, comparing the unscented candles to each, different group of scented candles. Notice that each one of the results is less than .05 (some even lower than .001). This suggests that there is a significant difference between each data pair.

  8. Limitations • Only four candles were tested for each scent • T-TEST works best with five or more data points • Some heat was lost during the process • Apparatus construction Further Studies • test more scents • compare colored, unscented candles to white, unscented ones. • compare energy released from unscented-colored candles, to candles of the same color, but scented.

  9. Conclusion • Partial Support of Hypothesis • Scent does affect heat given off • Unscented candles give off more heat in a shorter period of time than scented ones do (contradicts hypothesis)

  10. Resources • Arnold, Brian (2003, September 22). Energy and energy changes. The Hutchinson Encyclopedia of Science. Retrieved November 13, 2005 from eLibrary database. • Calorimetry. (1996). In Chemistry : connections to our changing world (pp.     393-396). Upper Saddle River, NJ: Prentice-Hall. • Energy. (2003, December 1). Compton’s by Britannica. Retrieved November 13, 2005 from eLibrary database. • Farabee, M., J. (2001). Laws of thermodynamics. Retrieved November 13, 2005 from http://www.emc.maricopa.edu/faculty/farabee/BIOBK/BioBookEner1.html • The Free Dictionary (Calorimeter). (2005). Retrieved November 13, 2005 from • http://www.thefreedictonary.com/calorimeter • Physics: heat and temperature. (1995, January 1). The New York Public Library Science Desk Reference. Retrieved November 10, 2005 from eLibrary database. • Wikipedia, the free encyclopedia (Calorimeter) (2005 November 4, 2005). Retrieved November 13, 2005 from http://en.wikipedia.org/wiki/Calorimeter

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