Lichen Storyline- AP Environment Unit 1

 Lichen Storyline Overview

Unit 1 AP Environmental Science CED- Living World- Ecosystems

Goals 

This storyline is designed to introduce the major concepts and themes of environmental science and engage students in a scientific investigation.  It walks them through the major skills of designing an experiment and serves as a formative assessment for educators to see how those skills need further instruction.  Many AP environmental science teachers have a unit 0 to introduce major themes of the course.  I have incorporated those themes I typically cover with my students into this storyline.

Why use storylines? 

Storylines are essentially a thematic study of a phenomenon students can question and observe.  The storyline covers many unit topics, essentially working through your content and skill standards within a unit but wraps them around sense making of the phenomenon.  The value in this form of teaching is that it:

• Walks students through a research pattern used in scientific study

• Engages students in scientific practices that align with AP environment’s CED and NGSS national science standards

• Encourages students to be curious and wonder about their environment; engaging them in science like they did in early education (something often lost in traditional methods!)

• Builds stronger understanding of how content connects and applies to each other; improving strength in understanding of systems of change

• Provides opportunity to introduce topics that will be covered in depth in future units, building background knowledge and optimizing the practice of a spiral curriculum to reinforce concepts year-long.

Elements of experimental design that are addressed:

• Forming a scientific question and identifying variables

• Methods of experimental design used in environmental science: lab investigation, field work, GIS information and tools including inaturalist, photometers

• Data collection and analysis- primarily percentages

• Experimental error: There are intentional limits to this experiment that I openly share with students to demonstrate that all experiments have errors.  Be explicit in the discussion of human error vs experimental design error and how field work has many confounding variables that will affect data.  How can we follow field work with more controlled experiments in the lab to isolate those variables?

• Working in collaboration with others to evaluate scientific experiments 

Why lichen?

The choice in using lichen is that it is an organism found in nearly all environments. Even if your school is in an urban area, you’d likely find some growing on undisturbed structures and trees.  Students also have experience seeing them but may not know what it is. This taps into their curiosity and sense making skills.  I found that even by the end of the school year after completing this unit, students still talked about lichen (and made many puns).  My group even made signs to hang in the classroom about it.  They love the topic and it's a great way to kick off the year with something interesting. 

CED standards: 

Not all unit 1 standards are covered in this storyline because I begin the use of ecocolumns directly following this lesson.  The early ecocolumn steps cover the remaining standards. In addition, the goal of storylines is to cover content that explains a phenomenon so you will see several standards that are covered from units later in the CED. The following standards are covered in this storyline:

• I can differentiate between habitats and niches. 

• I can predict how biotic and abiotic factors affect the growth patterns and niches of organisms. 

• I understand the impact humans have on natural systems within ecosystems, especially related to biogeochemical cycles. 

• I can describe symbiotic relationships between organisms and the advantages they provide. 

• I can use biological processes of photosynthesis and cellular respiration to describe primary productivity within a food web. 

• I can describe how competition drives the process of succession and how that will change the range of an organisms’ habitat. 

Student Lab Notebook

Share the student lab notebook or print it for students to complete as they move through the unit.

Storyline Planning Guide: 

My school runs on a hybrid blocked/standard schedule with a weekly zero hour component. This unit lasts approximately 11-12 class periods.

You can find a detailed teacher guide for purchase at my Teacher Pay Teachers Site (Moonier Science)

Lesson	Approximate Time Frame	Content standards	Skill standards
1.1 Tragedy of the commons fishing activity  Read “Honorable Harvest” Braiding Sweetgrass by Robin Kimmerer	30 minutes	5.1 Tragedy of the commons	7A Describe environmental problems.  7B Describe potential responses or approaches to environmental problems 3B Describe an author’s perspective
1.2 Thinking like an environmental scientist Watch HHMI Gorongosa Think like a Scientist Diagram environmental sustainable solutions Exit slip: Local issue diagram	45 minutes	5.12 Introduction to sustainability	7A and 7B problems and solutions 7F Justify a proposed solution by explaining potential advantages
1.3 Modeling trophic levels and species interactions HHMI Gorongosa (or local food web) food web and pyramid activity Carbon cycling lecture Exit slip: comfort zone probe	90 minutes	1.4 Carbon cycle 1.9 Trophic levels 1.10 Energy flow and the 10% rule 1.11 Food chains and food webs	2A Describe characteristics of a process visually 2B Explain relationships using models.
1.4 Phenomenon: Lichen nature hike and collection (lab notebook p 1-2)	45 minutes	1.1 Introduction to ecosystems 2.1 Introduction to biodiversity	4C Describe a research method 4D Make observations or collect data
1.5 symbiosis and primary productivity Show “Lichen in the city: short film” from Youtube Braiding Sweet grass- Read “Umbilicaria: The Belly Button of the World” Lab notebook p. 3	45 minutes	1.1 Introduction to ecosystems 1.8 Primary productivity	3C Describe an author’s reasoning use of evidence to support a claim 1A,C Describe environmental concepts and process. Explain them in applied contexts.
1.6 Microscope lab: lichen research (notebook p. 4-5)	30 minutes	1.1 Introduction to ecosystems	4D Make observations or collect data from the lab 5A Describe patterns or trends in data
1.7 Competition and succession Finish chapter in Braiding Sweetgrass (notebook p. 6) Lecture- succession and nitrogen cycling	30 minutes	2.7 Ecological Succession 1.5 Nitrogen cycle 7.2 Photochemical smog	2B Explain relationships between concepts visually 1C Explain environmental concepts and processes in applied context
1.8 Experimental design Introduce scientific questions and variables Show “Studying lichens (Harvard University)” youtube. Practice an FRQ 1 and self grade/revise answers	45 minutes	3.1 Generalist and specialist species	4A Identify a testable hypothesis or scientific question. 4B Identify a research method, design or measure used.
1.9 Plan your experiment Show youtube “Watching Lichen grow… scientifically” to model experimental design Introduce classroom tools; Groups of 3-4 plan experiment (notebook p. 7-10)	90 minute class period	1.8 Primary productivity	4A Identify a testable question 4B,C Identify and describe a research method, design and measure used
1.10 Experiment  Students perform their experiment; collect data	90 minutes	4D Make observations and collect data from the lab.
1.11 Analyzing data Practice calculating surface area, volume and percentages. Students analyze data.	45 minutes	5A Describe patterns or trends in data 5b Describe relationships among variables in data 5C Draw conclusions from patterns in data 6B Apply appropriate mathematical relationships to solve a problem 6C Calculate an accurate numeric answer with units(Calculating Surface area; %)
1.12 Create a group poster Groups evaluate model posters Create a group poster	90 minutes	3D Evaluate credibility of a source 3E Evaluate the validity of conclusions of a research study 5C Explain patterns and trends in data to draw conclusions 5D Interpret results in relation to a given hypothesis 5E Explain what the data implies or illustrates about an environmental issue
1.13 Science fair and evaluations (notebook p. 11-13)	45 minutes	3D Evaluate credibility of a source 3E Evaluate the validity of conclusions of a research study 4E Explain modifications to an experimental producer that will alter results

*This storyline can be implemented prior to or in conjunction with the ecocolumn build to complete all the standards for unit 1. The following unit 1 standards are not addressed in this storyline.  I’ve included how I cover them below:

• 1.2 Terrestrial biomes- You can discuss this briefly with them on the nature walk and when watching the videos throughout the storyline (each video features different types of terrestrial biomes).  I assign this section as flipped notes and self study with a short introductory lecture on biome patterns.  I quiz them on this section. I emphasize that they’ll receive practice with the biomes throughout the year and will see the climate patterns again in unit 4 Earth systems. 

• 1.3 Aquatic biomes- I assign this as a flipped note as well and actually quiz them on it in unit 2.  Unit 2 storyline is a pond study which lends itself to learning about aquatic ecosystems.  

• 1.6 Phosphorus cycle and 1.7 Hydrologic cycle- all the biogeochemical cycles are studied in depth during the ecocolumn build so I table those discussions for that activity. Both of these are also covered in depth in my Unit 2 storyline on pond water, during learning about eutrophication and surface runoff.

Assessment:

I often give students a couple of days to reflect and polish the lab notebooks before turning them in.  It gives them time to think and process the information or to catch up on sections they may have gotten behind on. I allow them to edit their posters after the science fair if they find significant errors.  For grading purposes, I grade lab notebooks based on completion.  I’ll usually pick some portions to spot check for content accuracy but typically, I’m more interested in their final product for close grading. I usually spend more time reading their self assessments and group posters (paying attention to the version history to assess individual students). 

I give a unit test that I build in AP classroom after covering the phosphorus and water cycles in the ecocolumn build (about 3 class periods after finishing lichen). I assign the multiple choice progress check for unit 1 one week prior to the assessment. Students must take the progress check before the morning of the test as a qualification for test corrections.  By completing the progress check and test corrections, I offer them a test curve of 10%.  A 10% curve encourages them to study because the curve is limited but is a large enough incentive for them to complete the self assessments which in turn improve their test taking skills and practice working with multiple choice. I save the FRQ progress checks for classroom practice. 

Ecocolumns

 

 Ecocolumns are an engaging and interactive way for students to conduct scientific practices over a long period of time.  I use ecocolumns as a first semester project to teach and reinforce concepts over many units of study in my AP environmental science course.  

I begin them two weeks into the semester to give students to become acquainted with the course and to gather supplies they'll need for the build.  Over the years I've learned a few things that help the columns function better and ways to work error into the project, leading students through problems they can solve that are connected directly to the course.  

This project is conducted all of first semester.  I start the build in unit 1 and end in Unit 5.  Usually we deconstruct our columns before winter break and then create the final poster when we return, since our semester ends in mid-January.

My students finish this project with a very strong understanding of:

• The nutrient cycles, especially nitrogen
• Concepts of eutrophication
• The relationship between cellular respiration and photosynthesis
• Soil properties and its relationship with the hydrologic cycle
• Water quality monitoring

I have modified my ecocolumn build from the work of Kristi Schertz at Teaching AP Science.  Changes were made based on my probeware, newly released CED guidelines and experience predicting issues with the columns.  As students experience issues, such as sedimentation in their aquatic columns, I use real time learning and teach them weathering, erosion, sedimentation and the effects of turbidity, for example. 

This activity begins with the building and monitoring of the ecocolumn and runs from unit 1-4 of AP environmental science CED.  During this time period, students complete journaling where they record data in a spreadsheet, make observations and reflect on the concepts the ecocolumn connects to.  During this period, I'll collect their notebooks at times when I feel appropriate and read their entries.  There is a lot of reading but I find it a valuable tool to see the depth of their learning.  Their answers to the prompts help me identify areas I need to cover in more depth and shows me the connections they are making to the class standards.  To reduce grading, you could collect one notebook per group and give a group grade.   

Ecocolumn Lab Notebook- Journaling and Reflection 

Ecocolumn Lab Note Guide

Here are some tips on how to run this portion of the ecocolumn experiment: 

• Give students time to gather supplies.  In the instructions, they mention using flat bottom bottles.  These are not readily available in my area so we use typical soda bottles.  Encourage students to choose thick plastics with flatter bases.  No green bottles.  If they bring a green bottle, they should only use it for the filtration (middle section). 
• My instructions use Vernier Probeware, LaMotte rapid test tabs and Rapitest soil testers.  There are many different types of tests on the market.  Use what makes sense for your budget and supplies on hand. 
• For several years I used guppies in the aquatic chamber.  Some years it was very successful but one year they all died.  We all felt terrible.  I made a switch, then, to aquatic snails.  You can order them through Carolina Biological supply for very low cost.  I keep an old aquarium in my room with duckweed, elodea and snails and its completely self sufficient with the exception of adding water now and again.  I haven't needed to order any since that first year since they grow so well. 
• I get basic pea gravel and topsoil for the terrestrial chambers.  Avoid fertilized soil as it'll create eutrophic conditions in your aquatic chamber.  It's interesting to see how the soil changes so much between groups based on their choices.  
• Use "mistakes" or problems students encounter as a class learning opportunity.  Many things will happen unexpectedly but they all fit in the curriculum! 
• Provide students with many different seed choices.  Some of the most interesting columns have a variety of grasses in them.  There are always groups that have no sprouting that occurs and I'll suggest they use mung beans at that point.  They sprout within 3 days in any soil and grow well. 

At the end of the semester (Unit 5) we'll dismantle our ecocolumns and analyze them.  This is a great opportunity to have students compare early soil structure to later soil structure and see the effects of erosion and plants on soil quality.  

Ecocolumn Final Analysis Lab Notebook

During this section of the project, we also look long term at the data.  Showing students how to find patterns in data and to think about how those patterns occur is very important.  At this portion of the project we discuss cause-effect and study major systems of change to see if our data fits those diagrams.  We also talk about scientific error and the difference between causation and correlation.  

The final portion is for each group to prepare a scientific poster and presentation.  The posters are modified from University templates and students create them collectively.  When they make them, I tell them to be sure to work on it while logged in on their google drives.  That way, I can see the group history and know who made each section of the poster. They are also responsible for explaining their poster sections during the presentations. 

Scientific poster template

To improve the quality of the posters, I always start with a group analysis of past posters.  Students use the scoring guide for the project and grade posters from previous years.  I give all groups two or three posters that look completely different.  This activity improves the quality of their outcomes in several ways- first it shows them models so they understand what to expect.  Second, by grading them, they can work with the scoring guide and know clearly what I'm looking for.  Third, each poster is unique to the column and the changes that occur. Many groups will develop envy over another's outcome.  By showing them how even a desolate ecocolumn has potential for an outstanding poster, they understand that all ecocolumns have their own personality and that they need to focus on what happened to theirs.

Example Ecocolumn Posters

I test at the end, giving a 25 point comprehensive quiz.  This is not shared here because I create it in AP classroom using AP exam questions that align to the topics in the ecocolumn.