1) A compound gives a mass spectrum with peaks at m/z = 77 (40%), 112 (100%), 114 (33%), and essentially no other peaks. Identify the compound. First,

Slides:

Advertisements

Similar presentations

Bromobutane. Halogenoalkanes Halogenoalkanes are hydrocarbon chains that have one or more hydrogen atom(s) exchanged for halogen atom(s).

Advertisements

Lecture 5 HDI More Sample Problems (NMR & IR) Due: Lecture Problem 3.

Chapter 14 Mass Spectroscopy.

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.

Spectroscopy Molecules move Movement can be monitored with electromagnetic radiation, e.g. light.

Today: Brief Review of Mass Spectroscopy Discussion/Review of H-NMR, CMR Next time (our last lab lecture): Your questions Final Exam at 2:10 pm in your.

Mechanism of Phenylurethane

Molecular weight: Molecular ion peak M + ? odd-numbered (N...) ? isotope peaks (Cl, Br)? Alcohols … Recognize typical fragments: H 2 O, alkyl, acyl, tropylium.

Check your Unknown #3 mass spectrum

Complete this reaction equation:

Nuclear Magnetic Resonance (NMR) Spectroscopy

1 CHEM 212 – NMR Spectroscopy Spring Spectral Analysis – 1 H NMRNMR Spectroscopy NMR Spectral Analysis – Introductory 1 H NMR 1.NMR is rarely.

Experiment 14: IR AND NMR IDENTIFICATION OF AN UNKNOWN.

Infrared Spectroscopy

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

INFRARED SPECTROSCOPY. Electromagnetic Spectrum.

William H. Brown & Christopher S. Foote

Nuclear Magnetic Resonance Spectroscopy. The Use of NMR Spectroscopy Used to map carbon-hydrogen framework of molecules Most helpful spectroscopic technique.

Aim: What are functional groups?. Isomers Compounds that have the same molecular formula but have different structural formulas and different names; isomers.

Spectroscopy Problems

Organic Compounds Carbon Bonding Forms 4 covalent bonds in chains or rings 1.

Solving Spectroscopy Problems Part 1 Lecture Supplement page 159

Common 1 H NMR Patterns 1. triplet (3H) + quartet (2H) -CH 2 CH 3 2. doublet (1H) + doublet (1H) -CH-CH- 3. large singlet (9H) t-butyl group 4. singlet.

Give the formula and structure of the compound with this IR and a molecular ion peak at 116.

(slides can be accessed here)

1) Draw a structure consistent with the following data:

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

Units of Unsaturation This is also called “Degrees of Unsaturation” or “Double Bond Equivalents (DBE)”. By looking at a molecular formula, it is possible.

Short Answer: 1) What type of electromagnetic radiation is used in nuclear magnetic resonance? radio 2) What is the most abundant peak in a mass spectrum.

Identification of Organic Compounds by GC/MS, IR & NMR Marcela James.

Chapter 11 Introduction to Organic Chemistry: Alkanes

Chapter 10 Introduction to Organic Chemistry: Alkanes 10.1 Organic Compounds 1 Copyright © 2009 by Pearson Education, Inc.

Ch 22: Organic Chemistry.

Hydrocarbon Derivatives

1 Chapter 11 Introduction to Organic Chemistry: Alkanes 11.4 Properties of Alkanes Copyright © 2007 by Pearson Education, Inc. Publishing as Benjamin Cummings.

1) Which of the following alkanes will give more than one monochlorination product when treated with chlorine and light? a) 2,2’-dimethylpropane,

19/12/2015 Draw the displayed formula of ethanol What would we see in an IR and in the mass spec for ethanol?

1 H NMR Interpretation Using the NMR Mosaic. NMR Spectra contain THREE Pieces of Information Chemical Shift –Information about functionality Integration.

NMR Practice: C 4 H 10 O Given a molecular formula and an NMR spectrum, what is the structure of the compound? 2 H 3 H.

Identifying Functional Groups The Key to Survival.

CONTENTS Fragmentation of molecular ions - theory What a mass spectrum tells you Molecular ions Fragmentation Mass spectra of alkanes Mass spectra of halogenoalkanes.

Demonstrate understanding of spectroscopic data in chemistry Chemistry A.S internal credits.

Problem 1 3 peaks (8 C) means considerable symmetry

In carbon-13 NMR, what do the number of peaks represent? The number of chemically different carbon atoms present.

Unit 15: Organic Chemistry

Goals for the Day: Combustion Reactions of Alkanes Functional Groups Naming Alkenes & Alkynes Physical Properties of Alkenes & Alkynes Reactions of Alkenes.

CHAPTER 11 Alkenes; Infrared Spectroscopy and Mass Spectroscopy.

1) Molecular ion peak of 122 and 124 (3:1) = 87/12 = 7 carbons = 3 hydrogens C 7 H 3 Cl (2(7) + 2 – 3 – 1)/2 = 6 DOUS C 6 H 15 Cl 2(6) + 2.

IB Chemistry Option 1 Analytical Chemistry

“Structure Elucidation”-Comprehensive Spectral Interpretation

NMR spectroscopy – key principles

Spectroscopy nuclear magnetic resonance.

CHEM 212 – NMR Spectroscopy

1) A compound gives a mass spectrum with peaks at m/z = 77 (40%), 112 (100%), 114 (33%), and essentially no other peaks. Identify the compound. First,

Course Evaluation Last semester the average response rate for the on-line form was 54% as compared to about 80% for the old paper forms. Let’s do better.

Chapter 3 Organic Compounds: Alkanes and Their Stereochemistry

1H-NMR spectra interpretation

Unit 14: Investigate organic chemistry reactions in order to gain skills in preparative organic chemistry Learning Aim D.

Figure: 13.1 Title: Figure Nuclei in the absence and presence of an applied magnetic field. Caption: In the absence of an applied magnetic field,

Get your answers out for the challenge we finished with last lesson.

Worked Example Molecular Structures: Identifying Functional Groups

Vibrational Spectroscopy - IR

Determination of Structure

1H NMR Interpretation Number of Signals (Resonances)

Problem O, C5H10O2 DBE = {[(2x5)+2]-10}/2 = 1

10.3 Alcohols These compounds have an -OH attached to the carbon chain. This functional group is called a hydroxyl group. Note: The oxygen is bonded to.

UNIT FIVE KEY TOPICS Chapters 10/11 Alcohols Acidity of alcohols 1

In this lesson you will learn:

Advanced Pharmaceutical Analysis

Presentation transcript:

1) A compound gives a mass spectrum with peaks at m/z = 77 (40%), 112 (100%), 114 (33%), and essentially no other peaks. Identify the compound. First, your molecular ion peak is 112 and you have a M+2 peak at 114. Therefore, you have a halogen. Now, your molecular ion peak and M+2 peak are in a 3 to 1 ratio. This means chlorine. So, 112-35=77 # C’s 77/12=6 carbons so C6H5Cl. DOUS (2(6)+2-5-1)/2=4

2) While organizing the undergraduate stockroom, a new chemistry professor found a half-gallon jug containing a cloudy liquid (bp 100–105 °C), marked only "STUDENT PREP". She ran a quick mass spectrum, which is shown below. As soon as she saw the spectrum (without even checking the actual mass numbers), she said, "I know what it is." What compound is the "student prep"?

So molecular ion peak at 136 and M+2 peak at 138, so halogen present. They are in a 1:1 ratio so Br. So 136-79=57/12 = 4x12=48 57-48=9, C4H9Br (2(4)+2-9-1)/2=0 The peaks at 107 (C2H5) and 93(C3H7) tell us it is a linear chain instead of a branched one.

3) A laboratory student added 1-bromobutane to a flask containing dry ether and Mg turnings. An exothermic reaction resulted, and the ether boiled vigorously for several minutes. Then she added acetone to the reaction mixture, and the ether boiled even more vigorously. She added dilute acid to the mixture, and separated the layers. She evaporated the ether layer, and distilled a liquid that boiled at 143 °C. GC–MS analysis of the distillate showed one major product with a few minor impurities. The mass spectrum of the major product is shown below. Show the structure of this major product.

The molecular ion peak should be at 116, but the loss of a carbon from the quatenary C forms a stable carbocation at 101.

1) One of the following compounds is responsible for the IR spectrum shown. Draw the structure of the responsible compound. 1-butene, 1-butanol, 4-hydroxy-1-butene, methyl propyl ether, butanoic acid.

First thing to notice is the presence of an alcohol at 3200-3600 cm-1, which narrows our choices down to 1-butanol, 4-hydroxy-1-butene and butanoic acid.. Only 1-butanol works, because there are no peaks corresponding to C=C and C=O.

2) One of the following compounds is responsible for the IR spectrum shown. Draw the structure of the responsible compound. phenylacetone, benzoic acid, acetophenone, benzyl alcohol, benzaldehyde

First you can eliminate benzoic acid and benzyl alcohol because there is no –OH peak. Second you can eliminate benzaldehyde because there is no peak at 2740 cm-1 (aldehyde peak). That leaves phenylacetone and acetophenone. Acetophenone is the answer because the carbonyl peak is at 1700 cm-1 and a simple ketone like that on phenylacetone would absorb at a higher energy.

3) One of the following compounds is responsible for the IR spectrum shown. Draw the structure of the responsible compound. 2-ethynylcyclohexanone, 2-methyl-2-cyclohexenone, acetophenone, cyclohexylmethyl alcohol, 4-ethylcyclohexanone.

First, 2-ethynylcyclohexanone can be eliminated because there is no peak for a carbon carbon triple bond. Second, cyclohexylmethyl alcohol is eliminated because there is no –OH peak present. Acetopheone can be eliminated next because there is no peak for aromatic C-H stretches. Also the carbonyl peak would be at a higher energy like around 1800 cm-1. 2-methyl-2-cyclohexenone can be eliminated because there is no carbon carbon double bond peak. Leaving 4-ethylcyclohexanone.

(4) Determine the structure of the compound that gives rise to the following mass and IR spectra.

The molecular ion peak is at 162 and the M+2 peak is at 164, and they are in a 1:1 ratio, therefore there is a bromine atom. 162-79=83 83/12=6 carbons and 6x12= 72 so 83-72=11 C6H11Br So 2(6)+2-11-1=2/2=1, which means 1 double bond or 1 ring. Looking at the IR, there is no C=C peak so that means a ring.

(5) Determine the structure of the compound that gives rise to the following mass and IR spectra.

So the molecular ion peak is 72. So 72/12= 6 carbons 2(6)+2=14/2=7 a bit high. So subtract 1 C and replace with 12 Hs. C5H12. 2(5)+2-12=0 Not pentane, there is a carbonyl stretch.

So to add an O, subtract a methyl group C4H8O. 2(4)+2-8=2/2=1 Lastly there is a peak at 2740 which tells us that the carbonyl is due to an aldehyde.

(1) The following 1H NMR spectrum is of a compound of molecular formula C3H8O. Propose a structure for this compound.

First you have a septet that integrates to 1 H and a doublet that integrates to 6 Hs. This is typical of an isopropyl group. Then the peak at 2.5ppm. is a singlet and represents a H on an OH group.

2) Draw the structure of the compound with the 1H NMR and IR spectra shown and the formula C5H12O.

2(5)+2-12=0 so no double bonds or rings. Also there is no –OH or C=O peaks in the IR, so it has to be an ether. Looking downfield you have a triplet and a singlet. For there to be a singlet there must be only a methyl on one side of the ether. Thus giving us the following structure. Looking at this structure, it explains the presence of the multiplets for the middle two CH2s. And finally the triplet upfield is for the terminal methyl group.

3) Draw the structure of the compound with the 1H NMR and IR spectra shown and the formula C6H12O2.

First 2(6)+2-12=2/2=1 And based on the carbonyl peak in the IR we know this is our degree of unsaturation. Also we know that there must also be an ether since there is no OH peak in the IR. And based on the proton NMR we have two types of protons. One has to be connected to the ether. And for the rest to be all the same, there must be an isobutyl group.

(4) Determine the structure of the following compound based on its mass, IR, and 1H NMR spectra.

114/12=9 carbons 114-108=6 hydrogens C9H6 2(9)+2-6= 7 degrees of unsaturation Based on the IR we know there is a carbonyl So –CH4 add O C8H2O 2(8)+2-2=16/2=8 Lets take off a C and add 12 Hs C7H14O 2(7)+2-14=2/2=1 Which accounts for the C=O

1) What is the major product of the following reaction? HBr 25

2) What is the major product of the following reaction? 1. Hg(OAc)2, H2O 2. NaBH4 , HO– 26

3) What is the major product of the following reaction? HBr peroxide 27

4) What is the major product of the following reaction? Cl2 CH2Cl2 28

5) What alkene, when allowed to react with HBr, would produce the following alkyl bromide? (There is more than one correct answer.) 29

14.43) a) quartet doublet b) triplet triplet

e) doublet triplet septet quartet h) multplet of 12 triplet singlet multiplet of 9 triplet

j) doublet doublet l) doublet of doublets doublet of doublets multiplet of 16