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Chemistry-

General

Easy

Question

Which of the following reaction occurs in a Daniel cell

$Cu (s) + 2 {Ag}^{+} (aq .) \to {Cu}^{2 +} (aq .)$
$Zn (s) + 2 H^{+} (aq .) \to {Zn}^{2 +} (a q) + H_{2} (g)$
$Z n (s) + C u^{2 +} (a q) \to Z n^{2 +} (a q) + C u (s)$
$C u (s) + Z n^{2 +} (aq.) \to C u^{2 +} (aq.) + Z n (s)$

The correct answer is: $Z n left parenthesis s right parenthesis plus C u to the power of 2 plus end exponent left parenthesis a q right parenthesis not stretchy rightwards arrow Z n to the power of 2 plus end exponent left parenthesis a q right parenthesis plus C u left parenthesis s right parenthesis$

Related Questions to study

A rocket is fired and ascends with constant vertical acceleration of 10m/s² for 1 minute Its fuel is exhausted and it continues as a free particle The maximum altitude reached is ( $g equals 10 m divided by s to the power of 2 end exponent$ )

A rocket is fired and ascends with constant vertical acceleration of 10m/s² for 1 minute Its fuel is exhausted and it continues as a free particle The maximum altitude reached is ( $g equals 10 m divided by s to the power of 2 end exponent$ )

physics-General

If $i subscript 1 end subscript equals 3 s i n invisible function application omega t$ and $i subscript 2 end subscript equals 4 c o s invisible function application omega t$ , then $i subscript 3 end subscript$ is

If $i subscript 1 end subscript equals 3 s i n invisible function application omega t$ and $i subscript 2 end subscript equals 4 c o s invisible function application omega t$ , then $i subscript 3 end subscript$ is

physics-General

At time t = 0, terminal A in the circuit shown in the figure is connected to B by a key and an alternating current I(t) = I0 cos( $omega$ t) with $l subscript 0 end subscript$ = 1A and $omega$ = 500 rad/s starts flowing in it with the initial direction shown in the figure.

$text At end text t equals fraction numerator 7 pi over denominator 6 omega end fraction text , end text$ the key is switched from B to D. Now onwards only A and D are connected. A total charge Q flows from the battery to charge the capacitor fully. If C = 20 $mu F$ , R = 10 $capital omega$ and the battery is ideal with emf of 50 V, identify the correct statement(s).

At time t = 0, terminal A in the circuit shown in the figure is connected to B by a key and an alternating current I(t) = I0 cos( $omega$ t) with $l subscript 0 end subscript$ = 1A and $omega$ = 500 rad/s starts flowing in it with the initial direction shown in the figure.

$text At end text t equals fraction numerator 7 pi over denominator 6 omega end fraction text , end text$ the key is switched from B to D. Now onwards only A and D are connected. A total charge Q flows from the battery to charge the capacitor fully. If C = 20 $mu F$ , R = 10 $capital omega$ and the battery is ideal with emf of 50 V, identify the correct statement(s).

physics-General

parallel

In the given circuit, the AC source has $omega$ = 100 rad/s. considering the inductor and capacitor to be ideal, the correct choice(S) is(are)

In the given circuit, the AC source has $omega$ = 100 rad/s. considering the inductor and capacitor to be ideal, the correct choice(S) is(are)

physics-General

In an L–R series circuit, a sinusoidal voltage $V equals V subscript 0 end subscript s i n invisible function application omega t$ is applied. It is given that L = 35 mH, R = 11 $capital omega$ , Vrms = 220 V, $omega divided by 2 pi equals 50 H z$ and $pi$ = 22/7. Find the amplitude of current in the steady state and obtain the phase difference between the current and the voltage. Also plot the variation of current for one cycle on the given graph.

An AC voltage source of variable angular frequency $omega$ and fixed amplitude V connected in series with a capacitance C and an electric bulb of resistance R (inductance zero). When $omega$ is increased :

In an L–R series circuit, a sinusoidal voltage $V equals V subscript 0 end subscript s i n invisible function application omega t$ is applied. It is given that L = 35 mH, R = 11 $capital omega$ , Vrms = 220 V, $omega divided by 2 pi equals 50 H z$ and $pi$ = 22/7. Find the amplitude of current in the steady state and obtain the phase difference between the current and the voltage. Also plot the variation of current for one cycle on the given graph.

An AC voltage source of variable angular frequency $omega$ and fixed amplitude V connected in series with a capacitance C and an electric bulb of resistance R (inductance zero). When $omega$ is increased :

physics-General

When an AC source of emf $E equals E subscript 0 end subscript s i n invisible function application left parenthesis 100 t right parenthesis$ is connected across a circuit, the phase difference between the E and the current i in the circuit is observed to be $pi divided by 4$ , as shown in the diagram. If the circuit consists possibly only of R-C or R-L or L-C series, find the relationship between the two elements.

When an AC source of emf $E equals E subscript 0 end subscript s i n invisible function application left parenthesis 100 t right parenthesis$ is connected across a circuit, the phase difference between the E and the current i in the circuit is observed to be $pi divided by 4$ , as shown in the diagram. If the circuit consists possibly only of R-C or R-L or L-C series, find the relationship between the two elements.

physics-General

parallel

An LCR circuit is equivalent to a damped pendulum. In an LCR circuit the capacitor is charged to $Q subscript 0 end subscript$ and then connected to the L and R as shown below :

If a student plots graphs of the square of maximum charge $open parentheses Q subscript M a x end subscript superscript 2 end superscript close parentheses$ on the capacitor with time (T) for two different values $L subscript 1 end subscript$ and $L subscript 2 end subscript open parentheses L subscript 1 end subscript greater than L subscript 2 end subscript close parentheses$ of L then which of the following represents this graph correctly ? (Plots are shematic and not drawn to scale)

An LCR circuit is equivalent to a damped pendulum. In an LCR circuit the capacitor is charged to $Q subscript 0 end subscript$ and then connected to the L and R as shown below :

If a student plots graphs of the square of maximum charge $open parentheses Q subscript M a x end subscript superscript 2 end superscript close parentheses$ on the capacitor with time (T) for two different values $L subscript 1 end subscript$ and $L subscript 2 end subscript open parentheses L subscript 1 end subscript greater than L subscript 2 end subscript close parentheses$ of L then which of the following represents this graph correctly ? (Plots are shematic and not drawn to scale)

physics-General

In the LCR circuit shown in figure unknown resistance and alternating voltage source are connected. When switch 'S' is closed then there is a phase difference of $fraction numerator pi over denominator 4 end fraction$ between current and applied voltage and voltage across resister is $fraction numerator 100 over denominator square root of 2 end fraction V$ When switch is open current and applied voltage are in same phase. Neglecting resistance of connecting wire answer the following questions :

Peak voltage of applied voltage sources is :

In the LCR circuit shown in figure unknown resistance and alternating voltage source are connected. When switch 'S' is closed then there is a phase difference of $fraction numerator pi over denominator 4 end fraction$ between current and applied voltage and voltage across resister is $fraction numerator 100 over denominator square root of 2 end fraction V$ When switch is open current and applied voltage are in same phase. Neglecting resistance of connecting wire answer the following questions :

Peak voltage of applied voltage sources is :

physics-General

A voltage source V = $V subscript 0 end subscript$ sin (100 t) is connected to a black box in which there can be either one element out of L, C, R or any two of them connected in series

At steady state. the variation of current in the circuit and the source voltage are plotted together with time, using an oscilloscope, as shown

If AC source is removed, the circuit is shorted for some time so that capacitor is fully discharged and then a battery of constant EMF is connected across the black box, at t = 0. The current in the circuit will –

A voltage source V = $V subscript 0 end subscript$ sin (100 t) is connected to a black box in which there can be either one element out of L, C, R or any two of them connected in series

At steady state. the variation of current in the circuit and the source voltage are plotted together with time, using an oscilloscope, as shown

If AC source is removed, the circuit is shorted for some time so that capacitor is fully discharged and then a battery of constant EMF is connected across the black box, at t = 0. The current in the circuit will –

physics-General

parallel

A voltage source V = $V subscript 0 end subscript$ sin (100 t) is connected to a black box in which there can be either one element out of L, C, R or any two of them connected in series

At steady state. the variation of current in the circuit and the source voltage are plotted together with time, using an oscilloscope, as shown

Values of the parameters of the elements, present in the black box are –

A voltage source V = $V subscript 0 end subscript$ sin (100 t) is connected to a black box in which there can be either one element out of L, C, R or any two of them connected in series

At steady state. the variation of current in the circuit and the source voltage are plotted together with time, using an oscilloscope, as shown

Values of the parameters of the elements, present in the black box are –

physics-General

A voltage source V = $V subscript 0 end subscript$ sin (100 t) is connected to a black box in which there can be either one element out of L, C, R or any two of them connected in series

At steady state. the variation of current in the circuit and the source voltage are plotted together with time, using an oscilloscope, as shown

The element(s) present in black box is/are :

A voltage source V = $V subscript 0 end subscript$ sin (100 t) is connected to a black box in which there can be either one element out of L, C, R or any two of them connected in series

At steady state. the variation of current in the circuit and the source voltage are plotted together with time, using an oscilloscope, as shown

The element(s) present in black box is/are :

physics-General

An ac generator G with an adjustable frequency of oscillation is used in the circuit, as shown.

Thermal energy produced by the resistance R in time duration 1 $mu$ s, using the source at resonant condition, is

An ac generator G with an adjustable frequency of oscillation is used in the circuit, as shown.

Thermal energy produced by the resistance R in time duration 1 $mu$ s, using the source at resonant condition, is

physics-General

parallel

An ac generator G with an adjustable frequency of oscillation is used in the circuit, as shown.

Average energy stored by the inductor $L subscript 2 end subscript$ (Source is at resonance frequency) is equal to

An ac generator G with an adjustable frequency of oscillation is used in the circuit, as shown.

Average energy stored by the inductor $L subscript 2 end subscript$ (Source is at resonance frequency) is equal to

physics-General

An ac generator G with an adjustable frequency of oscillation is used in the circuit, as shown.

If the ac source G is of 100 V rating at resonant frequency of the circuit, then average power supplied by the source is –

An ac generator G with an adjustable frequency of oscillation is used in the circuit, as shown.

If the ac source G is of 100 V rating at resonant frequency of the circuit, then average power supplied by the source is –

physics-General

An ac generator G with an adjustable frequency of oscillation is used in the circuit, as shown.

To increase resonant frequency of the circuit, some of the changes in the circuit are carried out. Which change(s) would certainly result in the increase in resonant frequency ?

An ac generator G with an adjustable frequency of oscillation is used in the circuit, as shown.

To increase resonant frequency of the circuit, some of the changes in the circuit are carried out. Which change(s) would certainly result in the increase in resonant frequency ?

physics-General

parallel

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