No Prerequisites

20 Jun 2009
Description: 

All VIPEr learning objects are supposed to include clear student learning goals and a suggested way to assess the learning. This "five slides about" provides a brief introduction to the "Understanding by Design" or "backward design" approach to curriculum development and will help you develop your VIPEr learning object.

Prerequisites: 
Course Level: 
Corequisites: 
Learning Goals: 

Faculty will

  • understand the "backward design" concept
  • learn to write learning outcomes and assessments using the verbs ("activities") and "products" provided
  • learn how a rubric can be used to discriminate students' levels of achievement
Implementation Notes: 

These slides are a quick and dirty summary of a longer hands-on faculty development workshop I do. They provide an introduction to the Understanding by Design process, help in writing learning goals, suggestions for developing assessments of student learning, and helpful hints for preparing a VIPEr learning object.

Time Required: 
15 minutes to read the slides; a lifetime to practice the skill :)
Evaluation
Evaluation Methods: 

I hope that faculty will use these slides to aid their writing of learning goals and assessments for the VIPEr site.

22 Jan 2018

Streamlining Lab Report Grading: Errors Checklists

Submitted by Sabrina G. Sobel, Hofstra University
Evaluation Methods: 

Errors Checklists are most effective when you list the most common errors with explanations. You will see if you are successful if you use the items on the checklist repeatedly in your grading. Students will better understand their grades because of the clear communication of their errors. You should see a reduction of student inquiries as to why a certain grade was assigned on lab work.

Evaluation Results: 

My students really appreciate the errors checklists because my expectations and my grading choices are made clear. I have found that the formulation of Errors Checklists cause me to focus on and articulate the most common students errors; I subsequently pay more attention to the items in my pre-lab lectures, and student misunderstanding has decreased.

Description: 

I present a format for more effective communiction of errors in lab reports to students that I term Errors Checklists. Grading lab reports are one of the banes of our existence as professors. They are endless, unremitting papers that need to be scrutinized for accuracy, precision and understanding. Instead of tearing your hair out at the fifteenth report in which the student failed to use to proper number of significant figures, or failed to produce a readable graph, why not just breezily check a box on your Errors Checklist (in which you have provided a complete and thoughtful explanation), and staple to the student report?

I have created and used Errors Checklists for General Chemistry and Foundations of Inorganic Chemistry lab classes for almost two decades. I have passed them on to junior colleagues in my department, which they have modified to suit their needs. Errors Checklists lower my anxiety and anger when grading multiple lab reports, and provide clearer communication with students.

Corequisites: 
Prerequisites: 
Learning Goals: 

1. More effective communication of student errors on lab reports.

2. Streamline lab report grading to enable quick turnaround to students.

3. Better communicate expectations on lab reports to enable students to improve performance during the semester.

Topics Covered: 
Equipment needs: 

None.

Implementation Notes: 

You need to develop your own Errors Checklists customized for the experiments in your curriculum. A template is provided. I have included two example checklists; the first is for a Chemical Kinetics lab in which students determine the orders WRT iodide and peroxide for the iodine clock reaction. The second is for the synthesis of potassium alum from aluminum foil, with supplemental analysis of the unit cell (available online).

Time Required: 
not applicable
19 Dec 2017

Visual scaffold for stoichiometry

Submitted by Margaret Scheuermann, Western Washington University
Description: 

These five slides are intended to share a visual scaffolding that I developed to help my general chemistry students identify what calculations are needed to solve stoichiometry problems.

 

The visual scaffold involves writing the balanced equation and then under it drawing a table with two rows and enough columns so that there is one column under each reagent in the equation. The top row is labeled as "moles" and the bottom row is labeled as "measurable quantity". Students then write in any information about a specific reagent or product that was given and identify the quantity that the question is asking them to find. They then add a series of arrows to the table to generate a "map" of how to get from the information they are given to the information they need to find with each arrow representating a type of calculation that they have already seen and practiced. Vertical arrows represent a calculation between a measured quantity and a number of moles. Horizontal arrows in the top row represent calculations between moles of one substance and moles of another substance. Horziontal arrows in the "measured quantity" row are not allowed since those unit conversion factors are not readily available. 

 

Prerequisites: 
Subdiscipline: 
Corequisites: 
Learning Goals: 

A student should be able to determine the quantity of a reagent required or the quantity of a product produced in a reaction.

Course Level: 
Topics Covered: 
Related activities: 
Implementation Notes: 

The scaffolding begins with a review of the two types of calculations that are required for basic stoichiometry: converting between grams and moles, and converting between moles of one substance and moles of another substance using the coefficients of a balanced equation as unit conversion factors (slide 1).

Some ABCD card/clicker questions can be added here if students have not practiced these types of problems in class recently.

After introducing the visual scaffold (slide 2) I do an example problem or two on the board/overhead/doc cam (slide 3).

This is a good point to give students an opportunity to work on a practice problem or if the introduction to stoichiometry began part way through a class period, an exit question.

Next I introduce situations where it could take more than one calculation to get from the measured quantity to moles (slide 4). 

An example problem and/or practice problem and/or exit question can be added here.

The visual scaffold is also relevant for limiting reagent problems. I've included an example (slide 5/6) but limiting reagent is usually presented in a subsequent class period after some examples of the limiting reagent concept using sandwiches or something similar. 

Time Required: 
30-50 minutes. varies with the number of examples and practice problems
Evaluation
Evaluation Methods: 

I will usually do an exit question- a stoichiometry problem from the textbook- after either slide 3 or slide 4. I do not require students to use the visual scaffold if they are already comfortable with stoichiometry from a previous class but many choose to use it. Some students will include the tables from the visual scaffold as part of the work they show on exams, again without being prompted or required to do so. 

3 Jun 2017

Literature Discussion of "A stable compound of helium and sodium at high pressure"

Submitted by Katherine Nicole Crowder, University of Mary Washington
Evaluation Methods: 

Students could be evaluated based on their participation in the in-class discussion or on their submitted written answers to assigned questions.

Evaluation Results: 

This LO has not been used in a class at this point. Evaluation results will be uploaded as it is used (by Spring 2018 at the latest).

Description: 

This paper describes the synthesis of a stable compound of sodium and helium at very high pressures. The paper uses computational methods to predict likely compounds with helium, then describe a synthetic protocol to make the thermodynamically favored Na2He compound. The compound has a fluorite structure and is an electride with the delocalization of 2e- into the structure.

This paper would be appropriate after discussion of solid state structures and band theory.

The questions are divided into categories and have a wide range of levels.

Dong, X.; Oganov, A. R.; Goncharov, A. F.; Stavrou, E.; Lobanov, S.; Saleh, G.; Qian, G.-R.; Zhu, Q.; Gatti, C.; Deringer, V. L.; et al. A stable compound of helium and sodium at high pressure. Nature Chemistry 2017, 9 (5), 440–445 DOI: 10.1038/nchem.2716.

Corequisites: 
Learning Goals: 

After reading and discussing this paper, students will be able to

  • Describe the solid state structure of a novel compound using their knowledge of unit cells and ionic crystals
  • Apply band theory to a specific material
  • Describe how XRD is used to determine solid state structure
  • Describe the bonding in an electride structure
  • Apply periodic trends to compare/explain reactivity
Implementation Notes: 

The questions are divided into categories (comprehensive questions, atomic and molecular properties, solid state structure, electronic structure and other topics) that may or may not be appropriate for your class. To cover all of the questions, you will probably need at least two class periods. Adapt the assignment as you see fit.

CrystalMaker software can be used to visualize the compound. ICE model kits can also be used to build the compound using the template for a Heusler alloy.

Time Required: 
2 class periods
3 Jun 2017
Evaluation Methods: 

This LO was craeted at the pre-MARM 2017 ViPER workshop and has not been used in the classroom.  The authors will update the evaluation methods after it is used.

Description: 

This module offers students in an introductory chemistry or foundational inorganic course exposure to recent literature work. Students will apply their knowledge of VSEPR, acid-base theory, and thermodynamics to understand the effects of addition of ligands on the stabilities of resulting SiO2-containing complexes. Students will reference results of DFT calculations and gain a basic understanding of how DFT can be used to calculate stabilities of molecules.

 
Prerequisites: 
Corequisites: 
Course Level: 
Learning Goals: 

Students should be able to:

  1. Apply VSEPR to determine donor and acceptor orbitals of the ligands

  2. Identify lewis acids and lewis bases

  3. Elucidate energy relationships

  4. Explain how computational chemistry is beneficial to experimentalists

  5. Characterize bond strengths based on ligand donors

Implementation Notes: 

Students should have access to the paper and have read the first and second paragraphs of the paper. Students should also refer to scheme 2 and table 2.

 

This module could be either used as a homework assignment or in-class activity. This was created during the IONiC VIPEr workshop 2017 and has not yet been implemented.

 
Time Required: 
50 min
3 Jun 2017
Evaluation Methods: 

This was created during the IONiC VIPEr workshop 2017 and has not yet been implemented.

 
Description: 

This module offers students an introductory chemistry or foundational inorganic course exposure to recent literature work. Students will apply their knowledge of VSEPR and basic bonding to predict geometries of complex SiO2-containing structures. Students will gain a basic understanding of how crystallography is used to determine molecular structures and compare experimental crystallographic data to their predictions.

Prerequisites: 
Corequisites: 
Course Level: 
Learning Goals: 

Students will be able to:

  1. Describe the bonding in SiO2 and related compounds
  2. Apply bonding models to compare and contrast bond types
  3. Apply VSEPR to predict bond angles
  4. Utilize crystallographic data to evaluate structures
Implementation Notes: 

Students should have access to the paper and read the first and fourth paragraphs on the first page and the third paragraph on the second page. Students should also reference scheme 1 and figure 1.

 

This module could be either used as a homework assignment or in-class activity.

 
3 Jun 2017
Evaluation Methods: 

This learning object was created at the pre-MARM workshop in 2017 and as such has not been used in a classroom setting. The authors will update the learning object once they have used it in their classes.

Description: 

This module offers students in an introductory chemistry or foundational inorganic course exposure to recent literature. Students will apply their knowledge of Lewis dot structure theory and basic thermodynamics to compare and contrast bonding in SiO2 and CO2.

Corequisites: 
Learning Goals: 

Students should be able to:

  1. Describe the bonding in SiO2 and related compounds (CO2)

  2. Use Lewis dot structure theory to predict bond orders

  3. Apply bonding models to compare and contrast bond types and bond energies (sigma, pi)

  4. Characterize bond strengths based on ligand donors

Course Level: 
Prerequisites: 
Implementation Notes: 

Students should read the first paragraph of the paper prior to completing this learning object. They can be encouraged to read more of the paper, but the opening paragraph is the focus of this learning object.

Time Required: 
50 min
26 Mar 2017

Formulas and Nomenclature of Compounds

Submitted by Sarah Shaner, Southeast Missouri State University
Evaluation Methods: 

The activity was not graded. After students work through the problems in pairs, we come back together as a class and discuss any problems that caused the students trouble.

Description: 

Students will be given the formula for a cation or anion on a slip of paper or index card. He or she will find another student with an ion with the opposite charge and practice writing the formula and naming the ionic compound that would result by combining the cation and anion. Students also answer a few questions about naming and formulas of binary molecular compounds with their partner.

Learning Goals: 
  • Become better acquainted with their classmates and get used to working in groups.
  • Construct formulas for ionic compounds based on ion charges.
  • Practice naming ionic and molecular compounds based on their formulas.
Corequisites: 
Equipment needs: 

The instructor will need scissor and/or index cards to prepare the slips of paper or cards with ion names on them.

Subdiscipline: 
Prerequisites: 
Course Level: 
Topics Covered: 
Implementation Notes: 

I typically give cations to one half of the room and anions to the other half. This means that students must move around the room to find a suitable partner. Since this is early in the semester, this helps with getting students to talk and work with people in the class they may not know.

Time Required: 
About 20 minutes
3 Mar 2017

In-class peer review

Submitted by S. Chantal E. Stieber, Cal Poly Pomona
Evaluation Methods: 

Student participation was evaluated during the in-class portion based on the questions students asked. 

The formal peer review homework was evaluated based on completion, level of thought and thoroughness.

Evaluation Results: 

Overall, students were very interested in this topic and had not formally learned about the process before. There was a very lively discussion and a lot of questions were asked. All students received full credit for participation. 

Similarly, once students received their classmate's paper for peer review, they took the process very seriously and carefully went through the paper and answered the worksheet questions. 

I was very impressed by the high quality of the formal peer reviews that were turned in as homework. Students clearly spent a lot of time to carefully think about the paper and craft a reasonable response. Most students received full-credit. 

Description: 

This activity includes questions for students to answer to help guide them through the process of peer review. It was designed to assist students in writing peer reviews for research reports written by their classmates, but could be applied to literature articles as well.

Corequisites: 
Prerequisites: 
Learning Goals: 

A student will be able to:

-Explain how the peer-review process works

-Critically read through a research article

-Carefully review a research article

-Write a professional peer review

Implementation Notes: 

An overview of peer review was given with three powerpoint slides. Students then worked through a modified Q&A of the peer review module "Peer Review - How does it work?" posted by Michael Norris on VIPEr. This provided students with an example of real reviews, along with the resulting article revisions. 

The current worksheet was then passed out to students along with a research report written by one of their classmates (I assigned these and removed names). In class, students answered the questions on the worksheet and were able to ask questions of the editor (the instructor in this case). Following the in-class peer review, students had to write a formal peer review, which was turned in as homework. 

The peer review was a final component of a research report that students had been working on throughout the course. The final report was turned in after students had received the review comments back from their peers. The grade of the final report took into consideration whether or not students had made modifications based on comments by their peer reviewer.

 
Time Required: 
60 min
2 Mar 2017

Experimenting with Danger- CSB safety Video

Submitted by Sheila Smith, University of Michigan- Dearborn
Description: 

This 2011 video by the Chemical Safety Board is a very serious and moving motivation for adopting safe practices in the chemical laboratory.  It focuses on two recent and very real safety issues in University labs (UCLA, 2008 and TTU, 2010 ), both of which have shaken the educational research community to result in positive change. 

I have shared a "SafeShare" link so that you will not have to listen to ads, and if you choose to play the link in your classroom, you will not see all the Youtube ads on the screen.  

Learning Goals: 

Students will gain a real sense of the importance of chemical safety in the laboratory that is related to real people who have suffered real losses.  

Corequisites: 
Prerequisites: 
Implementation Notes: 

I will be using this video as part of my standard safety training during intake of new undergraduate researchers in my research lab and in the first week of Advanced lab.

I will also be working to get our general chemistry coordinator to adopt some or all of it as part of the lab safety training for freshmen.

Time Required: 
24 minutes

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