IV. Structure of a Typical Abstract

Almost all scientists agree that an informative abstract should have the following five parts:

• Introduction. This is where you describe the purpose for writing your paper or doing research. The abstract begins by stating the main objective of the experiment/report in one or two sentences. Why should anyone care about the work you did? You have to tell them why. If you made an invention or developed a new procedure how is it better, faster, or cheaper than what is already out there? Motivate the reader to finish the abstract and read the entire paper.
• Problem Statement. Identify the problem you solved or the hypothesis you investigated.
• Procedures. The name of the methods used to complete the work is cited. Specifics about the materials used or set-up details are not included in the abstract. In most cases, one to three sentences should be sufficient for describing the methods. What was your approach for investigating the problem? Don't go into detail about materials unless they were critical to your success. Do describe the most important variables if you have room.
• Results. The experimental findings are reported next, in the most concise and direct manner possible. The length of this section of the abstract varies depending on the nature of the experiment. What answer did you obtain? Be specific and use numbers to describe your results. Do not use vague terms like " most" or " some."
• Conclusions. The conclusion section is a concise analysis and interpretation of the results of the work. This section should make an impact on the reader so that it is clear what the outcome of the scientific work is and what it means. State what your science project or invention contributes to the area you worked in. Did you meet your objectives?

· Using keywords. Using keywords is a vital part of abstract writing, because of the practice of retrieving information electronically: keywords act as the search term. Use keywords that are specific, and that reflect what is essential about the paper. Put yourself in the position of someone researching in your field: what would you look for? Consider also whether you can use any of the current " buzz words".

V. Things to Avoid

• Avoid jargon or any technical terms that most readers won't understand.
• Avoid abbreviations or acronyms that are not commonly understood unless you describe what they mean.
• Abstracts do not have a bibliography or citations.
• Abstracts do not contain tables or graphs.
• For most science projects, the abstract must focus on the latest research, and give only minimal reference to any earlier work.
• If you are working with a scientist or mentor, your abstract should only include procedures done by you, and you should not put acknowledgements to anyone in your abstract.

How to Meet the Word Limit

Most authors agree that it is harder to write a short description of something than a long one.  Here's a tip: for your first draft, don't be overly concerned about the length. Just make sure you include all the key information. Then take your draft and start crossing our words, phrases, and sentences that are less important than others. Look for places where you can combine sentences in ways that shorten the total length. Put it aside for a while, then come back and re-read your draft. With a fresh eye, you'll probably find new places to cut. Before you know it you will have a tightly written abstract.

VI. Sample Abstracts

Sample A

Conversion Of Optically Active Acid-Esters To Ester-Acid Chlorides Without Loss Of Optical Activity
Sean Purdy (Senior, Chemistry), Mason Marsh (Senior, Chemistry)
Stephen Flowers (Junior, Biology), Brenda Benfield (Junior, Biology)
Advisor: Dr. George B. Trimitsis, Chemistry

It has been reported in the literature that attempts to convert optically active acid-esters to their corresponding ester-acid chlorides by standard procedures is often accompanied by loss of optical activity. The purpose of the present investigation was to develop a suitable experimental procedure for the conversion of methyl (R)-3-methyl glutarate (1) to the corresponding ester-acid 2 with preservation of optical purity. A number of suitable reagents and reaction conditions for accomplishing this goal will be discussed. The present investigation also sought to develop an accurate and convenient assay for determining the enantiomeric excess of compounds 1 and 2. Although ¹NMR can be used for this purpose, it was found that GC-MS offers a number of distinct advantages. A comparison of the two analytical procedures will be presented.

 

 

Sample B

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