I need to arive to target

And al Delta H you will see in the photos and must use the graph

positive. If a negative value for the heat capacity is obtained, then C should be adjusted to zero. In this Lab In Part A of the experiment, { for the acid-base neutralization reaction is calculated. H'(aq) + OH-(aq) → H20(1) Δ.Hne.-? The heat produced in the neutralization reaction is absorbed by the calorimeter and the solution, composed of HCI and NaOH Since the solution was created by mixing HCI and NaOH, the Qun, can be broken down. to give: We will assume the specific heats of NaOH and HCI solutions are the same as water 4.18 J/(g × ℃). The mass of the HCl solution is collected in step 3. The mass of the NaOH solution is calculated from the volume used in step 6 and the density 1.083 g/mL. T, and T, for solutions are both taken from the graph (for details, see graph analysis) and To is the original measured temperature of the NaOH solution, step 4: Quici = 4. 18 J/(g ×°C) × mass ofHCI solution in g × (Tf-T0°C Qwaon® 4. 18 JOg ×。CJX mass of NaOH solution in g × (Tf-TJ oc

We can use this to solve for the heat capacity of our calorimeter, C, by using AT: qcalorimeter = C × (Tf-T) °C The heat capacity of the calorimeter will probably be a rather small number but it should be positive. If a negative value for the heat capacity is obtained, then C should be adjusted to zero, In this Lab In Part A of the experiment, for the acid-base neutralization reaction is calculated. H'(aq) + OH-(aq) → H20の dHncu" ? The heat produced in the neutralization reaction is absorbed by the calorimeter and the solution, composed of HCI and NaOH. Since the solution was created by mixing HCI and NaOH, the quoln Can be broken down, to give: We will assume the specific heats of NaOH and HCI solutions are the same as water, 4. 18 J/(g × °C). The mass of the HCI solution is collected in step 3, The mass of the NaOH solution is calculated from the volume used in step 6 and the density 1.083 g/mL. T and T, for solutions are both taken from the graph (for details, see graph analysis) and To is the original measured temperature of the NaOH solution, step 4: qHC1-4, 18 J/(g × "O × mass of HCl solution in g × (Tf-T) °C Qwaon® 4. 18 JOg × °C) × mass of NaOH solution in g × (Tr_TJ °C qcalonmeter-c × (T-T) °C

5. 0.20 L of a 0.40 M HCI is totally reacted with 0.20 L of a NaOH solution in a Styrofoam coffee cup. The temperature of both solutions before mixing is 25.1 °C and 26.6 °C after. Assume that both the HCI and the NaOH solutions have a density of 1.00 g/mL, the heat absorbed by the cup is negligible, and the specific heat capacity of the solutions is 4.18 J/g C. Calculate the heat released per mol HCl in this neutralization reaction. (Hint: How many moles of HCI was reacted in the experiment?)

of Neutralization for an Acid-Base Reaction B. Enthalpy adea) HNO, NaOH HCI NaOH Trial 2 Trial 2 Trial 1 Trial 1 1. Volume of acid (mL) 2. Temperature of acid 3. Volume of NaOH (mL) 4. Temperature of NaoH 5. Exact molar concentration of NaoH (moUL) 6. Maximum temperature from graph (°C) 7. Instructor's approval of graph Calculations for Enthalpy GHea) of Neutralization for an Acid-Base Reaction 1. Average initial temperature of acid and NaoH CC) 55 2. Temperature change, ATCC 3. Volume of final mixture (ml) 4. Mass of final mixture (g)(Assume the density of the solution is 1.0 g/mL) 5. Specific heat of mixture 4.18 J/g. C 4.18 J/g PC 6. Heat evolved (J) 7. Moles of OH reacted, the limiting reactant (mol) 8. Moles of H2O formed (mol) 9. AH (klhnol equation 25.8 10. Average AH, (kWhnol H,o) .show calculations for Trial i using the correct number of significant figures. Comment on your two values of AH,