Presentation is loading. Please wait.

Presentation is loading. Please wait.

13.21 Mass Spectrometry. Atom or molecule is hit by high-energy electron Principles of Electron-Impact Mass Spectrometry e–e–e–e–

Published byCecily Reed Modified over 9 years ago

Similar presentations

Presentation on theme: "13.21 Mass Spectrometry. Atom or molecule is hit by high-energy electron Principles of Electron-Impact Mass Spectrometry e–e–e–e–"— Presentation transcript:

1 13.21 Mass Spectrometry

2 Atom or molecule is hit by high-energy electron Principles of Electron-Impact Mass Spectrometry e–e–e–e–

3 Atom or molecule is hit by high-energy electron electron is deflected but transfers much of its energy to the molecule e–e–e–e– Principles of Electron-Impact Mass Spectrometry

4 Atom or molecule is hit by high-energy electron electron is deflected but transfers much of its energy to the molecule e–e–e–e– Principles of Electron-Impact Mass Spectrometry

5 This energy-rich species ejects an electron. Principles of Electron-Impact Mass Spectrometry

6 This energy-rich species ejects an electron. Principles of Electron-Impact Mass Spectrometry forming a positively charged, odd-electron species called the molecular ion e–e–e–e– +

7 Molecular ion passes between poles of a magnet and is deflected by magnetic field amount of deflection depends on mass-to-charge ratio highest m/z deflected least lowest m/z deflected most Principles of Electron-Impact Mass Spectrometry +

8 If the only ion that is present is the molecular ion, mass spectrometry provides a way to measure the molecular weight of a compound and is often used for this purpose. However, the molecular ion often fragments to a mixture of species of lower m/z.

9 The molecular ion dissociates to a cation and a radical. Principles of Electron-Impact Mass Spectrometry +

10 The molecular ion dissociates to a cation and a radical. Principles of Electron-Impact Mass Spectrometry + Usually several fragmentation pathways are available and a mixture of ions is produced.

11 mixture of ions of different mass gives separate peak for each m/z intensity of peak proportional to percentage of each ion of different mass in mixture separation of peaks depends on relative mass Principles of Electron-Impact Mass Spectrometry + + + + + +

12 mixture of ions of different mass gives separate peak for each m/z intensity of peak proportional to percentage of each atom of different mass in mixture separation of peaks depends on relative mass ++++ ++ Principles of Electron-Impact Mass Spectrometry

13 20406080100 120 m/z m/z = 78 10080 60 40 20 0 Relative intensity Some molecules undergo very little fragmentation Benzene is an example. The major peak corresponds to the molecular ion.

14 HHH HH H HHH HH H HHH HH H all H are 1 H and all C are 12 C one C is 13 C one H is 2 H Isotopic Clusters 78 7979 93.4%6.5%0.1%

15 20406080100 120 m/z10080 60 40 20 0 Relative intensity 112 114 Isotopic Clusters in Chlorobenzene visible in peaks for molecular ion 35 Cl 37 Cl

16 20406080100 120 m/z Relative intensity 77 Isotopic Clusters in Chlorobenzene no m/z 77, 79 pair; therefore ion responsible for m/z 77 peak does not contain Cl H H H H H+ 10080 60 40 20 0

17 Alkanes undergo extensive fragmentation m/z Decane 142 43 57 71 85 99 CH 3 —CH 2 —CH 2 —CH 2 —CH 2 —CH 2 —CH 2 —CH 2 —CH 2 —CH 3 Relative intensity 10080 60 40 20 0 20406080100 120

18 Propylbenzene fragments mostly at the benzylic position 20406080100 120 m/z Relative intensity 120 91 CH 2 —CH 2 CH 3 10080 60 40 20 0

19 13.22 Molecular Formula as a Clue to Structure

20 Molecular Weights CH 3 (CH 2 ) 5 CH 3 Heptane CH 3 CO O Cyclopropyl acetate Molecular formula Molecular weight C 7 H 16 C5H8O2C5H8O2C5H8O2C5H8O2 100100 Exact mass 100.1253100.0524 Mass spectrometry can measure exact masses. Therefore, mass spectrometry can give molecular formulas.

21 Molecular Formulas Knowing that the molecular formula of a substance is C 7 H 16 tells us immediately that is an alkane because it corresponds to C n H 2n+2 C 7 H 14 lacks two hydrogens of an alkane, therefore contains either a ring or a double bond

22 Index of Hydrogen Deficiency relates molecular formulas to multiple bonds and rings index of hydrogen deficiency = 1 2 (molecular formula of alkane – molecular formula of compound)

23 Example 1 index of hydrogen deficiency 12 (molecular formula of alkane – molecular formula of compound) C 7 H 14 12 (C 7 H 16 – C 7 H 14 ) = =12 (2) = 1 = Therefore, one ring or one double bond.

24 Example 2 C 7 H 12 12 (C 7 H 16 – C 7 H 12 ) =12 (4) = 2 = Therefore, two rings, one triple bond, two double bonds, or one double bond + one ring.

25 Oxygen has no effect CH 3 (CH 2 ) 5 CH 2 OH (1-heptanol, C 7 H 16 O) has same number of H atoms as heptane index of hydrogen deficiency = 1 2 (C 7 H 16 – C 7 H 16 O) = 0 = 0 no rings or double bonds

26 Oxygen has no effect index of hydrogen deficiency = 1 2 (C 5 H 12 – C 5 H 8 O 2 ) = 2 = 2 one ring plus one double bond CH 3 CO O Cyclopropyl acetate

27 If halogen is present Treat a halogen as if it were hydrogen. C C CH 3 Cl H H C 3 H 5 Cl same index of hydrogen deficiency as for C 3 H 6

28 Rings versus Multiple Bonds Index of hydrogen deficiency tells us the sum of rings plus multiple bonds. Catalytic hydrogenation tells us how many multiple bonds there are.

Download ppt "13.21 Mass Spectrometry. Atom or molecule is hit by high-energy electron Principles of Electron-Impact Mass Spectrometry e–e–e–e–"

Similar presentations

Infrared Spectroscopy

Infrared Spectroscopy
Mass Spectrometry.

Mass Spectrometry.
Mass Spectrometry Mass spectrometry involves ionizing a compound, separating the ions that result on the basis of mass to charge ratio (m/z) and obtaining.

Mass Spectrometry Mass spectrometry involves ionizing a compound, separating the ions that result on the basis of mass to charge ratio (m/z) and obtaining.
Advanced Higher Unit 3 Mass Spectrometry. Mass spectrometry can be used to determine the accurate molecular mass and structural features of an organic.

Advanced Higher Unit 3 Mass Spectrometry. Mass spectrometry can be used to determine the accurate molecular mass and structural features of an organic.
Organic Structural Spectroscopy by Lambert, Shurvell, Lightner Calculation of approximate intensity distribution due to natural isotope abundance.

Organic Structural Spectroscopy by Lambert, Shurvell, Lightner Calculation of approximate intensity distribution due to natural isotope abundance.
Mass spectroscopy. In a typical MS procedure:  1- a sample is loaded onto the MS instrument, and undergoes vaporization.  2- the components of the sample.

Mass spectroscopy. In a typical MS procedure:  1- a sample is loaded onto the MS instrument, and undergoes vaporization.  2- the components of the sample.
Dr. Wolf's CHM 201 & 202 13- 1 Chapter 13 Spectroscopy Infrared spectroscopy Ultraviolet-Visible spectroscopy Nuclear magnetic resonance spectroscopy Mass.

Dr. Wolf's CHM 201 & Chapter 13 Spectroscopy Infrared spectroscopy Ultraviolet-Visible spectroscopy Nuclear magnetic resonance spectroscopy Mass.
Structure Determination: MS, IR, NMR (A review)

Structure Determination: MS, IR, NMR (A review)
Chapter 14 Mass Spectroscopy.

Chapter 14 Mass Spectroscopy.
Mass Spectrometry Introduction:

Mass Spectrometry Introduction:
Mass Spectrometry The substance being analyzed (solid or liquid) is injected into the mass spectrometer and vaporized at elevated temperature and reduced.

Mass Spectrometry The substance being analyzed (solid or liquid) is injected into the mass spectrometer and vaporized at elevated temperature and reduced.
MiniQuiz 6 Answers: Which of the compounds below do you expect to absorb light in the UV-region? (circle) Hexane Ethanol Benzene Naphthalene Explain your.

MiniQuiz 6 Answers: Which of the compounds below do you expect to absorb light in the UV-region? (circle) Hexane Ethanol Benzene Naphthalene Explain your.
Modern techniques for structure determination of organic compounds include: Mass spectrometry Size and formula of the compound Infrared spectroscopy Functional.

Modern techniques for structure determination of organic compounds include: Mass spectrometry Size and formula of the compound Infrared spectroscopy Functional.
Mechanism of Phenylurethane

Mechanism of Phenylurethane
Alkanes undergo extensive fragmentation

Alkanes undergo extensive fragmentation
CHE 232 MtWTF 8-8:50pm. Chemical Identification Comparison of Physical Properties –Boiling Point –Melting Point –Density –Optical rotation –Appearance.

CHE 232 MtWTF 8-8:50pm. Chemical Identification Comparison of Physical Properties –Boiling Point –Melting Point –Density –Optical rotation –Appearance.
Mass Spectrometry Mass spectrometry (MS) is not true “spectroscopy” because it does not involve the absorption of electromagnetic radiation to form an.

Mass Spectrometry Mass spectrometry (MS) is not true “spectroscopy” because it does not involve the absorption of electromagnetic radiation to form an.
Introduction to Mass Spectrometry (MS)

Introduction to Mass Spectrometry (MS)
Mass Spectrometry Chapter 14 Chapter 14.

Mass Spectrometry Chapter 14 Chapter 14.
12. Structure Determination: Mass Spectrometry and Infrared Spectroscopy Based on McMurry’s Organic Chemistry, 7th edition.

12. Structure Determination: Mass Spectrometry and Infrared Spectroscopy Based on McMurry’s Organic Chemistry, 7th edition.

Similar presentations

Ads by Google