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Thermochemistry

We will begin lab in the amphitheatre of DBH

Objective

  • To explore heat transfer through calorimetry.
  • To use calorimetry to determine the enthalpy of reaction of a strong acid and a strong base.
  • To use Hess's Law of Heat Summation to determine the heat of hydration in calcium chloride.
  • To explore a common use of heat of reaction in real life.

Grading

  • Pre-Lab (10%)
  • Lab Report Form (80%)
  • TA Points (10%)

Background information

When two objects at different temperatures are brought into physical contact, thermal energy will spontaneously transfer from the warmer object to the colder object until both objects have achieved the same temperature. Assuming the two objects are thermally insulated from their surroundings, the heat lost by the warm object is identical to the heat gained by the cold object. This is a manifestation of the Law of Conservation of Energy.

The heat transfer, q, is a function of the mass of the object (m), the change in temperature undergone by the object ( ΔT size 12{ΔT} {} ) and the object's specific heat ( C s size 12{C rSub { size 8{s} } } {} ). This statement can be expressed mathematically as

q = mC s ΔT size 12{ ital "mC" rSub { size 8{s} }ΔT} {}

Temperature change is always defined as T final size 12{T rSub { size 8{ ital "final"} } } {} - T initial size 12{T rSub { size 8{ ital "initial"} } } {} , which means that q for the hotter object ( q hot size 12{q rSub { size 8{ ital "hot"} } } {} ) is negative and q for the colder object ( q cold size 12{q rSub { size 8{ ital "cold"} } } {} ) is positive. If energy is conserved, then

q hot size 12{q rSub { size 8{ ital "hot"} } } {} + q cold size 12{q rSub { size 8{ ital "cold"} } } {} = 0

and

( mC s ΔT size 12{ ital "mC" rSub { size 8{s} }ΔT} {} ) hot size 12{ {} rSub { size 8{ ital "hot"} } } {} + ( mC s ΔT size 12{ ital "mC" rSub { size 8{s} }ΔT} {} ) cold size 12{ {} rSub { size 8{ ital "cold"} } } {} = 0

Now consider dropping an ice cube into water just warm enough to melt the ice cube but not warm enough to further heat the water from the cube. The observation is that the ice cube melts and the warm water cools to 0 ° size 12{0°} {} C. It is important to recognize that during the phase change, the temperature of the ice cube does not change. Therefore, it is not possible to use the preceding equation to determine the heat transferred. Rather, the energy transferred to the ice cube from the warm water affects the phase change. The energy equation is now adjusted to incorporate the enthalpy required to melt the ice cube, ΔH f size 12{ΔH rSub { size 8{f} } } {} (where f stands for fusion):

( mC s ΔT size 12{ ital "mC" rSub { size 8{s} }ΔT} {} ) warm size 12{ {} rSub { size 8{ ital "warm"} } } {} + ΔH f size 12{ΔH rSub { size 8{f} } } {} = 0

It is also possible to have thermal energy when chemical reactions occur. The amount and direction of heat flow is dependant on the chemicals reacting. Using a calorimeter, it is possible to experimentally determine the heat of reaction.

Calorimetry

In the technique known as constant-pressure calorimetry, enthalpies of phase changes or chemical reactions are determined indirectly by measuring temperature (at constant pressure) changes in a medium, most often water, surrounding the materials undergoing the change. That is, by measuring ΔT size 12{ΔT} {} of the water one can use the preceding equation to calculate ΔH size 12{ΔH} {} for the process of interest. Of course, this means one must know the mass of the water used and water's specific heat: C water size 12{C rSub { size 8{ ital "water"} } } {} = 4.18 J/(gK).

Today in Part I, you will add a strong base to a strong acid, measure the temperature change in the water as the two react, and use that information to calculate the heat of reaction per gram of NaOH. Then convert your experimental value into an enthalpy in kJ/mol (of NaOH).

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Source:  OpenStax, Gen chem lab. OpenStax CNX. Oct 12, 2009 Download for free at http://cnx.org/content/col10452/1.51
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