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Consider the given data : (a) mathrmHCl(g) + 10mathrmH_2mathrmO(l)rightarrow mathrmHCl.10H_2O quad Delta mathrm H = - 6 9. 0 1 mathrm k J mathrm m o l ^ - 1 (b) mathrmHCl(g) + 40mathrmH_2mathrmO(l)rightarrow mathrmHCl.40H_2O quad Delta mathrm H = - 7 2. 7 9 mathrm k J mathrm m o l ^ - 1 Choose the correct statement :

Solution & Explanation

### Related Formula Delta H_textdilution = Delta H_2 - Delta H_1 ### Core Logic Analyzing the thermodynamic statements: - Delta H values are negative, so the dissolution of HCl(g) is clearly exothermic, eliminating option (1). - Since the enthalpy release changes when the moles of water solvent shift from 10 to 40 (-69.01 vs -72.79), the **heat of solution depends explicitly on the amount of solvent** (Statement 2 is true). - Let's check Statement 3: By subtracting equation (a) from (b): mathrmHClcdot10H_2O + 30mathrmH_2mathrmO rightarrow mathrmHClcdot40H_2O Delta H = -72.79 - (-69.01) = -3.78 mathrm~kJcdot mol^-1 The value is negative, indicating an exothermic process, so calling it +3.78 makes option (3) incorrect. ### Pattern Recognition The standard integral enthalpy of solution varies with solvent concentration until infinite dilution is achieved. Thus, concentration dependence is a core property of partial molar solution variables. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 11 Chemistry: Chemical Thermodynamics

More Chemical Thermodynamics Previous-Year Questions

Q38 2025 Thermodynamic Work and Reversible Processes
Arrange the following in order of magnitude of work done by the system / on the system at constant temperature : (a) |mathrmw_mathrmreversible| for expansion in infinite stage. (b) |mathrmw_mathrmirreversible| for expansion in single stage. (c) |mathrmw_mathrmreversible| for compression in infinite stage. (d) |mathrmw_mathrmirreversible| for compression in single stage. Choose the correct answer from the options given below:
  • A. a > b > c > d
  • B. mathrmd > mathrmc = mathrma > mathrmb
  • C. c = a > d > b
  • D. a > c > b > d

Solution

### Related Formula w_textrev = -nRT lnleft(fracV_mathrmfV_mathrmiright) w_textirrev = -P_textext left(V_mathrmf - V_mathrmiright) ### Core Logic For isothermal reversible and irreversible steps: 1. **Reversible Path**: Since a reversible compression path retraces the exact coordinates of the reversible expansion path, the magnitudes of work are equal: |w_textrev, expansion| = |w_textrev, compression| implies a = c
P-V indicator diagrams comparing reversible and irreversible expansion/compression
P-V indicator diagrams comparing reversible and irreversible expansion/compression
2. **Isothermal Expansion**: Reversible work magnitude is the maximum possible work. Hence, for expansion: |w_textrev, expansion| > |w_textirrev, expansion| implies a > b
P-V indicator diagrams comparing reversible and irreversible expansion/compression
P-V indicator diagrams comparing reversible and irreversible expansion/compression
3. **Isothermal Compression**: Irreversible compression requires more work than reversible compression because of sudden pressure adjustments against the surroundings: |w_textirrev, compression| > |w_textrev, compression| implies d > c
P-V indicator diagrams comparing reversible and irreversible expansion/compression
P-V indicator diagrams comparing reversible and irreversible expansion/compression
P-V indicator diagrams comparing reversible and irreversible expansion/compression
P-V indicator diagrams comparing reversible and irreversible expansion/compression
### Step 1: Combine the inequalities Combining the results: - We have a = c - We have d > c - We have a > b This leads to the strict inequality sequence: d > c = a > b ### Pattern Recognition Thermodynamics Principle: Reversible expansion is the most efficient (gives maximum work magnitude), whereas reversible compression is the most efficient (requires minimum work magnitude). Single-stage irreversible compression is always the least efficient, demanding the absolute highest work input. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 11 Chemistry: Chemical Thermodynamics
Q 2025 Ideal Gas Free Expansion
Two vessels A and B are connected via stopcock. The vessel A is filled with a gas at a certain pressure. The entire assembly is immersed in water and is allowed to come to thermal equilibrium with water. After opening the stopcock the gas from vessel A expands into vessel B and no change in temperature is observed in the thermometer. Which of the following statement is true?
Ideal Gas Free Expansion experimental setup diagram for Q31
The diagram displays a water bath calorimeter surrounding two interconnected glass flasks via a valve setup to demonstrate thermal expansion behavior.
  • A. (1)\ mathrmdw neq 0
  • B. (2)\ mathrmdq neq 0
  • C. (3)\ mathrmdU neq 0
  • D. (4)\ textThe pressure in the vessel B before opening the stopcock is zero.

Solution

### Related Formula First Law of Thermodynamics expression: mathrmdU = dq + dw ### Core Logic The system parameters show an isothermal transformation layout with zero overall heat transfer step: * No change in temperature signifies mathrmdT = 0, hence internal energy change for an ideal gas satisfies: mathrmdU = nC_vmathrmdT = 0 * Since it expands freely into an empty chamber (vessel B), external pressure P_textext = 0, meaning work done is: mathrmdw = -P_textextmathrmdV = 0 * Combining these parameters in the First Law gives mathrmdq = 0. * This classic situation of "free expansion" implies vessel B was completely evacuated initially. ### Step 1: Statement Verification Therefore, the pressure inside vessel B before opening the stopcock was precisely zero. ### Pattern Recognition Isothermal + expansion against no opposing force = Free Expansion. For free expansion of an ideal gas, always remember: w = 0, q = 0, and Delta U = 0 simultaneously. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 11 Chemistry: Chemical Thermodynamics
Q29 2025 Enthalpy Changes
Total enthalpy change for freezing of 1 mathrm~mol of water at 10^circ mathrmC to ice at -10^circ mathrmC is (Given: Delta_mathrmfusmathrmH = mathrmx kJ/mol, mathrmC_mathrmp[mathrmH_2mathrmO(ell)] = mathrmytext J mol^-1text K^-1, mathrmC_mathrmp[mathrmH_2mathrmO(texts)] = mathrmztext J mol^-1text K^-1)
  • A. -mathrmx - 10mathrmy - 10mathrmz
  • B. -10(100mathrmx + mathrmy + mathrmz)
  • C. 10(100mathrmx + mathrmy + mathrmz)
  • D. mathrmx - 10mathrmy - 10mathrmz

Solution

### Related Formula Delta H_texttotal = n C_p(ell) Delta T_1 - nDelta H_textfusion + n C_p(s) Delta T_2 ### Core Logic We need to compute the enthalpy change for the pathway: mathrmH_2O(ell, 10^circC) rightarrow mathrmH_2O(s, -10^circC) This can be divided into three consecutive steps: 1. Cool liquid water from 10^circC to 0^circC: Delta H_1 = n cdot C_p[mathrmH_2O(ell)] cdot (0 - 10) = 1 cdot y cdot (-10) = -10y text J 2. Freeze water to ice at 0^circC: Delta H_2 = -n cdot Delta_textfusH = -1 cdot x text kJ = -1000x text J 3. Cool ice from 0^circC to -10^circC: Delta H_3 = n cdot C_p[mathrmH_2O(s)] cdot (-10 - 0) = 1 cdot z cdot (-10) = -10z text J
Thermodynamics enthalpy cycle for freezing Q29
Thermodynamics enthalpy cycle for freezing Q29
Adding these three steps yields: Delta H_texttotal = -10y - 1000x - 10z = -10(100x + y + z) text Joule ### Pattern Recognition Freezing is an exothermic process, so all three steps (cooling water, freezing, and cooling ice) must carry a negative sign. Factoring out -10 cleanly yields the expression -10(100x+y+z). ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 11 Chemistry: Chemical Thermodynamics
Q46 2025 Resonance Energy
Resonance in an X_2Y molecule is represented as follows: X=X=Y longleftrightarrow X equiv X^+-Y^- The experimental enthalpy of formation for gaseous X_2Y is given by the reaction: X equiv X(g) + frac12Y=Y(g) longrightarrow X_2Y(g) quad Delta H_f(textexp) = 80 text kJ mol^-1 Calculate the magnitude of the resonance energy of X_2Y in textkJ mol^-1 (as the nearest integer value). Given bond energies: * X equiv X = 940 text kJ mol^-1 * X = X = 410 text kJ mol^-1 * Y = Y = 500 text kJ mol^-1 * X = Y = 602 text kJ mol^-1 Valence settings: X:3, Y:2.
Numerical Answer. Answer: 98 to 98

Solution

### Related Formula Resonance energy equation related to experimental and theoretical formation enthalpies: Delta H_textR.E. = Delta H_f(textexp) - Delta H_f(textTheo) Theoretical enthalpy calculation using bond energies: Delta H_f(textTheo) = sum textB.E._textreactants - sum textB.E._textproducts ### Execution Step 1: Write the chemical equation to calculate the theoretical enthalpy of formation based on the localized structure X=X=Y: X equiv X(g) + frac12Y=Y(g) longrightarrow X=X=Y(g) Step 2: Substitute the localized bond energies into the reactant-minus-product relation: Delta H_f(textTheo) = left[ textB.E._X equiv X + frac12textB.E._Y=Y right] - left[ textB.E._X=X + textB.E._X=Y right] Delta H_f(textTheo) = left[ 940 + frac12(500) right] - [410 + 602] Delta H_f(textTheo) = [940 + 250] - 1012 = 1190 - 1012 = 178 text kJ mol^-1 Step 3: Calculate the resonance energy: Delta H_textR.E. = Delta H_f(textexp) - Delta H_f(textTheo) = 80 - 178 = -98 text kJ mol^-1 Taking the magnitude as requested: |Delta H_textR.E.| = 98. ### Pattern Recognition Resonance energy is always a stabilizing factor, meaning Delta H_f(textexp) is more exothermic (or less endothermic) than the theoretical localized state. The magnitude is simply the absolute value of this difference (|80 - 178| = 98). ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 11 Chemistry: Chemical Thermodynamics Class 11 Chemistry: Chemical Bonding and Molecular Structure
Q34 2025 Phase Equilibrium and Le Chatelier's Principle
Ice and water are placed in a closed container at a pressure of 1 atm and temperature 273.15mathrmK . If pressure of the system is increased 2 times, keeping temperature constant, then identify correct observation from following:
  • A. textVolume of system increases.
  • B. textLiquid phase disappears completely.
  • C. textThe amount of ice decreases.
  • D. textThe solid phase (ice) disappears completely.

Solution

### Core Logic Water has a unique property where the density of the liquid phase is greater than the density of the solid phase (ice). Consequently, the molar volume of ice is larger than that of liquid water: V_m(textice) > V_m(textwater) According to Le Chatelier's Principle, increasing the pressure favors the phase that occupies a smaller volume to alleviate the applied stress. Thus, shifting the system forward converts ice into liquid water:
Phase shift diagram for Q34 - JEE Main 2025 Morning
Phase shift diagram for Q34 - JEE Main 2025 Morning
If the pressure is increased considerably (such as doubling it to 2 atm) at 273.15mathrmK, the melting point decreases, causing the entire solid phase (ice) to disappear completely. ### Pattern Recognition Sees: Ice-water system under pressure change. Trap: Assuming that an increase in pressure always favors the solid phase. Water has an anomalous phase curve with a negative slope. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 11 Chemistry: Chemical Thermodynamics

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