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ALDEHYDES, KETONES AND CARBOXYLIC ACID

28136 An organic compound of molecular formula ${C_4}{H_{10}}O$ does not react with sodium. With excess of $HI,$ it gives only one type of alkyl halide. The compound is

1 Ethoxyethane

2 $2-$Methoxypropane

3 $1-$Methoxypropane

4 $1-$Butanol

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28137 જ્યારે $C{H_2} = CH - COOH$ is reduced with $LiAl{H_4}$, the compound obtained will be

1 $C{H_3} - C{H_2} - COOH$

2 $C{H_2} = CH - C{H_2}OH$

3 $C{H_3} - C{H_2} - C{H_2}OH$

4 $C{H_3} - C{H_2} - CHO$

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28138 In a set of the given reactions, acetic acid yielded a product C.Product C would be$C{H_3}COOH + PC{l_5} \to A\mathop {\xrightarrow{{{C_6}{H_6}}}}\limits_{anh.\,AlC{l_3}} $ $B\mathop {\xrightarrow{{{C_2}{H_5}MgBr}}}\limits_{ether} C$

1 $\begin{array}{*{20}{c}}
{{C_2}{H_5}\,\,} \\
{|\,\,\,\,\,\,\,\,\,} \\
{C{H_3} - C(OH){C_6}{H_5}}
\end{array}$

2 $C{H_3}CH(OH){C_2}{H_5}$

3 $C{H_3}CO{C_6}{H_5}$

4 $C{H_3}CH(OH){C_6}{H_5}$

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28139 Carboxylic acids are more acidic than phenol and alcohol because of

1 Intermolecular hydrogen bonding

2 Formation of dimers

3 Highly acidic hydrogen

4 Resonance stabilization of their conjugate base

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28136 An organic compound of molecular formula ${C_4}{H_{10}}O$ does not react with sodium. With excess of $HI,$ it gives only one type of alkyl halide. The compound is

1 Ethoxyethane

2 $2-$Methoxypropane

3 $1-$Methoxypropane

4 $1-$Butanol

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28137 જ્યારે $C{H_2} = CH - COOH$ is reduced with $LiAl{H_4}$, the compound obtained will be

1 $C{H_3} - C{H_2} - COOH$

2 $C{H_2} = CH - C{H_2}OH$

3 $C{H_3} - C{H_2} - C{H_2}OH$

4 $C{H_3} - C{H_2} - CHO$

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28138 In a set of the given reactions, acetic acid yielded a product C.Product C would be$C{H_3}COOH + PC{l_5} \to A\mathop {\xrightarrow{{{C_6}{H_6}}}}\limits_{anh.\,AlC{l_3}} $ $B\mathop {\xrightarrow{{{C_2}{H_5}MgBr}}}\limits_{ether} C$

1 $\begin{array}{*{20}{c}}
{{C_2}{H_5}\,\,} \\
{|\,\,\,\,\,\,\,\,\,} \\
{C{H_3} - C(OH){C_6}{H_5}}
\end{array}$

2 $C{H_3}CH(OH){C_2}{H_5}$

3 $C{H_3}CO{C_6}{H_5}$

4 $C{H_3}CH(OH){C_6}{H_5}$

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28139 Carboxylic acids are more acidic than phenol and alcohol because of

1 Intermolecular hydrogen bonding

2 Formation of dimers

3 Highly acidic hydrogen

4 Resonance stabilization of their conjugate base

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28136 An organic compound of molecular formula ${C_4}{H_{10}}O$ does not react with sodium. With excess of $HI,$ it gives only one type of alkyl halide. The compound is

1 Ethoxyethane

2 $2-$Methoxypropane

3 $1-$Methoxypropane

4 $1-$Butanol

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28137 જ્યારે $C{H_2} = CH - COOH$ is reduced with $LiAl{H_4}$, the compound obtained will be

1 $C{H_3} - C{H_2} - COOH$

2 $C{H_2} = CH - C{H_2}OH$

3 $C{H_3} - C{H_2} - C{H_2}OH$

4 $C{H_3} - C{H_2} - CHO$

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28138 In a set of the given reactions, acetic acid yielded a product C.Product C would be$C{H_3}COOH + PC{l_5} \to A\mathop {\xrightarrow{{{C_6}{H_6}}}}\limits_{anh.\,AlC{l_3}} $ $B\mathop {\xrightarrow{{{C_2}{H_5}MgBr}}}\limits_{ether} C$

1 $\begin{array}{*{20}{c}}
{{C_2}{H_5}\,\,} \\
{|\,\,\,\,\,\,\,\,\,} \\
{C{H_3} - C(OH){C_6}{H_5}}
\end{array}$

2 $C{H_3}CH(OH){C_2}{H_5}$

3 $C{H_3}CO{C_6}{H_5}$

4 $C{H_3}CH(OH){C_6}{H_5}$

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28139 Carboxylic acids are more acidic than phenol and alcohol because of

1 Intermolecular hydrogen bonding

2 Formation of dimers

3 Highly acidic hydrogen

4 Resonance stabilization of their conjugate base

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28136 An organic compound of molecular formula ${C_4}{H_{10}}O$ does not react with sodium. With excess of $HI,$ it gives only one type of alkyl halide. The compound is

1 Ethoxyethane

2 $2-$Methoxypropane

3 $1-$Methoxypropane

4 $1-$Butanol

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28137 જ્યારે $C{H_2} = CH - COOH$ is reduced with $LiAl{H_4}$, the compound obtained will be

1 $C{H_3} - C{H_2} - COOH$

2 $C{H_2} = CH - C{H_2}OH$

3 $C{H_3} - C{H_2} - C{H_2}OH$

4 $C{H_3} - C{H_2} - CHO$

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28138 In a set of the given reactions, acetic acid yielded a product C.Product C would be$C{H_3}COOH + PC{l_5} \to A\mathop {\xrightarrow{{{C_6}{H_6}}}}\limits_{anh.\,AlC{l_3}} $ $B\mathop {\xrightarrow{{{C_2}{H_5}MgBr}}}\limits_{ether} C$

1 $\begin{array}{*{20}{c}}
{{C_2}{H_5}\,\,} \\
{|\,\,\,\,\,\,\,\,\,} \\
{C{H_3} - C(OH){C_6}{H_5}}
\end{array}$

2 $C{H_3}CH(OH){C_2}{H_5}$

3 $C{H_3}CO{C_6}{H_5}$

4 $C{H_3}CH(OH){C_6}{H_5}$

ALDEHYDES, KETONES AND CARBOXYLIC ACID

28139 Carboxylic acids are more acidic than phenol and alcohol because of

1 Intermolecular hydrogen bonding

2 Formation of dimers

3 Highly acidic hydrogen

4 Resonance stabilization of their conjugate base

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