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3.4: Physical Properties of Amides

  • Page ID
    227550
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    Learning Objectives

    • Compare the boiling points of amides with alcohols of similar molar mass.
    • Compare the solubilities in water of amides of five or fewer carbon atoms with the solubilities of comparable alkanes and alcohols in water.

    With the exception of formamide (HCONH2), which is a liquid, all simple amides are solids (Table \(\PageIndex{1}\)).  Primary and secondary amides can have hydrogen bonding, and therefore have high boiling points and melting points. Tertiary amides cannot hydrogen bond, so their boiling points are lower than those of similar size amides. Primary, secondary, and tertiary amines can hydrogen-bond with water, so the lower members of the series are soluble in water, with borderline solubility occurring in those that have five or six carbon atoms.Like the esters, solutions of amides in water usually are neutral—neither acidic nor basic.

     

    Amides melting points.png

    Table \(\PageIndex{1}\): Physical Constants of Some Unsubstituted Amides
    Condensed Structural Formula Name Melting Point (°C) Boiling Point (°C) Solubility in Water
    HCONH2 formamide 2 193 soluble
    CH3CONH2 acetamide 82 222 soluble
    CH3CH2CONH2 propionamide 81 213 soluble
    CH3CH2CH2CONH2 butyramide 115 216 soluble
    C6H5CONH2 benzamide 132 290 slightly soluble

    The amides generally have high boiling points and melting points. These characteristics and their solubility in water result from the polar nature of the amide group and hydrogen bonding (Figure \(\PageIndex{1}\)). (Similar hydrogen bonding plays a critical role in determining the structure and properties of proteins, deoxyribonucleic acid [DNA], ribonucleic acid [RNA], and other giant molecules so important to life processes.

    clipboard_eb25efb5af4b7538afcaa46b316f25f88.png
    Figure \(\PageIndex{1}\): Hydrogen Bonding in Amides. Amide molecules can engage in hydrogen bonding with water molecules (a). Those amides with a hydrogen atom on the nitrogen atom can also engage in hydrogen bonding (b). Both hydrogen bonding networks extend in all directions.

     

    Primary and secondary amides can have hydrogen bonding, and therefore have high boiling points and melting points. Tertiary amides cannot hydrogen bond, so their boiling points are lower than those of similar size amides

     

     

    Concept Review Exercises

    1. Which compound has the higher boiling point—pentanamide (CH3CH2CH2CH2CONH2) or propyl acetate (CH3COOCH2CH2CH3)? Explain.
    2. Which compound is more soluble in water—propanamide (CH3CH2CONH2) or 1-pentene (CH2=CHCH2CH2CH3)? Explain.

    Answers

    1. pentanamide because the nitrogen-to-hydrogen (N–H) and the carbon-to-oxygen double (C=O) bonds can engage in hydrogen bonding; propyl acetate cannot engage in hydrogen bonding
    2. propanamide because the N–H and C=O bonds can engage in hydrogen bonding with water; 1-pentene cannot engage in hydrogen bonding with water

    Key Takeaways

    • Most amides are solids at room temperature; the boiling points of amides are much higher than those of alcohols of similar molar mass.
    • Amides of five or fewer carbon atoms are soluble in water?.

    Exercises

    1. Which compound has the higher boiling point—butyramide (CH3CH2CH2CONH2) or ethyl acetate (CH3COOCH2CH3)? Explain.

    2. Which compound has the higher boiling point—butyramide or dimethylacetamide [CH3CON(CH3)2]? Explain.

    3. Which compound is more soluble in water—acetamide (CH3CONH2) or 1-butene (CH2=CHCH2CH3)? Explain.

    4. Which compound is more soluble in water—CH3CONHCH3 or 2-methylbutane [CH3CH(CH3)CH2CH3)]? Explain.

    Answers

    1. butyramide because the nitrogen-to-hydrogen (N–H) and the carbon-to-oxygen double (C=O) bonds can engage in hydrogen bonding; ethyl acetate cannot engage in hydrogen bonding

     
    1. acetamide because the N–H and C=O bonds can engage in hydrogen bonding with water; 1-butene cannot engage in hydrogen bonding with water


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