Heat released by the reaction, q_rxn (J)

Use the equation q_rxn = –m_soln×C_soln× ΔT_soln. Assume the specific heat capacity of the reaction solution is the same as that of pure water, 4.184 J/g·°C.

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### Temperature Measurements 1. **Initial temperature (°C)**: 25.00 2. **Final temperature (°C)**: 31.37 --- ### Calculations 3. **Change in temperature of the reaction solution, \( \Delta T_{\text{soln}} \) (°C)**: 6.37 4. **Mass of the reaction solution, \( m_{\text{soln}} \) (g)**: - Add together the masses of the NaOH(aq) and HCl(aq). - Convert the volume of each solution to mass using 1.000 g/mL as the density (assuming these aqueous solutions have the same density as water). - **Mass**: 200 g 5. **Heat released by the reaction, \( q_{\text{rxn}} \) (J)**: - Use the equation \( q_{\text{rxn}} = -m_{\text{soln}} c_{\text{soln}} \Delta T_{\text{soln}} \). - Assume the specific heat capacity of the reaction solution is the same as that of pure water, 4.184 J/g°C. The calculations are structured into parts, providing step-by-step guidance for determining each variable and applying the heat equation.