Explanation: CH protons will give quartet due to adjucent CH3 protons around 5.5 ppm due to presence of two Cl atoms on same carbon. CH3 protons will give doublet due to adjucent CH proton around 2.0 ppm.
Construct a simulated 1H NMR spectrum, including proton integrations, for CH3CHCl2. Drag the appropriate splitting patterns...
Construct a simulated 1H NMR spectrum, including proton integrations, for CH3CHCl2. Drag the appropriate splitting patterns to the approximate chemical shift positions; place the integration values in the small bins above the associated chemical shift. Splitting patterns and integrations may be used more than once, or not at all, as needed. Likewise, some bins might remain blank. Note that peak heights are arbitrary and do not indicate proton integrations.
Construct a simulated H NMR spectrum, including proton integrations, for CH3CHCl2. Drag the appropriate splitting patterns to the approximate chemical shift positions; place the integration values in the small bins above the associated chemical shift. Splitting patterns and integrations may be used more than once, or not at all, as needed. Likewise, some bins might remain blank. Note that peak heights are arbitrary and do not indicate proton integrations.
Construct a simulated 1H NMR spectrum for the given structural formula. Drag the appropriate splitting patterns to the approximate chemical shift positions; place the integration values in the small bins above the associated chemical shift. Splitting patterns and integrations may be used more than once, or not at all, as needed. Likewise, some bins might remain blank. Note that peak heights are arbitrary and do not indicate proton integrations.
Construct a simulated 1H NMR spectrum, including proton integrations, for CH3OC(CH2OCH3)3 (see Hint). Drag the appropriate splitting patterns to the approximate chemical shift positions; place the integration values in the small bins above the associated chemical shift. Splitting patterns and integrations may be used more than once, or not at all, as needed. Likewise, some bins might remain blank. Note that peak heights are arbitrary and do not indicate proton integrations.
Construct a simulated 1H NMR spectrum, including proton integrations, for CH3OC(CH2OCH3)3) (see Hint). Drag the appropriate splitting patterns to the approximate chemical shift positions; place the integration values in the small bins above the associated chemical shift. Splitting patterns and integrations may be used more than once, or not at all, as needed. Likewise, some bins might remain blank. Note that peak heights are arbitrary and do not indicate proton integrations.
Construct a simulated 1H NMR spectrum, including proton integrations, for CH3OC(CH2OCH3)3 (see Hint). Drag the appropriate splitting patterns to the approximate chemical shift positions; place the integration values in the small bins above the associated chemical shift. Splitting patterns and integrations may be used more than once, or not at all, as needed. Likewise, some bins might remain blank. Note that peak heights are arbitrary and do not indicate proton integrations.
NMR for CH3OC(CH2OCH3)3 Construct a simulated 1H NMR spectrum, Including proton Integrations, for CH3OC(CH2OCH3)3 (see Hint). Drag the appropriate splitting patterns to the approximate chemical shift positions; place the integration values in the small bins above the associated chemical shift. Splitting patterns and integrations may be used more than once, or not at all, as needed. Likewise, some bins might remain blank. Note that peak heights are arbitrary and do not indicate proton integrations.
Construct a simulated 1H NMR spectrum for the given structural formula. Drag the appropriate splitting patterns to the approximate chemical shift positions; placethe integration values in the small bins above the associated chemical shift. Splitting patterns and integrations may be used more than once, or not at all, asneeded. Note that peak heights are arbitrary and do not indicate proton integrations.
Mapf Chemistry Roberts & Company Publishers anic presented by Saping Loarning Construct a simulated 'H NMR spectrum, including proton integrations, for CICH-CHCl2. Drag the appropriate ing patterns to the approximate chemical shift positions; place the integration values in the smail bins above the associated chemical shift. Splitting patterns and integrations may be used more than once, or not at all, as needed. Likewise, some bins might remain biank. Note that peak heights are arbitrary and do not indicate proton integrations...
Construct a simulated 1H NMR spectrum for methyl propanoate by dragging and dropping the appropriate splitting patterns into the boxes on the chemical shift baseline, and by dragging integration values into the small box above each signal. Items may be used more than once. Peak heights do not represent integration. Construct a simulated 1H NMR spectrum for methyl propanoate by dragging and dropping the appropriate splitting patterns into the boxes on the chemical shift baseline, and by dragging integration values...