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This section includes 7 InterviewSolutions, each offering curated multiple-choice questions to sharpen your Current Affairs knowledge and support exam preparation. Choose a topic below to get started.
| 1. |
Molarity of a given orthophosphoric acid solution is 3 M. Its normalityis |
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Answer» Solution :MOLARITY of orthophosphoric ACID = 3 M Now, basicity of orthophosphoric acid `(H_(3)PO_(4)) = 3` `therefore` Normality of orthophosphoric acid = `3 xx 3N = 9N` |
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| 2. |
Molarity of 0.2 N H_(2)SO_(4) is |
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Answer» `0.2` i.e., Molarity = 0.2/2 = 0.1 |
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| 3. |
Molarity of 1m aqueous NaOH solution [density of the solution is 1.02 g/ml] |
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Answer» 1M |
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| 4. |
Molarity of 0.2 N H_(2) SO_(4) is |
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Answer» A) 0.2 |
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| 5. |
Molarity is related to molality (m) , density of the solution (d) and molar mass of the solute (M^(@)) by which of following relation. |
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Answer» `M=(10MD)/(M^(@))` |
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| 6. |
Molarity (M), molality (m), and mole (x) are some methods for expressing concentration of solutions. Which of these are temperature independent ? |
| Answer» SOLUTION :MOLALITY, MOLE FRACTION | |
| 7. |
Molarity is expressed in gram/litre |
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Answer» litre/mol |
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| 8. |
Molarity is |
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Answer» the NUMBER of moles of SOLUTE present in `1 dm^(3)` volume of solution `"Molarity (M)"=("Number of moles of solute")/("Volume of solution (in L ordm"^(3)")")` |
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| 9. |
Molar masses of salutes are best measured from osmeticpressure. Why? |
| Answer» Solution : Compared to other COLLIGATIVE properties, magnitude of OSMOTIC pressure is large, even for very dilute solutions. Determination of molar masses is particularly useful for polymers as they have poor solubility and for BIOMOLECULES as they are unstable at HIGHER TEMPERATURES. | |
| 10. |
Molar ionic conductivities of a two-bivalent electrolytes x ^(2+) and y ^(2-)are 57 and 73 respectively. The molar conductivity of the solution formed by them will be |
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Answer» 130 S `cm^(2) MOL^(-1)` |
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| 11. |
Molar mas sof an ideal gas can be calculated from the relation. |
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Answer» `M = ( pd)/( RT )` |
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| 12. |
Molar ionic conductivities of a bivalent electrolyte are 57 and 73. The molar conductivity of the solution will be |
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Answer» `130 S cm^(2) MOL^(-1)` |
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| 13. |
Molar heat of vapourisation of a liquid is 6kJ"mol"^(1) . If the entopy change is 16 J"mol"^(-1)K^(-1), the boiling point of the liquid is :- |
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Answer» `375^(@)C` |
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| 14. |
Molar heat of vaporization of a liquid is 6kJ mol^(-1). If the entropy change is 16 J mol^(-1) K^(-1), the boiling point of the liquid is |
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Answer» `375^(@)C` `T_(b.p.)=(DeltaH_("vapour"))/(DeltaS_("vapour"))=(6xx1000)/(16)=375 K`. |
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| 15. |
Molar heat of vaporisation of a liquid is 6 kJ mol^(-1). If the entropy change is 16 J mol^(-1) K^(-1) the boiling point of the liquid is |
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Answer» A) `375^(@)C` `T_(b.p.)=(/_\H_("vapour"))/(/_\S_("vapour")=((6xx1000)/(16))=375k` |
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| 16. |
Molar heat of neutralization of NaOH with HCl in comparison to that of KOH with HNO_(3) is |
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Answer» Less |
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| 17. |
Molar heat capacity of water in equilibrium with the ice at constant pressure is: |
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Answer» ZERO |
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| 18. |
Molar heat capacity of water in equilibrium with ice at costant pressure is |
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Answer» ZERO |
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| 19. |
Molar heat capacityof water inequilibriumwith ice at canstantpressure is |
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Answer» zero |
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| 20. |
Molar heat capacity of water at equilibrium with ice at constant pressure is : |
| Answer» Answer :B | |
| 21. |
Molar heat capacity of ethenol is 110.4 JK^(-1) mol^(-1). Its specific heat capacity is |
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Answer» 2.4 `= (110.4 JK)/(46)` `= 2.4 JK^(-1) mol^(-1)` |
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| 22. |
Molar heat capacity of CD_(2)O (deuterated form of formaldehyde) at constant pressure in 9 cal mol^(-1) K^(-1) at 1000K. Calculate the entropy change associated with cooling of 3.2 g of CD_(2)O vapour from 1000 to 900K. |
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Answer» `-0.1 "cal"K^(-1)` `CD_(2)O=mSDeltaT=3.2/32xx14xx100=140` cal `:.` Cooling is exothermic `Dletah=-140` cal Now `DELTAS=(DeltaH)/T=-140/900=-0.15"cal"K^(-1)` |
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| 23. |
Molar heat capacity of aluminium is 25 JK^(-1)mol^(-1). The heat necessary to raise the temperature of 54 g of aluminium (Atomic mass 27gmol^(-1)) from 30^(@)C to 50^(@)C is |
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Answer» 1.5 KJ `=2xx25xx20=1000 J` Q=1.0 kJ. |
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| 24. |
molar heat capacity of Aluminium is 25 JK^(-1)mol^(-1)the heat necessary to raise the temperature of 54 gram of aluminium (atomic mass 27 g mol^(-1))from 30°C to 50°C is |
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Answer» 1.5kJ |
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| 25. |
Molar heat capacity of aluminium is 25 JK^(-1) mol^(-1). The heat necessary to raise the temperature of 54 g of aluminium (atomic mass 27 g mol^(-1)) from 30^(@)C to 50^(@)C is |
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Answer» 1.5 kJ `N = (54)/(27) = 2 MOL`, `Delta T = 50 - 30 = 20^(@)` `Q = 2 mol xx 25 JK^(-1) mol^(-1) xx 20 K` = 1000 J = 1.0 kJ |
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| 26. |
Molar enthalpy change for vaporisation of 1 mole of water at 1 bar and 100^(@)C is 41 kJ mol^(-1) (If water vapour is assumed to be perfect gas). Find out of the internal energy change. If 1 mole of water is vaporised at 1 bar pressure and 100^(@)C. |
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Answer» `+37.904kJmol^(-1)` `DeltaH=DeltaU+Deltan_(g)RT` `DeltaU=41.00" KJ "mol^(-1)-8.3JK^(-1)mol^(-1)xx373K` `=41.00-3.096" kJ "mol^(-1)=37.904" kJ "mol^(-1)` |
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| 27. |
Molar heat capacity is given by: |
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Answer» dQ/dT |
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| 28. |
Molar heat capacity of a gas at constant temperature and pressure is: |
| Answer» Answer :C | |
| 29. |
Molar heat capacity at constant volume can be given a |
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Answer» `C_(V)=(DE)/(DT)` |
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| 30. |
Molar heat capacity at constant P for substance is equal to: |
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Answer» <P>`(deltaE//deltaT)_v` |
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| 31. |
Molar conductivity of KCl, NaCl and KNO_(3) are 150, 126 and 109 SC m^(2)mol^(-1) respectively, then what is the molar conductivity of NaNO_(3) ? |
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Answer» 385 S `cm^(2)mol^(-1)` `=126-109-150` =85 S `cm^(2)mol^(-1)` |
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| 32. |
Molar conductivity of ionic solution depends on_____. |
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Answer» temperature |
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| 33. |
Molar conductivity of ionic solution depends on………. 1) Temperature 2) Distance between electrodes. 3) Concentration of electrolytes in solution. 4) Surface area of electrodes. |
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Answer» 1 & 2 |
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| 34. |
Molar conductivity of ionic solution depends on ______ |
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Answer» TEMPERATURE (A) As temperature increases, molar conductivity increases. (B) Molar conductivity increases with decrease in concentration. |
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| 35. |
Molar conductivity of an electrolyte is the conductance of all the ions produced by one gram mole of the electrolyte in solution and is denoted as Lambda_(m). Lambda_(m)=(kxx1000)/(c ) Here k is the specific conductance while c is the molar concentration of the electrolyte. The molar conductance of the strong electrolytes at infinite dilution (Lambda_(m)^(oo)) can be obtained graphically by extrapolation while the same for weak electrolytes cannot be obtained graphically. It can be calculated theoretically with the help of Kohrausch's. Law. Lambda_(m(AxBy))^(oo)=xlambda_(m (A^(y+)))^(oo)+ylambda_(m(B^(x)))^(oo) Which of the following solution of KCl will have the maximum value of specific conductance ? |
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Answer» 1.0 N |
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| 36. |
Molar conductivity of Ba^(2+) and Cl^(-1) ions present in aqueous solution of BaCl_(2) are 127.32"S"cm^(2)mol^(-1) and 76.34" S "cm^(2)mol^(-1) respectively, then what is Lamda_(m) of BaCl_(2) solutioin ? |
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Answer» `280" S "CM^(2)mol^(-1)` `=127.32+2xx76.34` `=280" S "cm^(2)mol^(-1)`. |
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| 37. |
Molar conductivity of an electrolyte is the conductance of all the ions produced by one gram mole of the electrolyte in solution and is denoted as Lambda_(m). Lambda_(m)=(kxx1000)/(c ) Here k is the specific conductance while c is the molar concentration of the electrolyte. The molar conductance of the strong electrolytes at infinite dilution (Lambda_(m)^(oo)) can be obtained graphically by extrapolation while the same for weak electrolytes cannot be obtained graphically. It can be calculated theoretically with the help of Kohrausch's. Law. Lambda_(m(AxBy))^(oo)=xlambda_(m (A^(y+)))^(oo)+ylambda_(m(B^(x)))^(oo) Equivalent conductance of 1 M methanoic acid solution is 10" ohm"^(-1)cm^(2)" equiv"^(-1) and at infinite dilution it is 200" ohym"^(-1)cm^(2)" equiv"^(-1). The pH of methanoic acid solution is : |
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Answer» 7 `[H^(+)]= C alpha=1Mxx0.05=0.05 M` `pH=-LOG [H^(+)]=-log(0.05)` `=-log(5xx10^(-2))=(2-log 5)` =2-0.6990=1.3 |
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| 38. |
Molar conductivity of an electrolyte is the conductance of all the ions produced by one gram mole of the electrolyte in solution and is denoted as Lambda_(m). Lambda_(m)=(kxx1000)/(c ) Here k is the specific conductance while c is the molar concentration of the electrolyte. The molar conductance of the strong electrolytes at infinite dilution (Lambda_(m)^(oo)) can be obtained graphically by extrapolation while the same for weak electrolytes cannot be obtained graphically. It can be calculated theoretically with the help of Kohrausch's. Law. Lambda_(m(AxBy))^(oo)=xlambda_(m (A^(y+)))^(oo)+ylambda_(m(B^(x)))^(oo) 48250 C of electricity was required to deposit all the copper present in 0.5 L of CuSO_(4) solution using inert electrodes. The molarity of solution was (Assume volume constant). |
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Answer» 0.50 M `2xx96500" C"` of charge deposit Cu=63 g 48250 C of charge deposit Cu `=((63 g)xx(48250" C"))/((2xx96500" C"))=15.75" g"`b Molarity (M)`=(((15.75 g))/((63.0 g" MOL"^(-1))))/((0.5 L))` =0.5 mol `L^(-1)`=0.5 M |
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| 39. |
Molar conductivity of a solution is 1.26 xx 10^(2)Omega^(-1) cm^(2) "mol""^(-1). Its molarity is 0.01M. Its specific conductivity will be |
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Answer» `1.26xx10^(-5)` |
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| 40. |
Molar conductivity (^^_m) is defined as conducting power of the ions produced by 1 mole of an electrolyte in a solution. ^^_m =(K)/(C) where K is conductivity (in S-cm^(-1)), ^^_m is molar conductivity (in Scm^(2) mol^(-1)) and C is molar concontration (in "mole"//cm^(3)) The molar conductivity of 0.04 M solution of MgCl_2 is 200Scm^2 mol^(-1) at 298 K. A cell with electrodesthat are 2.0cm^(2) in surface area and 0.50 cm apart is filled with MgCl_2 solution. The cell constant is |
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Answer» `8 xx 10^(-3) S cm^(-1)` |
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| 41. |
Molar conductivity(L) mof aqueous solution of sodium stearate, which behaves as a strong electrolyte, is recorded at varying concentrations (c) of sodium stearate. Which one of the following plots provides the correct representation of micelle formation in the solution? (Critical micelle concentration (CMC) is marked with an arrow in the figures) |
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Answer»
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| 42. |
Molar conductivity increases with dilution. Is the above statement true? Justify your answer |
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Answer» Solution :Yes, the above given statement is TRUE. When the DILUTION increases, the ions are far APART and the attractive forces decrease. At infinite dilution the ions are so far apart, the interaction between them becomes insignigicant and HENCE, the molar conductivity increases and REACHES a maximum value at infinite dilution. |
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| 43. |
Molar conductivities of Li^(-),Na^(+),K^(+) and Rb^(+) ions in aqueous solutions are in the following order. |
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Answer» `Li^(+) GT Na^(+) = K^(+) lt Rb^(+)` As a result, hydrated Li ion being largest in ionic size, has lowest mobility in AQUEOUS solution. On the other hand, hydrated `Rb^(+)` ion being smallest in size has the HIGHEST mobility in aqueous solution. Higher the ionic mobility, greater is the molar conductivity. Thus, the DECREASING order of molar conductivity is,`Rb^(+) gt K^(+) gt Na^(+) gt Li^(+)` |
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| 44. |
Molar conductivities (wedge_(m)^(infty)) at infinite dilution of NaCl, HCl and CH_(3)COONa are 126.4, 425.9 and 91.0 S cm^(2) mol^(–1) respectively. wedge_(m)^(infty) for CH_(3)COOH will be: |
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Answer» `290.8 S CM^(2) MOL^(–1) ` |
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| 45. |
Molar conductivity decreases with decrease in concentration |
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Answer» For STRONG electrolytes |
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| 46. |
Molarconductivities atinfinitedilution ofMg^(2+) and Br^(-) are105.8 Omega^(-1) cm^(-2) mol^(-1)and 78.2 Omega^(-1) cm^(-2)mol^(-1)respectively . Calculatemolarconductivityat zeroconcentrationof MgBr_(2) |
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Answer» <BR> SOLUTION :`gamma_(Mg^(2+))^(o)= 105.8 Omega^(-1) cm^(2) mol^(-1)``gamma_(Br^(-))^(0) = 78.2 Omega^(-1) cm^(2) mol^(-1)` `A_(o(MgBr_(2))) = gamma_(Mg^(2+))^(0) = 2gamma_(Br^(-))^(0)` `=105.8 + 2 xx78 .2= 105.8 + 156 .4` ` =262 .2 Omega^(-1) cm^(-2) mol^(-1)` |
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| 47. |
Molar conductivity. |
| Answer» Solution :It is defined as a conductance of a VOLUME of the solution containing IONS from one MOLE of an electrolyte when placed between two PARALLEL plate electrodes 1 cm apart and LF large area, sufficient to accommodate the whole solution between them, at constant temperature. It is denoted by `^^_(m)`. | |
| 48. |
Molar conductivities at infinitedilution of KCl, HCl and CH_3COOK are 0.013o and 0.038 and 0.09 S m^(2) mol^(-1) respectively at 291 K . If conductivity of 0.001 M CH_3COOH is2.72 xx 10^(-3) Sm^(-1) then find % degree of ionization of CH_3COOH. |
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Answer» `^^_M^(0)(CH_3COH)=0.034 xx 10^(4) = 340S -cm^(2) -"mole"^(-1)` `^^_M^(0) = (K xx 10^(3))/(M)=(2.72 xx 10^(-3)xx 10^(-2))/(0.001) = 2.72 xx 10` `^^_M = 2.72 xx 10^(32) = 27.2 , ALPHA = (^^_M)/(^^_M^(0))=(27.2)/(340)=0.08, alpha % = 8%` |
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| 49. |
Molar conductance of electrolytic solution wedge_(m) is |
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Answer» `PROP1` `(wedge_(m))=kappaxxV` `wedge_(m)=kappa=(1000)/(C_(m))` where `C_(m)` is molar concentration (mol `l^(-1)`) `therefore`Molar conductance `(wedge_(m))prop(1)/(C)`. |
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| 50. |
Molar conductance of Al_(2)(SO_(4))_(3) equals |
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Answer» EQUIVALENT conductance `XX 1/6` |
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