Learning from Experience:
Aesop's Activities and Thinking Skills
in the General Chemistry Laboratory

 
by Craig Rusbult, Ph.D.

 
    A goal-directed educational strategy for helping students learn how to think more effectively is outlined on the home-page and is explored more fully in this page.  The teaching methods proposed here are based on two simple principles:  instruction should provide opportunities for experience, and help students learn from their experience.

    a personal introduction:  My academic background is in science (chemistry), history of science, and science education.  {for details, check PERSONAL GOALS on the home-page}   My recently completed PhD dissertation, a synthesis of ideas about scientific methods, is summarized in a website, SCIENCE AND DESIGN: METHODS FOR USING CREATIVITY AND CRITICAL THINKING IN PROBLEM SOLVING.
    I want to continue developing the ideas outlined in this website -- which is a project proposal, not a report on a completed project -- in cooperation with interested collaborators.  In doing this my main priority is to work with people who share my enthusiasm for the type of education described here.  { I know there are lots of you out there, because many of the ideas I'll be describing are borrowed from, or inspired by, the work of others;  I've just gathered and organized these ideas.  Hopefully this in-gathering, plus a few fairly new ideas of my own, will contribute some "added value" to the educational community. }
    Craig Rusbult ,  craigru178@yahoo.com

    This "Aesop's Activities and Thinking Skills" proposal was presented at a meeting of the AMERICAN CHEMICAL SOCIETY on March 21, 1999.

    All links on this page will keep it open; most links are within the page, and CAPITALIZED LINKS (to other pages) will open in a new window.  To prevent time-wasting reloads of this large page when using your browser's BACK-button, use this pseudo-link ( click here ) and then continue:

1Learning from Experience 
2Goal-Directed Analysis of Activities 
3Strategies for Effective Teaching 
4Examples of Aesop's Activities 


1. Learning from Experience
    An Aesop's Activities approach to instruction, with a goal-directed coordination of activities and methods, will help students gain useful experience.  It will also help students learn from their experience -- and remember what they have learned, and transfer this knowledge to new situations -- by explicitly directing attention to important aspects of what can be learned from each experience.  Both aspects are analogous to an Aesop's Fable in which the goal is learning a lesson about life, and "the moral of the story" directs attention to the main ideas.
    This section examines the second part of the educational process.  How can we help students learn more from their experiences?

    Personal Motivation:  According to a theory of intentional learning (Bereiter & Scardamalia, 1988), students will learn more when they invest extra mental effort, beyond what is required merely to fulfill schoolwork tasks, with the intention of pursuing their own cognitive goals.
    Intentional learning is A PROBLEM-SOLVING APPROACH to personal education because the student's goal is to transform a current state of knowledge (and skill) into an improved future state.  Effective intentional learning combines an introspective access to the current state of one's own knowledge, the foresight to envision a potentially useful state of improved knowledge that does not exist now, a decision that this goal-state is desirable and is worth pursuing, a plan for transforming the current state into the desired goal-state, and a motivated willingness to invest the time and effort required to reach this goal.

    As suggested by Perkins & Salomon (1988), the utilization of knowledge can be viewed from two perspectives: backward-reaching and forward-looking.  Students can reach backward in time, to use now what they have learned in the past.  Or they can focus on learning from current experience, motivated by their forward-looking expectations that this knowledge will be useful in the future.  { The future value of what is being learned may involve conceptual content or problem-solving process, or both. }
    In a forward-looking situation a learner is anticipating the future use of an idea in a context that may be similar (for basic application) or different (for application involving transfer).  When this occurs an idea becomes linked, in the mind of a learner, to several contexts -- including situations imagined in the future -- thus producing a bridge between now and the future.  This mental bridge can lead to improved retention (so knowledge is preserved) and application (so knowledge is more likely to be used).

    Intentional learning and forward-looking application are closely related, and both strategies are activated when a student wisely asks, "What can I learn now that will help me in the future?"  One of the main functions of instruction (and of a teacher) is to motivate students so they will want to learn.  Motivation can be intrinsic (to enjoy an interesting activity), extrinsic (to perform well on an exam), and personal (to improve the long-term quality of life).
    One useful motivational technique is a reflection activity that produces a "minds on" awareness (in contrast with students merely "going through the motions" so they can escape the lab) and promotes an attitude of intentional learning with a forward-looking expectation that the knowledge being learned will be personally useful in the future.



2. Goal-Directed Analysis of Activities
    Students gain experience by doing activities.  Opportunities for experience can be analyzed using an activity-and-experience grid (as shown below), with student activities in the top row and science experiences in the left column:

    science experiences

 student activities

 # 1  # 2 # 3   # 4  # 5
   A. generate experiments        yes  yes
   B. do physical experiment  yes  yes      yes
   C. hypothetico-deduction    yes yes    yes
   D. generate theories      yes    yes

    This grid clearly shows multi-function activities (scanning vertically down the column, we see that Activity #2 provides Experiences B and C) and repeated experiences (scanning the C-row horizontally, we see that experience with C occurs in Activities 2, 3 and 5).  And a grid may reveal gaps that will guide the design of new activities.  For example, an earlier version of this grid might have motivated a teacher, who noticed that after Activities 1-3 the students have no experience doing A, to add Activities 4 and 5.  Of course, a "yes" does not tell the whole story, and a grid with larger cells could show more detailed information, such as the difference between the hypothetico-deductive experiences in Activities 2 and 3.
    An activity-and-experience (A-and-E) grid can facilitate the design of Aesop's Activities by stimulating and structuring a search for activities to help students learn each type of "science experience" skill.  Also, in a grid the visually meaningful organization of information can improve our understanding of the educationally functional relationships between activities, and can help us visualize and plan the effective coordination of activities within a course.  When there is a repetition of experiences that are similar, or different yet supportive, the quality of learning will be improved by a carefully planned sequencing and coordinating (with respect to the types of experience, levels of sophistication, and contexts) of the activities that promote these experiences.  The overall goal is to develop a mutually supportive synergism between activities (and between experiences), to build a coherent system for teaching each type of cognitive skill, to produce a more effective environment for learning.
    But what cognitive skills are we trying to teach, and by using what types of instructional activities?  These questions, regarding experiences and activities, are discussed in the next two subsections.

    EXPERIENCES
    In the present context -- constructing an A-and-E grid to be used for a goal-oriented analysis of instruction -- a "science experience" is a thinking skill that we want students to learn.  The following list of roughly characterized experiences is intended to be useful rather than exhaustive.  And I think it will be useful mainly by inspiring you to think about your own goals for student learning.  You will probably find, as I have, that the process of actually doing A-and-E analysis will stimulate your awareness of "categories for experience."
    Examples of science experiences:  a student can make observations (with only the senses or using instrumentation);  analyze data (by finding patterns, relating data to a curve or equation, working with statistics,...), make a graph (by hand or using a computer), and do graphical analysis (visually or with math);  evaluate theories using hypothetico-deductive logic (by selecting a theory, doing theory-based thought experiments to generate predictions, making observations, and then comparing predictions with observations in order to estimate degrees of agreement and predictive contrast), make a hypothetico-deductive flowchart for identifying "unknowns" during qualitative analysis, use retroductive logic (by selecting or revising an existing theory, or inventing a new theory, in an effort to obtain a match between theory and known data);  formulate a scientific problem, analyze an existing experiment or design a new experiment, do a literature search (in books or research journals, or by using a CRC Handbook or electronic databank), examine scientific writing in a journal paper, solve problems (varying in difficulty from simple to complex, from algorithmic to improvisational), analyze a complex situation that involves conflicting goal-criteria, and apply concepts (such as limiting reagents, chemical reactivity,...) or construct concepts.  Student experiences also include skills that are "lower level" yet important, such as converting written instructions into personal action and performing cognitive/physical skills (filling and reading a pipet,...) in the lab.

    ACTIVITIES
    As above, for EXPERIENCES, this subsection is offered with humility, in the hope that it will be useful as a general orientation.  There is some overlap between the lists above and below, because usually it is convenient to define an activity by describing what students will do, and will therefore experience.
    Examples:  student activities can span a wide range of possibilities, including a discussion or debate, an experiment in lab, a project outside the lab, problems with students playing the role of detectives, questions about chemistry concepts or scientific methods or real-world "science and society" issues, case studies drawn from history or current events, research using computer simulations of nature, "direct learning" by reading or listening, a pause for quiet introspection, and reflection activities that direct a student's attention to opportunities for learning.
    Activities will vary in length:  a mini-activity may last only a few seconds, while a coherent mega-activity (composed of related mini-activities) can require several hours.
    Detailed examples of activities are available in Section 4.


3. Strategies for Effective Teaching
    Most teachers agree that education should help students learn higher-level thinking skills.  In a typical chemistry course, however, time is limited and there is lots of "content" to cover, so thinking skills are rarely given the attention they deserve.  But in chemistry labs there is more flexibility due to fewer expectations about content coverage, so more time can be devoted to thinking skills.  This section explores some possibilities for teaching in an "Aesop's Activities" lab environment.

    REFLECTION ACTIVITIES
    Activities that promote awareness (oriented either internally or externally) are at the heart of an Aesop's Approach to teaching and learning.  /   reflection:  the fixing of the mind on some subject;  serious thought;  contemplation.  (Webster's Dictionary)
    In an explicit reflection activity, a teacher directs a student's attention to "what can be learned" from an experience, and explains why a student might want to take advantage of the valuable opportunity.  In this way a teacher can encourage two important motivations: intentional learning and forward-looking application.
    In a lab, for example, students can learn the complementary thinking skills that are combined in a system we call scientific method.  One way to help students understand the mutually supportive relationships between thinking skills is to use my model of Integrated Scientific Method.  Students may become more motivated to pursue their own intentional mastery of thinking skills if they realize -- because a teacher calls it to their attention -- that similar problem-solving methods are used by scientists in different fields, so they can transfer skills from chemistry to their own field of science, such as biology or physics.  Engineering students can join in the fun, too, because similar methods are also used in a wide range of "design" fields where the goal is to design products and/or strategies.  { The essential elements in the process of design, and the relationships between design and science, are outlined in my model of Integrated Design Method.}
    But even if a student is not highly motivated, learning can be promoted by an implicit reflection activity.  For example, a student's attention can be directed to a learning opportunity by a simple request to discuss a question with the TA.  If this action-request shifts a student from a minimally aware "just going through the motions" mode to a more aware "active thinking" mode, it has served a useful purpose.  The educational function of reflection is similar to a basic principle of ACTIVE READING: "Will stop-and-go reading slow you down?  Yes, but that can be good.  If original awareness is minimal and you don't understand-and-remember what you read, it would be more appropriate to call it 'wasting time' than 'reading'.  Activity breaks can help you understand and remember; because of increased learning efficiency, brief pauses for thinking will save you time in the long run."
    A mixture of teaching styles, including both explicit and implicit requests for reflection by students, is practical and effective.  For example, at the beginning of each semester I give students a handout with TRUE STORIES about a skier (me) and a welder (a friend) that emphasize the value of a "searching for insight" approach to studying.  Occasionally during the semester I'll refer to the principle of active reflection in a general way, as illustrated in these stories.  But more often this concept is situated in a specific context -- "it will be useful for you to learn this" -- or in implicit requests that tend to promote active thinking automatically, independent of motivation.  And perhaps students will discover that thinking really is fun, and they will become motivated to do it more often and more skillfully!

    DISCUSSION-BASED LABS
    While serving as a Teaching Assistant (TA) at the University of Wisconsin, I tried a teaching experiment in the second semester of an introductory physics course.  Instead of the traditional method, with students writing a lab report that will be graded by the TA, we converted the writing into talking.  Each week I split the lab into parts and developed activities -- data to gather, calculations to do, problems to solve, concepts to ponder, questions to answer,... -- for each part.  When students working in Group C finished the activities for Part 1, they called me over and we discussed the activities.  When everyone was satisfied that our discussion for this part of the lab was finished, I made an X in the appropriate cell of a discussion grid (shown below) and they moved on to Part 2.  When a group had X's for each part of the lab they were free to leave.

 

A

B

C

D

E

F

G

Part 1

    

X

        

Part 2

              

Part 3

              

Part 4

              

    During our discussion of a lab activity, what did we talk about?  Most of the core questions and calculations came from the standard lab manual, with occasional modifications or "don't bother doing this" simplifications, and frequent supplementation with followup questions, usually by me and sometimes by students.  Within each lab I improvised in an effort to achieve optimal pacing.  In a 2-hour lab period, having 28 discussions (as in the grid above) is difficult, even for a fast-talking, quick-listening TA, so two or more groups would sometimes combine for a discussion.  This worked well, and if students did have to wait for me, this was all right because they could talk with each other or begin work on the next part of the lab.
    The response to these discussion-based labs was positive and enthusiastic.  Compared with their traditional labs from the first semester -- writing individual reports and eventually (a long time after leaving the lab) getting feedback that was not very detailed and not very useful -- students said that with our discussions they learned more and they had more fun, due to interactions with each other and with their TA.
    My own learning and fun also increased due to the discussions, and because the time I would have wasted on a boring, unpleasant task (grading lab books) was invested in a productive activity (preparing for labs) that was intellectually stimulating and enjoyable.  With a no-grading policy, during our discussions in lab I could focus my attention totally on teaching rather than judging.  {And students could focus on learning rather than being judged.}  For example, I could ask and answer any question freely, thinking only about what was best for the students.  When I did decide to withhold information my only motivation was pedagogical, and the purpose was to challenge students, to make them think, to let them play a more active role in their own learning.  I never had to worry about whether I was "giving away too much information" about a question that I would be using to assign grades.

    Discussion-based labs, which are extremely useful (but not essential) for an Aesop's Activities approach to learning, offer many educational advantages.  But two critical questions are discussed later.

    GOAL-DIRECTED DESIGN OF INSTRUCTION
    How can we improve our labs?  A general process of design -- by developing goals, activities, and teaching methods -- is outlined below.  A detailed analysis of the design process is provided by a model of Integrated Design Method:  first define goals (in this case, the desired "learning outcome" characteristics for a system of labs);  then develop ideas for labs, and do mental experiments (to generate predictions about student experiences and learning outcomes) or do actual experiments (to generate observations about experiences and outcomes); compare predictions with goals or compare observations with goalsadjust ideas (and maybe goals) in an effort to achieve a match between predictions/observations and goals.  { In order to learn from a wider range of educational "experiments" we should consider all relevant experience, both first-hand and second-hand. }
    This process is inherently complex because effective instructional design requires the careful consideration of many interrelated factors and a wide variety of potential solutions.  It is even more complicated in a large university where -- by contrast with a smaller school (or high school) where one course instructor is responsible for both lectures and labs -- many people are involved, with ideas about labs coming from instructors, TAs, lab director, coordinator, and support staff.  In such a setting, typically there is a diversity of opinions about goals, activities, and methods, so it will be impossible to totally please everyone.  Instead, we can agree that a reasonable objective is to aim for an optimal balancing of our alternative visions for education.  Here are a few of my own opinions:

  • Lab developers should be flexible, keeping an open mind about a variety of possibilities.  For example, I think instruction should include learning that is direct, action, and inquiry:
        direct learning by reading or listening can be especially effective when techniques of actively constructive reception learning are explained (as in my TOOLS FOR LEARNING AND PROBLEM SOLVING website) and emphasized, but the most important factor is whether students are motivated to learn.
        action learning should be the main focus in labs, with students learning by doing.
        inquiry learning can be very effective -- especially for promoting active thinking and for increasing motivation -- when it is done well.  But if it isn't done well, inquiry can be very frustrating for students and teachers.  The key to effective guided inquiry instruction is achieving a balance between making a problem too easy and too difficult, adjusting the balance by carefully controlling the information that is provided and withheld.  Also, I think inquiry instruction should be used, but in moderation;  it should not be the main mode of teaching.  {principles and examples of inquiry}
     
  • Students should engage in a variety of experiences and activities, including reflection activities, that require doing, thinking, discussing (by listening and talking), and writing.
     
  • When learning methods of scientific thinking, students should have first-hand experience (by solving problems) and second-hand experience (by listening to stories about the problem-solving methods that scientists use, and by observing the "expert" methods a teacher uses).
     
  • Labwork should often be done in groups, to take advantage of the many benefits of cooperative learning.  But sometimes -- especially for practice in using lab equipment, but also for problem solving -- students should work individually.   { During group activities, some students are more physically and mentally active than others, so "science experiences" will vary from one student to another. }
     
  • Labs should focus on helping students learn thinking skills.  While doing this, students will also learn chemistry concepts, but usually these should not be the primary goal.  {examples}
     
  • It can be useful for educators to think like radical revolutionaries, making decisions based on merit (not tradition) and examining every activity (old or new) to ask whether it performs a valuable educational function.  *  On the other hand, when the overall goal is to achieve maximally beneficial results in a limited amount of time, usually "it is more practical and immediately productive... to build on what already exists" by working to modify and improve a current set of labs.
        * Also, tradition is intentionally ignored during the first part of a freewheeling "brainstorm and edit" thinking strategy that begins with a brainstorming phase in which critical restraints are minimized to encourage a free creativity (by trying to see in a new way, to imagine new possibilities) while generating ideas, followed by an editing phase in which these ideas are critically examined and evaluated.

    •     In expressing these views there are many "shoulds" that I hold with varying degrees of confidence and perceived importance.  But I know there are other rational perspectives, and I recognize the need for flexibility and cooperation as we "aim for an optimal balancing of our alternative visions."

        TEACHING ASSISTANTS
        In a large department, it is difficult to get consistently high quality of teaching in general chemistry labs that are taught by TAs who have a wide range of abilities, experience, and motivation.  An appropriate question -- Should we therefore avoid any instruction that cannot be taught equally well by all TAs? -- is discussed later.}  This section will focus on three TA-related aspects of labs: preparation, feedback, and policies.
        preparation:  The goal is to help TAs be maximally effective with minimal investment of their own time.  In weekly training/discussion sessions, supplemented by written tip-sheets, we can help TAs prepare for labs.  { In addition, there can be special "help sessions" for foreign TAs who are not fluent in English, especially to help them prepare for discussion-based labs. }
        feedback:  TAs are the most valuable source of feedback about what is happening in labs and how this can be improved, since they are teaching the labs and have direct contact with students.  Feedback can be gathered in the weekly preparation sessions, by talking with TAs during or after labs, or observing interactions during lab, and in informal conversations and e-mail.  TAs will be more eager to provide feedback if they know their input will be used when labs are designed and policies are determined.  /   The lab director (or support staff,...) can also gather feedback directly from students, but TAs are in a better position to do this on a regular basis.
        policies:  When designing labs and deciding course policies, one objective should be to make life more pleasant and productive for TAs.  We should always consider the Golden Rule by asking:  If I were a TA, what would I want the policy to be?  Even better, ask TAs what they want the policy to be.  Even though their opinions should not be decisive, since other factors are involved, "what TAs want" should be an important consideration.

        DISCUSSION-BASED LABS, PART 2
        For students, discussion-based labs (DB labs) can produce improved learning with more fun.  But if the quality of their lab experience depends on interactions with a TA, what happens when students get a TA with less ability, experience, or motivation?  And if at the end of a lab the discussion grid is totally filled with Xs, there is no basis for distinguishing among students when assigning grades.  These two critical questions are discussed in this section.

        I'm fairly shy in many situations, but I enjoy thinking and talking about ideas.  For me, DB labs make interactions with students much easier, more enjoyable, and more effective for teaching.  Why?  If there is no "reason" to talk with students, and everything depends on my own social intuitions and actions, I often find it difficult to achieve a balance between ignoring students and bothering them with too much attention.  But with the grid to provide motivation (it must be filled with Xs before they can leave the lab!) students initiate conversations, and we have a focus for our discussions, which usually are intrinsically interesting for all of us, and also lead to small-talk that produces social and emotional bonding, both student-TA and student-student.  DB provides a useful organizing structure for interactions that lead to learning.
        Consider four types of TAs in DB labs.  1) Those like myself, who are a bit shy but can talk about ideas, will usually do better with DB.  2) TAs who are socially fluent will have a great time, and so will their students.  3) Those who are shy and not skilled at talking (even about ideas and chemistry) probably will improve their skills, and will become better teachers.  4) Foreign TAs, if they are not skilled in English, begin discussions with a fundamental disadvantage.  /   TAs in the last two categories will improve their social and linguistic skills as a natural result of the "listening and talking" practice that occurs with DB labs.  In conventional labs these TAs usually take the easy way out by ignoring students and avoiding conversations.  By contrast, the structure of DB will lead to interactions with students, and thus to opportunities for learning -- by students and by TAs.
        But the main goal should not be consistency in TA quality.  Although this will vary in DB-labs as in other aspects of teaching, and some TAs will perform better than others, it is more important to ask the pragmatic question of whether "the greatest good for the greatest number of students" is promoted by DB.  /   To achieve consistently high quality of teaching in labs, TA preparation is a high priority.  Good preparation will help all TAs, especially those in the latter two groups who begin with a lower level of verbal comfort and/or fluency, to improve their teaching quality.  For example, these TAs (and perhaps other TAs) might do better if they try to get students to do more of the talking during discussions.  And just "knowing their stuff" will help TAs feel better and teach better.

        If labs are part of a general chemistry course, rather than the entire focus of a separate course, what are the options for weighting the lab grades within this course?
        1. No weight, so TAs don't assign lab grades.  { In four semesters of teaching physics I never assigned a lab grade, and I thought this worked fine. }
        2. Place less weight on lab grades when determining the course grade.
        3. Place more weight on lab grades, to give students more external motivation for learning.
        Discussion-based labs can be used with any of these grading policies.  I prefer 1 or 2, but I realize that this may be the most controversial aspect of my proposal, and I'm flexible about the question of grading.

        What are the connections between accountability and motivation?  If there are no lab grades, as in Option 1, will this hinder learning?  Maybe not, because:
        When a lab is well integrated with a course, the course-exams can be designed to test the chedmistry concepts being learned in labs, and maybe even the thinking skills that are the main focus of labs.
        There can still be accountability, even with a policy of "no official grading."  Just let students know that labs will affect their course grade negatively if they skip labs or are uncooperative (in attitudes or actions), or positively if they do noticably good work in labs, especially if they are on a borderline between grades.  {In my experience, most students have been consistently cooperative.  Although external compliance does not guarantee full internal attention, it is an encouraging indicator. }
        Internal motivation can exist without external accountability.  I emphasize that, for students who will be rewarded for thinking in their professional careers (and in life as a whole), there is a high intrinsic value on learning how to think more skillfully.  Motivations for pursuing long-term intentional learning should be independent of grading policies.  {Of course, the intrinsic value of learning should be strongly emphasized, no matter what grading policy is adopted. }

        If grades are assigned for lab, what grading criteria can be used?
        For activities done in lab:  TAs can evaluate the quality of labwork and discussions;  labs can be designed with built-in accountability for work that is qualitative (such as doing detective work to find the identity of unknown chemicals) or quantitative (determining a concentration or...).
        Written reports for work done inside the lab or outside.
        Oral exams, skill exams (to test lab techniques), and written exams.
    comments:  Many of these (labwork, discussions, accountability, reports, skill exams) are typical components of conventional grading policies.  Oral exams can be excellent, but only if they're done well;  this is difficult and impractical when using TAs with a wide variety of abilities and experience, but oral exams might work well when all labs in a course are taught by one person, as in a small department or a high school.  Written exams deserve closer examination, which is done in the following two paragraphs.
        A written lab-exam can ask questions ranging from simple data analysis to high-level problems.  Simple algorithmic problems are easy to make by making variations (changing the chemicals, numbers,...) on a few basic themes.  But it is a challenge to construct high-level problems that provide a reliably accurate measure of thinking skills.  If an exam will be used to assign lab grades, we want to differentiate between varying levels of mastery by asking problems that vary in difficulty.  There should be some problems that most students solve, others that only a few students solve, and some between these extremes.  And success on problems should be correlated with mastery of the thinking skills that have been the focus of learning in labs.
        The difficulty of constructing high-level problems poses significant challenges.  It requires difficult creative and critical thinking, so in a small department the "benefit per student per hour invested in making new problems each semester" may not be worth the effort, and buying problems from test-constructing specialists may be expensive.  {A free exchange of exam problems between schools could be useful.}  Why do we need new problems?  For a school of any size, new problems will increase the level of justice in grading.  To minimize the advantages for students who have access to test files from an organization (a fraternity, sorority, dormitory, instructional center, athletic department,...) or tutor, questions from old exams should be available to all students.  Therefore, new problems are necessary.  {But including some old problems can be useful for motivating students to study problems from previous exams, and to decrease the number of new problems needed. }  In a large department with parallel courses and sections-within-courses that share the same system of labs and the same new questions, all students should take a lab exam at the same time or there will be "leaks of information" from students who have the exam earlier.  And to avoid leaks, TAs should not see the new problems until students see them;  TAs should "teach to the exam" by knowing the general type of exam questions (similar to those on previous exams), but if they know the specific questions there will be unavoidable ethical dilemmas about what to teach.

        METHODS FOR PROBLEM SOLVING
        This is a bonus section, since "models for methods" are not essential for any of the lab proposals in this paper.
        There are many interesting possibilities for using my models of Integrated Scientific Method (ISM) and Integrated Design Method (IDM) for instructional design or for instruction, to help students learn the interrelationships between the many different aspects of creativity and critical thinking that are coherently combined in the problem-solving methods used by scientists and designers.
        In labs an obvious starting point is the hypothetico-deduction (in Section 1 of ISM) that is the logical foundation for scientific methods of thinking.  This leads naturally into the closely related logical process of retroduction (Section 5).  Students should have an opportunity to analyze and design experiments (Section 6).  Students can even think about personal-cultural factors (Sections 3 and 8), as in a discussion of how numerical values get into the CRC Handbook, and how scientists handle their disagreements with each other.  And ISM's analysis of problem solving (in Section 7) can introduce students to the generalizability and transferability of scientific methods.
        In fact, the methods of science (described in ISM) are a "special case" of a more generalized method for design (described in IDM) in which a designer sets goals (for the desired characteristics of a product, strategy, or theory), formulates initial ideas, and then does experiments (either mental or physical) to produce predictions or observations that can be compared with the goals, to serve as a basis for modifications of the ideas.
        If you want to learn more about these models, visit my website, "Science and Design: Methods for Using Creativity and Critical Thinking in Problem Solving" -- especially the HOME-PAGE and the first four pages:  GOALS   SCIENCE   DESIGN   EDUCATION .

     

     

    4. Examples of Aesop's Activities

        This section describes examples of goal-oriented lab activities, drawn from my experience as a TA at the University of Wisconsin in Madison.  /   It is not finished now, on March 26.  Parts of it, written in this blue-green color, are extremely rough or incomplete.  A more complete version will be posted on Sunday, March 28.

        Some activities, such as A-1 (Competing Reactions), A-2 (Halogens and Halides), B-2 (Calibration Logic) and B-3 (The Logic of Le Chatelier), include examples of reflection activities intended to direct students' attention to opportunities for learning.  Others, such as B-1 (A Mass-Spec Problem), merely show an activity that provides a specific type of experience.  Of course, reflective questions could be asked for these activities, even though I haven't done so here.
        These activities will be described in 5 subsections:  Observation-Based Thinking SkillsHypothetico-Deductive LogicData AnalysisMiscellaneous , and Guided Inquiry .

     

    4A. Observation-Based Thinking Skills
        Experimental activities can help students learn to use observation-based logic and to make mental connections between levels of thinking: macro, micro, and symbolic.  As a secondary benefit, students also learn chemistry concepts.

    4B. Hypothetico-Deductive Logic
        Students should have opportunities to use hypothetico-deductive (HD) logic.  Here are several activities involving HD reasoning, selected from labs at UW:
     

  • C-2.  THE "SOCIAL AND LOGICAL" PROCESS OF SCIENCE. 
        As a prelab, students do the first Data Analysis handout, described above.  In lab they measure the density of an unknown liquid (a mixture of ethylene glycol and water), and we discuss two sets of questions:  1) What are your estimates for the precision of your measurements?   2) What are your estimates for the accuracy of your measurements?
        To introduce these questions, I ask students for their definitions of precision, and how precision differs from accuracy.  I provide four sets of data, and for each set I ask them to make a rough estimate (is it high or low) for precision and accuracy.  { all four possible combinations are represented: high precision with high accuracy, high with low, low with high, and low with low }  This provides an opportunity to discuss random errors and systematic errors.  Then we look at their data.
        The second set of questions, re: accuracy, is more interesting and challenging.  My initial goal is to get students to say "We can't estimate accuracy because we don't know the true value for the density of our unknown liquid."  Then I ask them about the values for density (and Avagadro's Number, the speed of light,...) in the CRC --- how did these values get into the CRC?  Here, the goal is to develop the concept of evaluations (and decisions and declarations) that are made by a scientific community (or sub-community or committee) or by an individual author or editor.
        This is followed by a series of questions about rationally justified confidence:  Would you be more confident about a value based on 5 experiments done by the same person, or 5 experiments done by a large research group?  What if these experiments were done by 4 large groups scattered around the world?  { we develop the concept of creative and critical thinking by individuals, in-groups, and out-groups }  /   Would you be more confident if 5 similar experiments gave the same value, or if 5 different types of experiments gave the same value?  { this lets us discuss several ideas, such as systematic errors, background assumptions, theoretical and experimental interdependencies, and we develop a concept of independent confirmation }  At some point, before or after this lab, in lab or lecture, examples of independent confirmations (such as multiple ways to calculate Avagadro's Number, or...) are described, and interdependencies are discussed.  /       What do scientists do if two different techniques give different results?  { we discuss experiments (reproducibility; analysis and design), critical thinking, arguments and consensus,... }  When they compare and evaluate results, can scientists be biased?  { we discuss potential sources of bias, including (but not limited to) "investments" of finances (such as owning expensive instruments of one type but not the other), experience (knowing how to perform and analyze one type of experiment better than the other), or ego (when there have been public declarations that one of the techniques is superior) }  Is there anything scientists can do to minimize the effects of these biases?
        This set of questions offers many opportunities for learning about the process of science (social and otherwise), about the wide variety of "strategies for problem solving" used by scientists.  If a teacher has some knowledge and imagination, awareness and enthusiasm, many types of discussions (short or long, taking off in many different directions) are possible.  /   Some relevant concepts are discussed in my model of INTEGRATED SCIENTIFIC METHOD --- especially in Sections 2 (conceptual factors), 3 (cultural-personal factors) and 8 (thought styles).  And on another web-page each concept (such as EXTERNAL RELATIONSHIPS BETWEEN THEORIES) is discussed in more detail.
    •  

    4D. miscellaneous

  • D-1.  QUESTIONS ABOUT LIQUID NITROGEN.  {this is the same description as on the home-page}  Students blow up a balloon, cool it in liquid nitrogen, let it warm up, and then discuss thought-stimulating questions:  In what state (s, l, g) is each component of air? {a table of freezing and boiling points is provided}  What is missing from the table? {it is a dry-air table so we can talk about humidity,...}  How does air in the balloon compare with air in the room? {due to the body's metabolism, balloon-air contains more H2O and CO2 but less O2 and the same N2}
     
  • D-2.  DIFFERENT WAYS TO SUBTRACT.  {this is the same description as on the home-page}  Students weigh a block in four ways, with and without the taring mechanism of the scale.  Later in the semester, the analogous concept of a blank stimulates thinking about the logical functioning that is designed into spectrometers.
     
  • D-3.  more examples
     


    •  

    4E. GUIDED INQUIRY

        4E-a. Principles of Inquiry Teaching
        Opportunities for inquiry occur when gaps in knowledge (intentionally designed into an activity) produce a situation in which students are required to think, and are allowed to think, on their own.
        During guided inquiry instruction the teacher, like a writer of a good mystery story, should aim for a level of challenge that is "just right" so students will not become bored if a problem is too easy, or frustrated if it is too difficult.  The goal is to provide enough guidance but not too much.  Ideally, students will succeed, and in doing so they will feel genuine intellectual and emotional satisfaction because their success is highly valued due to the obstacles they overcame during the process of problem solving.
        For most students, inquiry experience will promote active thinking and motivation, if the instruction is well designed.  But if not, the inquiry is more frustrating than stimulating.  { Some frustration can be beneficial, but usually it should be limited and temporary. }
        The level of challenge can be adjusted by preparation before a problem begins (by giving students prior experience in solving similar problems, by selecting the phenomena to be studied and the problems to be solved, and by controlling the conceptual knowledge and procedural information that is provided and is withheld) and by coaching during the process of problem solving (by observing students as they work, and providing guidance by asking and answering questions, directing attention and promoting reflection).

        A strategy for building skills:  If students are having trouble with a certain type of problem, activities can be designed to help students gradually improve their skills in this area, thereby allowing a gradually increasing level of difficulty for the problems being solved.
        Another teaching strategy is to set the initial difficulty higher than most students can cope with, and then give personally customized assistance when it is needed, while students are solving the problems.  These improvised coaching interactions let a teacher adjust the level of difficulty, and also provide opportunities to facilitate learning that is conceptual and procedural, intellectual and emotional.

        For another perspective on principles of learning, quotations from a "cognitive apprenticeship" paper (Collins, Newman & Brown, 1987) describe six ways a teacher can provide guidance:  by modeling, coaching, and scaffolding, and by encouraging articulation, reflection, and exploration.

        EXAMPLES
        This website provides two examples of inquiry instruction:  an in-depth study of a genetics classroom, and an outline of a chemistry experiment (in Section 4E-b).

        An In-Depth Study
        My Ph.D. dissertation had two main objectives:  to construct a model of INTEGRATED SCIENTIFIC METHOD and to use this model as a framework for the integrative analysis of an innovative inquiry course taught by an award-winning teacher.

        4E-b. An Inquiry Lab
        OBJECTIVES:  In a lab activity for General Chemistry at the University of Wisconsin in Madison, students design experiments to determine the enthalpy change per mole of acid-base reaction (in Part 1) and the precise concentration of a solution of acetic acid (in Part 2).
        RESOURCES that are available include:  a 25 mL graduated cylinder, thermometer (connected to computer for recording), styrofoam coffee-cup calorimeter;  .1 M NaOH (in lab the molarity will be given to the nearest .001 M), 5% solution of Acetic Acid (AA);  and free information (from CRC, lab-book, textbook,...).  /   Also, the weighing scales cannot be used for this experiment. (but this limitation is optional)

        The following discussion is in two parts:  an equation that provides a framework for experimental design;  questions that show some possibilities for guiding students.

        An Equation
        Early in the semester I remind students about a commonly used "miles per hour" strategy:  If they want to find the speed in miles per hour, they divide the miles traveled (for a certain part of a trip) by the hours (for the same part of the trip).  In chemistry the first analogous application is a grams per mole strategy, dividing the grams (for a certain amount of substance) by the moles (for the same amount of substance).  { A typical problem that can be solved using this strategy is:  If 973.0 g of a compound, X2O, is heated in H2 gas and is converted into 864.2 g of pure X, what is the atomic weight and chemical symbol of X? }  For Part 1 of this experiment we can use ana analogous strategy by.....

        an explanation for the reader:  Most of the rest of this "inquiry labs" section has been eliminated.  Why?  To prevent my own students (and those of other teachers at UW-Madison) from reading about their experiment on this page, getting "easy answers," and thereby spoiling their opportunity for a valuable learning experience.  If you want to get the full unedited version of this section, send an e-mail to me (craigru178@yahoo.com) with an explanation of who you are and where I can find your e-mail address on an institutional website (I'll check this to be sure you're not a UW student trying to avoid thinking) and I'll send the section to you (in an html file you can read in your web-browser) as an e-mail attachment.

        Hints and Questions {and Answers} to Use or Avoid
        This subsection shows, by describing potential hints and questions and answers, some strategies a teacher might use for adjusting the level of challenge in this inquiry lab.  At one extreme, we could just list the objectives and resources and say "do it," with no additional questions, hints, or information.  The other extreme is to make the problem easy for everyone, with minimal challenge, by asking every question below (and more), discussing each in detail, explaining how to use "what can be learned from each question" in the experimental design, and completely answering all the questions of every student.
        I don't make any claims about which of the questions below should be asked and discussed (and in what depth), because effective inquiry teaching depends on the students (their abilities and experience, motivations and attitudes), the context of instruction, and the goals of education.  The main purpose of Section 4E-b is to illustrate the complexity of inquiry teaching whose goal is an intermediate level of clarity (for the purpose of producing an optimal level of challenge), in contrast with the simplicity of direct teaching whose goal is a maximum level of clarity.

        Here are some possibilities:

        to the reader:  Much of this section has been removed but (as explained above) you can get all of it by sending an e-mail request.

        As discussed above, the purpose of this section is to illustrate the complexity of inquiry teaching, to show the difficulties involved in achieving a "just right" level of challenge, so that -- for most students -- the inquiry experience is stimulating rather than frustrating.

        moderation in the use of inquiry:
        I think every student should have many opportunities for small-scale guided inquiry and at least one intensive experience, as in Sue's course , because inquiry promotes experience that is productive (for learning the process of science and how to cope with problem situations in which "what to do next" is often not clear) yet is unfortunately rare in conventional education.
        But I don't think it would be beneficial if every course was taught using inquiry methods, because even though inquiry can help students learn scientific thinking skills (especially in their first few experiences) and can improve motivation, usually it is not efficient for learning the concepts of science. For a well-rounded approach to lifelong education, we should encourage students to learn by active inquiry and also by active reading, listening, and discussion. { Is "active reading" possible? }
        a summary: In my opinion, some inquiry experience is essential, but it should not be the main format for education.

     

     

        APPENDIX

        What is an Aesop's Activities approach?

        This website's original home-page, which describes an Aesop's Approach to instruction, appears below.  You can also check out the current homepage.

        Aesop's Fables are designed to teach lessons about life.  In a similar way, Aesop's Activities can teach the higher-level thinking skills used in science.  This analogy helps to focus attention on the principle that education should be goal-directed, with instructional activities done for a purpose.
        This website -- which is a proposal for a project I'd like to pursue in cooperation with other chemistry educators, rather than a report on a finished project -- describes a goal-directed strategy for helping students learn thinking skills in the undergraduate general chemistry laboratory:  1) define educational goals in terms of the skills [and associated concepts] to be learned by students,  2) design activities to provide experience with these skills, and  3) develop teaching methods that will direct students' attention to "what can be learned" from their experiences.
        While pursuing this 3-step strategy we could work through the steps in order and aim for a fresh beginning with a newly developed set of goals, activities, and methods.  But another approach, which is less radical because it builds on what already exists, is usually more practical and immediately productive.  In this approach there is a flexible overlapping of steps, beginning with a goal-oriented analysis of the activities now being used in a course.  During this analysis, which combines Steps 1 and 2, a careful examination of activities (in Step 2) stimulates productive thinking about goals (in Step 1), which in turn will inspire revisions or supplements to the existing activities (in Step 2).  Then in Step 3, as a logical extension of the analysis in the first two steps, we add reflection activities -- designed to encourage introspective reflection by students about what is being done (Step 2) and what can be learned (Step 1) -- to the activities already being done in a lab.  The overall result of this Aesop's Activities approach is the modification of a current set of labs.

        Some techniques for guiding inquiry, from Collins, Brown & Newman (1987, pages 481-483):
        "Modeling involves an expert's carrying out a task so that students can observe and build a conceptual model of the processes that are required to accomplish the task. In cognitive domains, this requires the externalization of usually internal (cognitive) processes and activities -- specifically, the heuristics and control processes by which experts make use of basic conceptual and procedural knowledge.
        "Coaching consists of observing students while they carry out a task and offering hints, scaffolding, feedback, modeling, reminders, and new tasks aimed at bringing their performance closer to expert performance. Coaching may serve to direct students' attention to a previously unnoticed aspect of the task or simply to remind the student of some aspect of the task that is known but has been temporarily overlooked.
        "Scaffolding refers to the supports the teacher provides to help the student carry out a task. These supports can either take the forms of suggestions or help."
        "Articulation includes any method of getting students to articulate their knowledge, reasoning, or problem-solving processes in a domain.
        "Reflection enables students to compare their own problem-solving processes with those of an expert, another student, and ultimately, an internal cognitive model of expertise. Reflection is enhanced by the use of various techniques for reproducing or 'replaying' the performances of both expert and novice for comparison.
        "Exploration involves pushing students into a mode of problem solving on their own."

        An Example of Guided Inquiry Instruction
        In a conventional course, students typically learn science as a body of knowledge but not as a process of thinking, and rarely do they have the opportunity to see how research science becomes textbook science.  A notable exception is a popular, innovative genetics course taught at Monona Grove High School by Sue Johnson, who in 1990 was named "Wisconsin Biology Teacher of the Year" by the National Association of Biology Teachers, due in large part to her creative work in developing and teaching this course.  In her classroom, students experience a wide range of problem-solving activities as they build and test scientific theories and, when necessary, revise these theories.  After students have solved several problems that "follow the rules" of a basic Mendelian theory of inheritance, they begin to encounter data (generated by computer) that cannot be explained using their initial theory.  To solve this new type of problem the students, working in small "research groups", must recognize the anomalies and revise their existing theory in an effort to develop new theories that can be judged, on the basis of the students' own evaluation criteria, to be capable of satisfactorily explaining the anomalous data.
        As these students generate and evaluate theories, they are gaining first-hand experience in the role of research scientists.  They also gain second-hand experience in the form of science history, by hearing or reading stories about the adventures of research scientists zealously pursuing their goal of advancing the frontiers of knowledge.  A balanced combination that skillfully blends both types of student experience can be used to more effectively simulate the total experience of a scientist actively involved in research.  According to educators who have studied this classroom, students often achieve a higher motivation level, improved problem-solving skills, and an appreciation for science as an intellectual activity.

        For details about this fascinating course, you can visit a web-page that describes THE COURSE AND ITS ANALYSIS and includes a link to let you download my dissertation.

        Can reading be active?
        In her excellent book "On Becoming an Educated Person" Virginia Voeks describes how you can learn more when you read: "Start with an intent to make the very most you can from whatever you read.  Treat the author as you do your friends.  When talking with a friend, you listen attentively and eagerly.  You watch for contributions of value and are sensitive to them.  You actively respond to his ideas with ones of your own.  Together you build new syntheses."  Reading is more fun and more productive when you approach it with an attitude of enthusiastic expectation.  Expect the author to share new ideas and fresh perspectives.  When you search with alert awareness for useful ideas, you will see them.  Reading then becomes refreshingly stimulating.  Of course, you can use this positive attitude to take full advantage of every opportunity for learning, in all modes of experience in all areas of life.  { This excerpt is from a section on CONCENTRATION in a website about Tools for Learning and Problem Solving. }

        citations
        Carl Bereiter & Marlene Scardamalia: 1989.  "Intentional Learning as a Goal of Instruction," in Knowing, Learning, and Instruction, edited by L. Resnick.  Hillsdale, New Jersey: Lawrence Erlbaum Associates.
        David Perkins & Gavriel Salomon: 1988.  "Teaching for Transfer," in Educational Leadership 46, pages 22-32.  The authors propose three basic

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