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At 300 K and 1 atm, 15 mL of a gaseous hydrocarbon requires 375 mL air containing 20% O2 by volume for complete combustion.  After combustion, the gases occupy 330 mL.  Assuming that the water formed is in liquid form and the volumes were measured at the same temperature and pressure, the formula of the hydrocarbon is :
Option: 1  C4H8  
Option: 2  C4H10
Option: 3  C3H6
Option: 4  C3H8
 

Volume of N in air = 375 × 0.8 = 300 ml

Volume of O2 in air = 375 × 0.2 = 75 ml
 

C_{x}H_{y} +\left ( x +\frac{y}{4} \right )O_{2} \; \rightarrow \; xCO_{2}(g) + \frac{y}{2} H_{2}O(l)

15ml                15\left ( x +\frac{y}{4} \right )

  0                         0                            15x                 -

 

After combustion total volume

330 =V_{N_{2}} + V_{CO_{2}}

330 = 300 + 15x 

x = 2 

Volume of O2 used

15\left ( x +\frac{y}{4} \right ) = 75

\left ( x +\frac{y}{4} \right ) = 5

y = 12 

So hydrocarbon is = C2H12

None of the options matches it therefore it is a BONUS.

----------------------------------------------------------------------

Alternatively  Solution


 C_{x}H_{y} +\left ( x +\frac{y}{4} \right )O_{2} \; \rightarrow \; xCO_{2}(g) + \frac{y}{2} H_{2}O(l)

15ml              15\left ( x +\frac{y}{4} \right )

  0                         0                            15x                 -

Volume of O2 used

15\left ( x +\frac{y}{4} \right ) = 75

\left ( x +\frac{y}{4} \right ) = 5

If further information (i.e., 330 ml) is neglected, option (C3H8 ) only satisfy the above equation.

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Posted by

Ritika Jonwal

A solution is prepared by mixing 8.5 g of CH2Cl2 and 11.95 g of CHCl3.  If vapour pressure of CH2Cl2 and CHCl3 at 298 K are 415 and 200 mmHg respectively, the mole fraction of CHCl3 in vapour form is : (Molar mass of Cl=35.5 g mol−1)  
Option: 1  0.162
Option: 2 0.675
Option: 3 0.325
Option: 4  0.486  
 

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Posted by

vishal kumar

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At 300 K, the density of a certain gaseous molecule at 2 bar is double to that of dinitrogen (N2) at 4 bar. The molar mass of gaseous molecule is :
Option: 1 28 g mol−1
Option: 2 56 g mol−1
Option: 3  112 g mol−1
Option: 4  224 g mol−1  
 

 

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Posted by

vishal kumar

Among the following, the incorrect statement is :
Option: 1  At low pressure, real gases show ideal behaviour.
Option: 2  At very low temperature, real gases show ideal behaviour.
Option: 3  At very large volume, real gases show ideal behaviour.
Option: 4  At Boyle’s temperature, real gases show ideal behaviour.  
 

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Posted by

vishal kumar

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When photon of energy 4.0eV strikes the surface of a metal A, the ejected photoelectrons have maximum kinetic energy T_A\: eV and de-Broglie wavelength \lambda _A. The maximum kinetic energy of photoelectrons liberated from another metal B by photon of energy 4.50eV is T_B = (T_A-1.5)eV. If the de-Broglie wavelength of these photoelectrons \lambda _B=2\lambda _A, then the work function(in eV) of metal B is: 
Option: 1 4
Option: 2 1.5
Option: 3 3
Option: 4 2

As we know \lambda =\frac{h}{\sqrt{2mT}}

where T=kinetic energy

So \frac{\lambda_A}{\lambda_B} = \sqrt{\frac{T_A}{T_B}}=\frac{1}{2}...(1)

Also Given \ \ T_B=T_A-1.5... (2)

Using equation (1) and (2)

T_A=2 \ eV , \ and \ T_B=1.5 \ eV

And using the Einstein equation

E_B=T_B+W_B\\ \Rightarrow W_B=E_B-T_B=(4.5-0.5)eV=4 \ eV

So the correct option is 1.

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Posted by

vishal kumar

The relative strength of interionic/intermolecular forces in decreasing order is:
Option: 1 ion - dipole > dipole - dipole > ion -ion
Option: 2 ion - ion > ion - dipole > dipole-dipole
Option: 3ion - dipole > ion -ion > dipole-dipole
Option: 4dipole-dipole > ion - dipole >  ion -ion
 

The correct order of intermolecular forces is:

ion-ion > ion-dipole > dipole-dipole

Therefore, Option(2) is correct.

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Posted by

Kuldeep Maurya

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NaClO_{3} is used, even in spacecrafts, to produce O_{2} . The daily consumption of pure O_{2} by a person is 492L at 1\; atm,300\; K. How much amount of NaClO_{3} , in grams, is required to produce O_{2} for the daily consumption of a person at 1\; atm,300\; K ? _______. NaClO_{3}(s)+Fe(s)\rightarrow O_{2}(g)+NaCl(s)+FeO(s) R=0.082\; L\; atm\; mol^{-1}K^{-1}
 

moles of NaClO_{3} = moles of O_{2}

\mathrm{moles\: of\: O_{2}\: =\: \frac{PV}{RT}\: =\: \frac{1\, x\, 492}{0.082\, x\, 300}\: =\: 20ml}

Mass of NaClO_{3}=20\times 106.5=2130g

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Posted by

Kuldeep Maurya

Which of the following compounds is likely to show both Frenkel abnd Schottky defects in its crystalline form ?
Option: 1 AgBr

Option: 2 CsCl

Option: 3 KBr

Option: 4 ZnS
 

2

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Posted by

Raj Singh

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A beam of electromagnetic radiation of intensity 6.4\times10^{-5} W/cm^2 is comprised of wavelength \lambda=310 nm. It falls normally on a metal (work function \phi=2 eV) of surface area 1 cm2. If one in 103 photons ejects an electron, total number of electrons ejected in 1s is 10x (hc=1240 eVnm, 1 eV=1.6 x 10-19J), then x is :-  
Option: 1 11
Option: 2 10
Option: 3 12
Option: 4 13

Energy in 1 second = 6.4 \times 10 ^{-5} \times \1 \ \times 1 = 6.4 \times 10 ^{-5} Joule

Energy (eV) = \frac{6.4 \times 10 ^{-5}}{1.6 \times 10^{-19}} = 4 \times 10^{14} eV

Energy \ of\ one\ photon = \frac{12400}{3100} = 4 \ eV

Number \ of \ photon \ = \frac{4 \times 10^{14}}{4} = 10^{14}

Number \ of \ electrons \ = \frac{10^{14}}{10^3} = 10^{11}

So, \ x = 11

So the correct answer is option 1.

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Posted by

Ritika Jonwal

An electron of mass m and magnitude of charge \left | e \right | initially at rest gets accelerated by a constant electric field E.The rate of change of de-broglie wavelength of this electron at time t is ? ( ignoring relativistic effects is) :
Option: 1 \frac{-h}{\left | e \right |Et^{2}}      
Option: 2  \frac{\left | e \right |Et}{h}    
Option: 3  -\frac{h}{\left | e \right |Et}
Option: 4  -\frac{h}{\left | e \right |E\sqrt{t}}
 

 

 

\lambda _{D}=\frac{h}{mv}

\therefore\; \; v=at

v=\frac{eE}{m}t\; \; \; \; \left ( a=\frac{eE}{m} \right )

\lambda _{D}=\frac{h}{m\left ( \frac{eE}{m}t \right )}

\lambda _{D}=\frac{h}{eEt}

\frac{d\lambda _{d}}{dt}=-\frac{h}{\left | e \right |Et^{2}}

 

Hence the correct option is (1). 

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Posted by

avinash.dongre

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