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Research Methods for Science PDF

237 Pages·2011·8.151 MB·English
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A unique introduction to the design, analysis, and presentation of M a scientific projects, this is an essential textbook for undergraduate r majors in science and mathematics. d e r • Gives an overview of the main methods used in scientific research, including hypothesis testing, the measurement of functional rela- tionships, and observational research. R • Describes important features of experimental design, such as the e s control of errors, instrument calibration, data analysis, laboratory e safety, and the treatment of human subjects. a R • Discusses important concepts in statistics, focusing on standard c h error, the meaning of p-values, and use of elementary statistical tests. M e • Introduces some of the main ideas in mathematical modeling, t h including order-of-magnitude analysis, function fitting, Fourier o transforms, recursion relations, and difference approximations to d differential equations. s • Provides guidelines on accessing scientific literature, and preparing f o scientific papers and presentations. R s c i e n research Methods c Michael P. Marder is Professor of Physics at The e University of Texas at Austin. He is co-director and co-founder of UTeach, a program preparing www.cambridge.org/Marder secondary teachers of science and mathematics. for s c i e n c e He has been teaching a course on how to do Extensive instructor’s manual containing scientific research, which led to the writing of sample lessons and student papers. this textbook. He is author of the graduate text Condensed Matter Physics. C Cover illustration: courtesy of Purestock/Getty Images. OV E R D E S IGN M i c h a e l P. M a r d e r : S U E W A T S O N MARDER: RESEARCH METHODS FOR SCIENCE CVR CMYBLK RESEARCH METHODS FOR SCIENCE A unique introduction to the design, analysis, and presentation of scientific projects,thisisanessentialtextbookforundergraduatemajorsinscienceandmath- ematics. Thetextbookgivesanoverviewofthemainmethodsusedinscientificresearch, including hypothesis testing, the measurement of functional relationships, and observationalresearch.Itdescribesimportantfeaturesofexperimentaldesign,such asthecontroloferrors,instrumentcalibration,dataanalysis,laboratorysafety,and the treatment of human subjects. Important concepts in statistics are discussed, focusing on standard error, the meaning of p-values, and the use of elementary statistical tests. The textbook introduces some of the main ideas in mathematical modeling, including order-of-magnitude analysis, function fitting, Fourier trans- forms,recursionrelations,anddifferenceapproximationstodifferentialequations. It also provides guidelines on accessing scientific literature, and preparing scien- tificpapersandpresentations.Anextensiveinstructor’smanualcontainingsample lessonsandstudentpapersisavailableatwww.cambridge.org/Marder. MICHAEL P. MARDER is Professor of Physics at The University of Texas at Austin. He is co-director and co-founder of UTeach, a program preparing sec- ondary teachers of science and mathematics. He has been teaching a course on howtodoscientificresearchwhichledtothewritingofthistextbook.Heisauthor ofthegraduatetextCondensedMatterPhysics. Research Methods for Science MICHAEL P. MARDER TheUniversityofTexasatAustin CAMBRIDGE UNIVERSITY PRESS Cambridge,NewYork,Melbourne,Madrid,CapeTown,Singapore, SãoPaulo,Delhi,Dubai,Tokyo,MexicoCity CambridgeUniversityPress TheEdinburghBuilding,CambridgeCB28RU,UK PublishedintheUnitedStatesofAmericabyCambridgeUniversityPress,NewYork www.cambridge.org Informationonthistitle:www.cambridge.org/9780521145848 (cid:2)c M.Marder2011 Thispublicationisincopyright.Subjecttostatutoryexception andtotheprovisionsofrelevantcollectivelicensingagreements, noreproductionofanypartmaytakeplacewithoutthewritten permissionofCambridgeUniversityPress. Firstpublished2011 PrintedintheUnitedKingdomattheUniversityPress,Cambridge AcatalogrecordforthispublicationisavailablefromtheBritishLibrary ISBN978-0-521-14584-8Paperback Additionalresourcesforthispublicationatwww.cambridge.org/Marder CambridgeUniversityPresshasnoresponsibilityforthepersistenceor accuracyofURLsforexternalorthird-partyInternetwebsitesreferredto inthispublication,anddoesnotguaranteethatanycontentonsuch websitesis,orwillremain,accurateorappropriate. Contents Preface pagevii 1 Curiosityandresearch 1 1.1 Coursegoals 1 1.2 Kindsofquestions 1 1.3 Researchmethodsforscience 3 1.4 Puttingmethodstogether 15 Assignments 15 2 Overviewofexperimentalanalysisanddesign 18 2.1 Hypothesis-drivenexperiments 18 2.2 Measuringvalues 30 2.3 Improvingexperiments 39 2.4 Safetyandethics 43 Assignments 48 3 Statistics 51 3.1 Motivationsforstatistics 51 3.2 Reducingmanynumberstofew 55 3.3 Probabilitydistributions 61 3.4 Connectingdataandprobabilitydistributions 70 3.5 WhathappenstoaveragesasN increases 75 3.6 CentralLimitTheorem 81 3.7 Comparingmanyexperimentalmeasurements 92 3.8 Datawithmanyvaluesofindependentvariable 97 3.9 Otherstatisticaltests 105 Assignments 105 4 Mathematicalmodels 112 4.1 Ingredientsofmathematicalmodeling 112 4.2 Estimation 121 4.3 Linearregression 125 v vi Contents 4.4 Matchingarbitraryfunctionstodata 128 4.5 Fouriertransforms 133 4.6 Deterministicmodeling 136 Assignments 146 5 Scientificinformation 151 5.1 Introduction 151 5.2 Writingaproposal 151 5.3 Writingscientificpapers 152 5.4 Scientificfigures 161 5.5 Givingscientificpresentations 166 5.6 Searchingforscientificinformation 168 5.7 Obtainingscientificarticles 172 5.8 Readingscientificpapers 173 5.9 Finalwords 177 Assignments 178 AppendixA Spreadsheetsforbasicscientificcomputation 182 A.1 Spreadsheetprograms 182 A.2 Basicprogramfeatures 183 A.3 Built-infunctions 189 A.4 Charts 194 Assignments 199 AppendixB ExtractfromGalileo’sTwoNewSciences 201 AppendixC Safetyinthelaboratory 204 C.1 Safetycontract 204 C.2 Chemicalsafetyforms 207 AppendixD Gradingrubrics 210 D.1 Writtenpresentation 211 D.2 Oralpresentation 222 Index 224 Preface This book accompanies a one-semester undergraduate introduction to scientific research. The course was first developed at The University of Texas at Austin forstudentspreparingtobecomescienceandmathematicsteachers,andhassince grown to include a broad range of undergraduates who want an introduction to research. The heart of the course is a set of scientific inquiries that each stu- dent develops independently. In years of teaching the course, the instructors have heard many questions that students naturally ask as they gather data, develop models, and interpret them. This book contains answers to those most common questions. Because the focus is on supporting student inquiries, the text is relatively brief, andfocusesonconceptssuchasthemeaningofstandarderror, p-values,anddeter- ministic modeling. If a single statistical test, such as χ2, is adequate to deal with moststudentexperiments,thetextdoesnotintroducealternatives,suchasANOVA, eveniftheyarestandardforprofessionalresearcherstoknow. Themathematicallevelofthebookisintermediate,andinsomeplacespresumes knowledge of calculus. It could probably be used with students who don’t know calculus,skippingthesesectionswithoutgreatloss. Thereisaninstructor’smanualthatdescribesdailyactivitiesfora14-weekclass thatmeetstwohoursperweekinaclassroomandtwohoursperweekinalab.Itis available at www.cambridge.org/Marder. The classroom sessions are not lectures coveringthematerialinthesechapters,butinsteadconsistinactivitiesfocusingon basic concepts. The text in many cases contains more complete explanation than thereistimetodeliverinclass. The basic idea for the class and hence of this book is due to David Laude, Professor of Chemistry and Associate Dean for Undergraduate Education at UT Austin. He had two essential insights: First, the way to learn about scientific research is actually to do some. Second, it doesn’t matter if research results are notnewsolongastheyarenewtothepersonwhodoesthem.Theingeniousorder vii viii Preface “BECURIOUS!!” in the first inquiry assignment (page 15) comes from his first assignmentinthefirstsemesterhetaughtit. Manyothercourseinstructorshavecontributed.MaryWalkerandDeniseEkberg both brought in course elements because of their backgrounds that span scientific research and secondary teaching. They emphasized the importance of procedures to ensure student safety, and also insisted on rubrics and checklists so that stu- dents received clear messages during an otherwise free-wheeling class of what wasacceptable,whatwasforbidden,whatwasdesired,andwhatwasdiscouraged. ThomasHillsemphasizedtheimportanceofopenquestions.Manyteachingassis- tantshavealsocontributedtothecoursecontent,particularlySedKeller,whowrote thefirstdraftoftheappendixonuseofspreadsheets. For many years, I have co-taught the class with Pawan Kumar, Professor of Astronomy, and Dan Bolnick, Associate Professor of Integrative Biology. Pawan Kumar helped create all the homeworks, and insistedwe find ways to tie research on closed questions back into research on areas of social concern. Dan Bolnick gentlyproddedmetothrowoutallpreviousapproachestostatistics,andmakeuse ofexamplesfrombiologythatworkedmuchbetter. Finally, I would like to thank Mary Ann Rankin, Dean of the College of Nat- ural Sciences, who insisted passionately from the start that future teachers in our UTeach program learn about scientific research, and has provided every form of supportneededtohelptheclassgrow. PreparationofthistextwaspartiallysupportedbytheNationalScienceFounda- tionunderDMR–0701373. 1 Curiosity and research 1.1 Coursegoals Sciencestartswithcuriosityabouttheworld.Itstartswithquestionsaboutwhythe sky is blue, why dogs wag their tails, whether electric power lines cause cancer, and whether God plays dice with the universe. But while curiosity is necessary forscience,itisnotenough.Sciencealsodependsuponlogicalthought,carefully plannedexperiments,mathematicalandcomputermodels,specializedinstruments, andmanyotherelements.Inthiscourse,youwilllearnsomeoftheresearchmeth- odsthatturncuriosityintoscience.Inparticular,youwilllearnto • Createyourownexperimentstoanswerscientificquestions. • Designexperimentstoreducesystematicandrandomerrorsandusestatisticstointerpret theresults. • Useprobesandcomputerstogatherandanalyzedata. • Treathumansubjectsinanethicalfashion. • Applysafelaboratoryprocedures. • Findandreadarticlesinthescientificliterature. • Createmathematicalmodelsofscientificphenomena. • Applyscientificargumentsinmattersofsocialimportance. • Writescientificpapers. • Reviewscientificpapers. • Giveoralpresentationsofscientificwork. Youwillnotjustbelearningabouttheseskills.Youwillbeacquiringandapplying thembycarryingoutscientificinquiries. 1.2 Kindsofquestions Testablequestions Everyscientificinquiryanswersquestions,andmostscientific inquiries begin with specific questions. People often wonder about questions that arehardtoaddress,suchas 1

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