Heat liberated(q) = C*DT
C = Heat capacity of calorimeter = 2.3 kj/c
DT = 28.5-25.0 = 3.5
q = 2.3*3.5 = 8.05 kjoule
q = 8.05 kj
n = No of mole of hydrocarbon burned = 0.233/114.23 = 0.00204 mole
DHrxn = - q/n
= - 8.05/0.00204
= -3947 kj/mol
answer: -3950
A0.233 g sample of a hydrocarbon (MM-114.23 g/mol) is burned in a bomb calorimeter that has...
When 0.0801 mol of an unknown hydrocarbon is burned in a bomb calorimeter, the calorimeter increases in temperature by 2.19°C. If the heat capacity of the bomb calorimeter is 1.229 kJ/°C, what is the heat of combustion for the unknown hydrocarbon?
Question 3 of 20 When 0.0701 mol of an unknown hydrocarbon is burned in a bomb calorimeter, the calorimeter increases in temperature by 2.19°C. If the heat capacity of the bomb calorimeter is 1.229 kJ/°C, what is the heat of combustion for the unknown hydrocarbon?
155 grams of a hydrocarbon (C20H62) is burned in a bomb calorimeter that has a calorimeter constant of 3250.0 J/oC The calorimeter undergoes a 1.95 oC temperature increase as the hydrocarbon is burned. Determine the hydrocarbon's heat of combustion, ΔHcomb in kJ/mol. (Closest answer)
A 0.54 g sample of fructose (MW = 180. g/mol) is burned in a bomb calorimeter that has a heat capacity of 2.69 kJ/oC. The temperature of the calorimeter increases by 3.16oC. Calculate the molar heat of combustion of fructose using the data from this experiment. Since this experiment is carried out under conditions of constant volume, we are measuring ∆E. Your answer should be in kJ/mol and entered to 3 sig. fig. ∆E=?
A 0.37 g sample of fructose (MW = 180. g/mol) is burned in a bomb calorimeter that has a heat capacity of 2.69 kJ/oC. The temperature of the calorimeter increases by 2.16oC. Calculate the molar heat of combustion of fructose using the data from this experiment. Since this experiment is carried out under conditions of constant volume, we are measuring ∆E. Your answer should be in kJ/mol and entered to 3 sig. fig. ΔE =
A 0.44 mol sample of a substance is burned in a bomb calorimeter with a heat capacity of 8.87 kJ/C. The temperature increases by 8.36 C. What is ΔHrxn (in kJ/mol) for the combustion of the substance?
A 0.437-g sample of benzil (C4HO2) is burned in a bomb calorimeter and the temperature increases from 24.50 C to 27.30 C. The calorimeter contains 1.04x10^3 g of water and the bomb has a heat capacity of 884 JC. Based on this experiment, calculate AE for the combustion reaction per mole of benzil burned (k/mol)
When 1.986 grams of sucrose (Molar mass 342.3 g/mol) is burned in a bomb calorimeter, the temperature of the calorimeter increases from 22.41°C to 26.63°C. If the heat capacity of the calorimeter is 4.900 kJ/°C, what is the heat of combustion of sucrose?
A 0.539-g sample of quinizarin (C14H8O4) is burned in a bomb calorimeter and the temperature increases from 24.70 °C to 27.00 °C. The calorimeter contains 1.19×103 g of water and the bomb has a heat capacity of 912 J/°C. Based on this experiment, calculate ΔE for the combustion reaction per mole of quinizarin burned (kJ/mol). C14H8O4(s) + 14 O2(g) 14 CO2(g) + 4 H2O(l) E = kJ/mol
A 0.2075−g sample of solid magnesium is burned in a constant-volume bomb calorimeter that has a heat capacity of 3024 J/°C. The temperature increases by 1.700°C. (a) Calculate the heat given off by the burning Mg in kJ/g. kJ/g (b) Calculate the heat given off by the burning Mg in kJ/mol. kJ/mol