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3 years ago

A species has the following MO configuration: (σ1s)2(σ1s)2(σ2s)2(σ2s)2(σ2p)2(π2p)2. This substance is:_______.

Chemistry

1 answer:

Goshia [24]3 years ago

3 0

Answer : The correct option is, (a) paramagnetic with two unpaired electrons.

Explanation :

According to the molecular orbital theory, the general molecular orbital configuration will be,

$(\sigma_{1s}),(\sigma_{1s}^*),(\sigma_{2s}),(\sigma_{2s}^*),(\sigma_{2p_z}),[(\pi_{2p_x})=(\pi_{2p_y})],[(\pi_{2p_x}^*)=(\pi_{2p_y}^*)],(\sigma_{2p_z}^*)$

As there are 14 electrons present in the given configuration.

The molecular orbital configuration of molecule will be,

$(\sigma_{1s})^2,(\sigma_{1s}^*)^2,(\sigma_{2s})^2,(\sigma_{2s}^*)^2,(\sigma_{2p_z})^2,[(\pi_{2p_x})^1=(\pi_{2p_y})^1],[(\pi_{2p_x}^*)^0=(\pi_{2p_y}^*)^0],(\sigma_{2p_z}^*)^0$

The number of unpaired electron in the given configuration is, 2. So, this is paramagnetic. That means, more the number of unpaired electrons, more paramagnetic.

Hence, the correct option is, (a) paramagnetic with two unpaired electrons.

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Theoretical yield = $\dfrac{n_P}{n_R}\times 100\%$

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Theoretical yield = $\dfrac{(\dfrac{w_P}{m_P})}{(\dfrac{w_R}{m_R})} \times 100\%$

Given that the theoretical yield = 100%

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$100\% =\dfrac{(\dfrac{w_P}{m_P})}{(\dfrac{w_R}{m_R})} \times 100\%$

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$m_P =$ the molecular mass of the derived product

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$w_R$ = weight in a gram of the reagent

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Explanation:

The reaction order is the relationship between the concentration of species and the rate of the reaction. The rate law is as follows:

$r = k [A]^{x} [B]^{y}$

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[B] is the concentration of species B,
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Concentration-time Equation: [A]=[A]o - kt

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For first-order kinetics, we have:

Rate Law: rate= k[A]

Concentration -Time Equation: ln[A]=ln[A]o - kt

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we clear K: K = [ln(100) - ln(5)] /60 (s) = 0,05 [1/s]

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A species has the following MO configuration: (σ1s)2(σ1s*)2(σ2s)2(σ2s*)2(σ2p)2(π2p)2. This substance is:_______.

A species has the following MO configuration: (σ1s)2(σ1s)2(σ2s)2(σ2s)2(σ2p)2(π2p)2. This substance is:_______.