Erstellt von Amelia Claire
vor mehr als 8 Jahre
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Frage | Antworten |
Conservation of Energy 1st Law of Thermodynamics | Energy can neither be created nor destroyed - it can only change form The total Energy of the universe is constant = 1st Law of Thermodynamics |
System | System = part of universe under study (e.g. - chemicals in a flask) |
Surroundings | Surroundings = the rest of the universe (or as much as needed (e.g. - the flask) |
Universe | Universe = System + Surrounds |
Internal Energy | Internal Energy depends on: Temperature Type of material (mass and particles) Amount of material (number of particles) |
Calculating Thermodynamic Changes | Energy change of a final system = ΔE = E final - E initial |
ΔE positive : internal energy increases | |
ΔE negative : internal energy decreases | |
Heat Capacity | Heat capacity = E required to raise the T(temperature) of an object by 1°C Specific Heat Capacity = E required to heat 1 gram of substance by 1°C Molar Heat Capacity = E required to heat 1 mole of substance by 1°C |
Specific Heat | Energy required to change Temp of an object is: Heat required = mass x specific heat x ΔTq = m c ΔT or… Heat required = moles x molar heat capacity x ΔT q = n cm ΔT |
When heat is ADDED to a system | q (heat) is positive the change is endothermic temperature decreases (liquid water boils to become gaseous water) |
When heat is REMOVED from a system | q (heat) is negative the change is exothermic temperature increases (gaseous water condenses to become liquid water) |
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