Share Course Ware
Natural Sciences > Chemistry > Advanced Chemical Experimentation and Instrumentat
 Advanced Chemical Experimentation and Instrumentat  posted by  member7_php   on 2/15/2009  Add Courseware to favorites Add To Favorites  
Abstract/Syllabus
Courseware/Lectures
Test/Tutorials
Further Reading
Webliography
Downloads
More Options
 
Abstract/Syllabus:

Gheorghiu, Mircea, and Andrei Tokmakoff, 5.33 Advanced Chemical Experimentation and Instrumentation, Fall 2007. (Massachusetts Institute of Technology: MIT OpenCourseWare), http://ocw.mit.edu (Accessed 09 Jul, 2010). License: Creative Commons BY-NC-SA

Advanced Chemical Experimentation and Instrumentation

Fall 2007

Following electronic excitation, a system vibrationally relaxes and releases energy via fluorescence. (Image by MIT OpenCourseWare.)

Course Description

5.33 focuses on advanced experimentation, with particular emphasis on chemical synthesis and the fundamentals of quantum chemistry, illustrated through molecular spectroscopy. The written and oral presentation of experimental results is also emphasized in the course.

Acknowledgements

The materials for 5.33 reflect the work of many faculty members associated with this course over the years.

Syllabus

Course Overview

Welcome to the final and culminating experience in your formal chemistry laboratory instruction at MIT. This subject, 5.33, is intended to synthesize a number of concepts you have encountered in lecture subjects, introduce you to techniques and procedures not encountered in earlier laboratory subjects, and in addition stimulate you to think about the following ideas:

  • Spectroscopy is more than group frequencies and chemical shifts. You will analyze a spectrum at high resolution to obtain structural information about a molecule, use intensity data to determine relative populations of species, relate line widths to lifetimes, perform ultrafast spectroscopic measurements in the time domain, and find out how optical properties of simple molecules are changing the world in which you live.
  • Quantum mechanics is good for something. You will use computational chemistry to predict or verify quantities that you measure in the laboratory.
  • Laboratory safety and proper waste disposal are necessary but not sufficient. In your laboratory work, you should always strive to reduce or eliminate the use or generation of hazardous substances in the design, synthesis, use, and disposal of chemical substances.

Experiments

There are four experiments in 5.33. Completion of all experiments is required.

  • Molecular spectroscopy of acetylene and methane
  • Magnetic resonance spectroscopy and ESR spectroscopy
  • Time-resolved electronic spectroscopy
  • Nitrogen scission by Molybdenum (III) Xylidene Complex

Laboratory Partners

Students will carry out all experiments with two laboratory partners. The importance of having lab partners with whom you can work compatibly and communicate conveniently cannot be overemphasized.

Working Hours

On average you should expect to spend the equivalent of three full afternoons a week in the lab. In some experiments more than this amount of time will be needed, and less in others. In some experiments, it may be possible for parts of the analysis, calculations, and discussion to be done outside of the lab. Reading about the experiments in advance is absolutely essential in 5.33.

Grading

Your grade in 5.33 will depend on the sum of scores for each of the four experiments. The grade for each experiment will be determined by several factors including the report, in-lab assignments and an experimental technique grade. There is no predetermined percentage of letter grades to be awarded.

The breakdown is as follows:

EXPERIMENT # TOPICS AND FORMATS POINTS
1 IR spectroscopy: written report 30 points
2 NMR and ESR: oral report 30 points
3 Time-resolved spectroscopy: written report 40 points
4 Nitrogen scission: Microsoft® PowerPoint® presentation 40 points
  Total 130 points

Teaching assistants will grade the individual experiments according to the following principles. The number of points given will primarily reflect the understanding of the experiment (in theory and practice), the analysis and interpretation of the data, and safe laboratory practice. The data quality, presentation, and the experimental skill of the student will also be considered, although to a lesser extent.

The manner in which these guidelines are implemented will vary somewhat with the type of report. The grade is partially subjective since the TAs must weigh the quality of the laboratory technique (including note taking) and the use of proper safety precautions in lab.

Preparation

Although they are demanding of laboratory skills and do introduce a number of new experimental techniques, the experiments in 5.33 are more oriented toward fostering a synthesis of your understanding of the concepts and theory being a phenomenon than was the case in 5.32 or 5.311. In other words, you cannot come into the lab without having read the experiment. Moreover, oral presentations will be expected to show a real grasp of the concepts underlying the lab work.

The TAs assigned to each experiment will have worked on the experiment before the start of the term. They will have been chosen because their area of graduate work corresponds roughly to the area of chemistry related to the experiment. You are encouraged to ask lots of questions while you are working on the experiment. This will be most effective if you have done your homework and know useful questions to ask.

Calendar

In this course, students are divided into three groups for the laboratory experiments. Each group begins working on a different experiment and completes a cycle of three experiments by the end of the semester. As a result, no two groups ever work on the same experiment at the same time. The experiments schedule shows this rotation format.

During the first six weeks of the course, the class attends a series of lectures on the general background and theory relevant to the experiments. A detailed discussion of each experiment is also presented to each laboratory group when they begin the experiment. These group sessions are designated as Conferences. Lecture and Conference topics are presented in the lecture schedule below.

Experiments Schedule

The lab manuals for the experiments referred to in the table below can be found on the Labs page.

DAY # GROUP A GROUP B GROUP C
1 Laboratory check-in
Begin first rotation
2-18 Nitrogen Lab: Day 1 to 17 Laser Lab and NMR/ESR Lab: Day 1 to 17 IR Lab: Day 1 to 17
19 Nitrogen Lab: Presentation practice meetings

Laser Lab and NMR/ESR Lab: Day 18

Laser Lab: Written report due

IR Lab: Day 18
20 Nitrogen Lab: Presentation practice meetings NMR/ESR Lab: Day 19 IR Lab: Day 19
21 Nitrogen Lab: Microsoft® PowerPoint® presentations NMR/ESR Lab: Oral reports IR Lab: Written report due
22 Nitrogen Lab: Microsoft® PowerPoint® presentations NMR/ESR Lab: Oral reports  
Begin second rotation
23-38 Laser Lab and NMR/ESR Lab: Day 1 to 16 IR Lab: Day 1 to 16 Nitrogen Lab: Day 1 to 16
39

Laser Lab and NMR/ESR Lab: Day 17

Laser Lab: Written report due

IR Lab: Day 17 Nitrogen Lab: Day 17
40 NMR/ESR Lab: Day 18 IR Lab: Day 18 Nitrogen Lab: Presentation practice meetings
41 NMR/ESR Lab: Day 19 IR Lab: Day 19 Nitrogen Lab: Presentation practice meetings
42 NMR/ESR Lab: Oral reports IR Lab: Written report due Nitrogen Lab: Microsoft® PowerPoint® presentations
43 NMR/ESR Lab: Oral reports   Nitrogen Lab: Microsoft® PowerPoint® presentations
Begin third rotation
44-59 IR Lab: Day 1 to 16 Nitrogen Lab: Day 1 to 16 Laser Lab and NMR/ESR Lab: Day 1 to 16
60 IR Lab: Day 17 Nitrogen Lab: Day 17

Laser Lab and NMR/ESR Lab: Day 17 Laser Lab: Written report due

61 IR Lab: Day 18 Nitrogen Lab: Presentation practice meetings NMR/ESR Lab: Day 18
62 IR Lab: Day 19 Nitrogen Lab: Presentation practice meetings NMR/ESR Lab: Day 19
63 IR Lab: Written report due Nitrogen Lab: Microsoft® PowerPoint® presentations NMR/ESR Lab: Oral reports
64   Nitrogen Lab: Microsoft® PowerPoint® presentations NMR/ESR Lab: Oral reports
65 Laboratory check-out

Lecture Schedule

The lecture notes for the lectures listed below can be found on the Lecture Notes page. On some indicated sessions, only the specified group is required to go to lecture.

DAY # LECTURE TOPICS
   
1 Mandatory safety lecture
Begin first rotation
2 Introduction, course organization
5 Classical description of spectroscopy, part I
7 Spectroscopy II
10 Principles for interpreting molecular spectra
11 Electronic spectroscopy (Group B only)
12 Vibrational spectroscopy
13 Analysis of IR spectra (Group C only)
14 Preparing oral presentations
16 Nitrogen scission with Molybdenum complexes
19 Magnetic resonance: NMR
21 Magnetic resonance: ESR
Begin second rotation
24 Electronic spectroscopy (Group A only)
27 Analysis of IR spectra (Group B only)
Begin third rotation
46 Electronic spectroscopy (Group C only)
48 Analysis of IR spectra (Group A only)




www.sharecourseware.org   Tell A Friend