Slide1 : The ChemCollective Virtual Lab and Other Online Materials David Yaron, Michael Karabinos, Jordi Cuadros, Emma Rehm, William McCue, David H. Dennis, Donovan Lange, Rea Freeland Department of Chemistry, Carnegie Mellon University Gaea Leinhardt, Karen Evans Learning Research and Development Center, University of Pittsburgh
Materials : Materials Virtual lab
Mixed reception murder mystery
Online course in stoichiometry
Learning challenges and interventions : Learning challenges and interventions Promoting flexibility and applicability
From mathematical procedures to chemical phenomena (use in chemistry)
Virtual laboratory
From chemical phenomena to real world (transfer to real world)
Scenario based learning
Promoting coherence
“Big picture” of chemistry
Use in chemistry: Virtual laboratory : Use in chemistry: Virtual laboratory Flexible simulation of aqueous chemistry
New mode of interaction with chemical concepts
Ability to “see” inside a solution removes one level of indirection in chemical problem solving
Installing the Virtual Lab : Installing the Virtual Lab Ways to run the lab in your classroom
From www.chemcollective.org
From CD-ROM
Feel free to make copies of the CD yourself, or request packs from us
Install on your local computer system
Options for introducing the lab to your students : Options for introducing the lab to your students Demo the lab in class
Show how to pour
Show information available in the viewers
Show how to use the “load homework” menu item
Ask students to watch the brief video demonstrating how to use the lab
Ask students to do the step-by-step walkthrough
A basic user guide with instructions for using each feature of the lab is also available
A survey of Virtual lab problems : A survey of Virtual lab problems Current topic list
Molarity - Stoichiometry
Quantitative analysis - Chemical equilibrium
Solubility - Thermochemistry
Acids and bases
Problem types
Predict and check
Virtual experiment
Puzzle problems (open-ended and inquiry based experiments)
Layered problems
How to use in your classroom : How to use in your classroom During recitation
As take-home work
Pre- and post-labs
Lab make-ups
Supplement to in-class demonstrations
Predict and Check : Predict and Check Students use the virtual lab to check the results of a pencil-and-paper calculation or qualitative prediction
Potential benefits
Encourages students to see connection between calculations/qualitative predictions and an experimental procedure
Design of the appropriate experiment can be challenging
Observations indicate that the shift from paper and pencil to lab activity can be difficult for students
Students can make use of intermediate results in locating errors
Predict and Check : Predict and Check Traditional calculation
Thermochemistry/Coffee: Calculate the amount of 100C milk that must be added to 250ml of 95oC coffee to lower its temperature to 90oC. Check your answer in the virtual lab.
As part of design activity
Thermochemistry/Camping 3: Using the virtual lab, create two solutions, initially at 25°C, that, when mixed together in equal volumes, cause the temperature of the mixture to increase from 25°C to 60°C
Can be done as predict and check, but is often done in iterative process with some predict and check steps
Virtual Experiments : Virtual Experiments Students who could perform the textbook procedure had difficulty designing the experiment, and needed help from a human tutor.
The procedure is not triggered in response to relevant prompt
The Virtual Lab format prevents students from using strategy of matching words to equations
See also: http://iry.chem.cmu.edu/oldlab/ for unknown acid with feedback Typical textbook problem
“When 10ml of 1M A was mixed with 10ml of 1M B, the temperature went up by 10 degrees. What is the heat of the reaction between A and B?” Virtual Lab problem
Thermochemistry/Camping 1: “Construct an experiment to measure the heat of reaction between A and B?”
Students generate and interpret data in the chemistry virtual lab program
Puzzle Problems : Puzzle Problems Stoichiometry/Oracle 1 and 2: Given four substances A, B, C, and D that are known to react in some weird and mysterious way (an oracle relayed this information to you within a dream), design and perform virtual lab experiments to determine the reaction between these substances, including the stoichiometric coefficients. You will find 1.00M solutions of each of these chemical reagents in the stockroom.
Oracle Problem Observations : Oracle Problem Observations Intent was to give practice with determining reaction coefficients
A + 2B 3C + D
Observation
When A is mixed with B, some A remains, so the reaction must be: A + B C + D + A
Reveals misunderstanding of limiting reagent concept (even though they could easily perform textbook limiting reagent problems)
This may be a good opportunity for an Elicit-Confront-Resolve instructional strategy
Layered Problems : Layered Problems A set of activities involving the same chemical system, but modeling the system with varying levels of complexity and approximation.
The approximations can either be removed or invoked as one moves through a series of problems.
These interconnected layers, particularly with the addition of structured debriefing, invite students to reflect on how the removal or an addition of an assumption changes both their problem solving approach and the predicted results.
Layered Problems : Layered Problems Acid Mine Drainage Scenario treats river at three levels
As distilled water at room temperature
As distilled water with seasonally-varying temperature
As a buffered solution
For all three models, student discuss factors influencing amount of Fe precipitated in the river bed
See http://iry.chem.cmu.edu/AMD/
Authoring a virtual lab activity : Authoring a virtual lab activity Add chemical species and reactions (if desired)
Can create “fictional” proteins, drugs etc.
Create Stockroom Solutions
Specify available functionality
Viewers
For example, turn off “Solution Contents” for exercises involving unknowns
Transfer mode
Precise: student enters exact amount to transfer
Facilitates comparison with paper and pencil problems
Realistic: simulates accuracy attainable in real lab
Forces student to use correct apparatus (buret for titration)
Significant figures transfer mode
Teaches relation between experimental technique and accuracy
HTML problem description can be included
Transfer to real world: Scenarios : Transfer to real world: Scenarios Scenario based learning
Embed the procedural knowledge of the course in a scenario that highlights its utility
Scenarios that touch down at various points in the course may promote coherence
Traditional course structure : Traditional course structure CA state standards
Standard 1 Atomic and Molecular Structure
Standard 2 Chemical Bonds
Standard 3 Conservation of Matter and Stoichiometry
Standard 4 Gases and Their Properties
Standard 5 Acids and Bases
Standard 6 Solutions
Standard 7 Chemical Thermodynamics
Standard 8 Reaction Rates
Standard 9 Chemical Equilibrium
Standard 10 Organic Chemistry and Biochemistry
Standard 11 Nuclear Processes
Chemistry AP exam guide’s are similarly structured around chemistry topic list
Domain analysis : Domain analysis Evidence of the domain as practiced
Nobel prizes for past 50 years
NY Times Science Times for 2002
Scientific American News Bites for 2002
Evidence of the domain as taught
CA state content standards
Best selling textbooks
Domain map: The big picture : Domain map: The big picture EXPLAIN ANALYZE SYNTHESIZE Hypothesis
Generation Hypothesis
Testing Goal (What do you
want to know?) Process (How to determine
what you have) Functional
Motifs Structural
Motifs Assembly
Motifs TOOLBOX Representational
Systems Quantification
Systems
Comparison : Comparison Domain as practiced
Scientific literature spread equally between these three subdomains
Domain as taught
Textbooks and standards found only in Toolbox and Analyze subdomain
Full domain map : Full domain map
Domain map as basis for course design : Domain map as basis for course design Guide development of scenarios
Ensure distribution at both upper and lower levels
Mediate conversation between traditional and reformed course
Encourage students to reflect on how the course concepts fit into chemistry as a domain
Scenarios: Examples : Scenarios: Examples Mixed reception (molecular weight, stoichiometry)
Cyanine dyes binding to DNA (equilibrium, Beer’s law)
Meals read-to-eat (thermochemistry)
Mission to mars (redox, thermochemistry)
Arsenic poisoning of wells in Bangladesh (stoichiometry, titration, analytical spectroscopy)
Ozone destruction (kinetics)
Mixed Reception : Mixed Reception
Support for problem solving : Support for problem solving Based on hourglass view of problem solving Initial problem analysis
and selection of procedure Implementation of computation
or procedure Reflection on problem
Solving efforts
Pseudotutors : Pseudotutors Mock up of pseudotutor for creation of ICE table in equilibrium calculations. Student has entered the data in the boxes, and the system turned “+2x” red to indicate an error. Feedback on this error is provided if the student clicks the hint button. (May be extended to include making approximations on x for large and small K.)
Fading : Fading Determine target PH Determine target [A-]/[HA] Construct solution with target [A-]/[HA] F S Path 1 Path 2 Path 3 Schematic representation of scaffolding for the virtual lab activity: “Create a solution that will cause the side chain of a protein with pKa=8.2 to be 75% ionized”. Ovals represent episodes (pseudotutors or templated feedback) in support of specific goals or subgoals. Support is added/faded by switching paths. Determine solutions and volumes mixed.
Structured dialogues : Structured dialogues Initial problem analysis
Categorize information as given or requested
Drawing of diagrams that summarize problem statement and goals (ala Bodner)
Where does this problem lie in the domain
Explanation: Which of the conceptual frameworks do you think may help explain this phenomena?
Analysis: Are you being asked for a qualitative or quantitative analysis?
Synthesis: Which of the following processes do you think is most likely to work here?
Structured dialogues : Structured dialogues Debriefing dialogues
See the big picture
How does the current activity fits into the domain of chemistry?
Cluster knowledge
How is a particular problem like other problems you have done?
Distinguish knowledge
What is unique about this problem in term of technique, theory, principles, or circumstance?
Linked problems (such as layered problems)
Promote clustering and distinguishing knowledge
Stoichiometry review course : Stoichiometry review course Basic tools of stoichiometry
Significant figures
Unit conversions, including Avogadro’s number
Molecular weight/ molar mass
Composition stoichiometry
Solution concentration
Empirical formula
Reaction stoichiometry
Stoichiometric conversion and percent yield
Limiting reagents
Titration
Analysis of mixtures
Stoichiometry review course : Stoichiometry review course As in Bangladesh groundwater
Measurement of As concentration
Remediation
Challenges facing modern analytical chemistry
Stoichiometry review course : Stoichiometry review course Go to http://oli.web.cmu.edu
Click on “Need an account?”
Fill out the forms and hit continue
Opt in or out of the study
Register for the course by putting “stoichdemo” in for the course admit code
Next time, you only need to login in with your username and password to access the course
Middle school through high school: Big Concepts : Middle school through high school: Big Concepts Structure
Relation to properties
Functional group
Emergent properties (bonding pattern molecular interactions - 3 d structure)
Transformation
Physical transformations and chemical reactions
Energy and motion
Heat
Molecular motion
Built with styrofoam balls, magnets, and then put on a vibrating table
Water, gold and plastic
The ChemCollective : The ChemCollective Build community around a specific educational goal
Digital Libraries can combine expertise through remote and asynchronous collaboration
Digital Libraries can support an iterative development process
Ways to participate
Use activities and give feedback
Participate in assessment studies
Modify and create activities
Discussions around activities and topics
Student opinion data : Student opinion data Student surveys (data is % response)
Attitude towards virtual lab correlates strongly with confidence measures (R2=0.82)
Confidence does not correlate to performance (R2=0.01)
Assessment : Assessment Study at Carnegie Mellon
Second semester intro course, 150 students
Information used
Pretest
9 homework activities
3 hour exams
2 pop exams (practice exam given 5 days before hour exam)
Final exam
Correlations : Correlations
Structural equation model : Structural equation model PT EX1 H1 H2 H3 EX2 PEX2 PEX3 C-ACH
Pittsburgh Science of Learning Center (PSLC) : Pittsburgh Science of Learning Center (PSLC) Bring learning scientists and chemistry educators together
Goal is controlled studies in real classrooms
What is the best balance of worked examples and problem solving?
What is the correct level of feedback? How far down the garden path should you let them wander?
What role does dialogue play in student learning?
Actively soliciting instructors for studies in 2006
Current and Previous Team Members : Carnegie Mellon
Michael Karabinos
Jordi Cuadros
William McCue
David H. Dennis
Emma Rehm
Rea Freeland
Donovan Lange
D. Jeff Milton
Tim Palucka
Jef Guarent
Amani Ahmed
Giancarlo Dozzi
Katie Chang
Erin Fried
Jason Chalecki
Greg Hamlin
Brendt Thomas
Stephen Ulrich
Jason McKesson
Aaron Rockoff
Jon Sung
Jean Vettel
Rohith Ashok
Joshua Horan
LRDC, University of Pittsburgh
Gaea Leinhardt
Karen Evans
Baohui Zhang
Current and Previous Team Members
Fictitious chemicals : Fictitious chemicals Protein-drug binding
Add 3 species: Protein, Drug, Protein:Drug
Add reaction: Protein + Drug Protein:Drug
Thermodynamic properties
Protein + Drug Protein:Drug
DHfo 0 0 DH
S0 0 0 DS
Determine DH and DS from K at two different temperatures
Fictitious chemicals : Fictitious chemicals Add a new acid
Add 2 species: HA, A-
Add reaction: HA H+ + A-
Thermodynamic properties
HA H+ + A-
DHfo DH (H+) DH (H+) DH
S0 So (H+) So (H+) DS
Determine DH and DS from K at two different temperatures
We also have a “Chemical Database Management System” that will generate thermodynamic data from a list of K’s etc.