Models in Science

Modeling Earth Science

     Students begin the lesson by first demonstrating the following vocabulary words, compression and tension.  It is important that students understand these two words before beginning the lesson.  I begin the lesson by having students roll up their play dough in a tube shape.  We first talk about the word compression.  To help the students remember this word, I tell the students to have their hands “come together and press”.  All of the students then practice compression with their play dough.  The next vocabulary word we demonstrate is tension.  The students roll the play dough in a tube.  Then we discuss the word tension.  Students then slowly put tension on their play dough and pull the play dough apart.  Once students understand these two concepts; we begin creating the faults.

Tension

compression

                                                                                                                                                                                            Students begin creating their models by making lay dough into the shape of a rectangle.  Students 

are working in groups of four.  The next step is to cut their play dough into a diagonal, using dental floss.  By cutting at a diagonal, the students are creating a footwall and a hanging wall.  The students then place their two diagonal pieces of play dough together.  We demonstrate what happens at a reverse fault that has compression.  The students slowly push their pieces together.  I tell the students to notice that their footwall looks like a sliding board.  The students then slowly slide their hanging wall up the foot wall.  Tillery, Enger, and Ross (2008) state that at a reverse fault, the hanging wall moves upward relative to the footwall.   We then describe what type of land formations could occur at this type of fault, such as mountains.  Students then draw their observations in their science journal.

     We then discus what happens at a fault with tension.  The students put their pieces together and slowly pull their pieces away.  I tell the students to relax their hands and look at what happens to the hanging wall. Tillery, Enger, and Ross (2008) state, that the hanging wall moves downward relative to the footwall at a normal fault.  Students then draw what they see at this type of boundary, such as faultblock mountains.

     Finally, the students mold their play dough into a rectangle again.  Instead of cutting at a diangle, student cut the play dough in half.  We then use these two pieces to discuss what happens at a strike slip fault.  Students then predict if this type of plate movement can create mountains.  Students draw what they see at this type of boundary.

Reverse Fault

Normal Fault

Normal Fault

Strike Slip Fault

    I feel the lesson was a success.  By using the model, students were able to visualize the faults and land formations that occur at the faults.  Perhaps, if larger pieces are used, students could visualize the landscape on a larger scale.  Braile (2000) also suggests using foam to create fault boundaries.  Braile (2000) states that foam models aid in visual understanding at plate boundaries since the models are three dimensional.  Play dough also serves as a three dimensional model, since foam can be expensive.  Students can also use the play dough to create large scale boundaries and add detail to their models.   Adding details like color for an ocean boundary or adding volcanoes and mountains to the model can increase student understanding.  Students can practice the different types of folds with their play dough,  such as anticline, syncline and monocline folds.

    Whether you use clay, paper, and foam or play dough, I feel models are an important part of the science classroom.  MacKay (2012) states that using models enhance student learning.  Models also allow students to visualize aspects of the world they may never see.  Models allow students to gain a boarder understanding of the topic and visualization of the model leaves a lasting impression on the students

     

 References

Braile, L.W. (2000). Teaching about plate tectonics using foam models.  Explorations in Earth Science.  Retrieved from http://web.ics.purdue,edu/~braile

Mackay, B. (2012). Teaching with models.  Retrieved from serc.carleton.edu/ntrogeo/models/index.html.

Tillery, B. W., Enger, E. D., & Ross, F. C. (2008). Integrated science (4th ed.). New York: McGraw-Hill.

Ask A Scientist

                                                             

  Can Diet Prevent Cancer?

I asked a scientist on the website, Ask A Scientist, if diet can prevent cancer.  Unfortunately, I have not heard from my scientist at this time.  However, there was information on the site that I found helpful in answering my question.  The article I read was, Vitamin D May be Crucial in Preventing Colon Cancer (Howard Hughes Medical Institute, 2012).  The article states that vitamin D helps to detoxify cancer causing chemicals that are released while eating high fat foods.  Vitamin D attacks the carcinogen and thus prevents colon cancer.  However, high amounts of vitamin D can cause and overload of calcium in the body.  therefore, scientist are trying to create a drug that activates this detoxification process, without causing calcemia.  

 I also searched on the Internet the answer to my question.  Researchers at the University of Iowa state that 1/3 of cancer deaths are related to diet and obesity(University of Iowa, 2012).  Researchers at the University of Iowa also state that high fiber has been found to reduce the risk of colon cancer.  Li(2012)  states that it is still not proven that a nutritious diet can prevent cancer.  However, Li(2012) reminds us that antioxidants shield cells from free radicals that damage the cell.  Therefore, eating foods that are high in antioxidants seem the best preventative measure to prevent cancer.  However, scientists and nutritionist will not say definitively that diet will prevent cancer.  They will say diet can lower the chances of  getting cancer, but never admit that diet will prevent cancer.  The reason for this is the number of people who follow a nutritious diet plan and who still contract cancer.  Maybe, the environmental factors are to blame.  My father-in-law is a prefect example.  This man ate more fruits and vegetables than anyone I know.  He also stayed aware from processed foods and preservatives.  However, he was a chemist.  He has been exposed to many toxic chemicals in his life.  In his sixties he devolved skin cancer, colon cancer and mesothelioma.  Mesothelioma is a cancer caused by exposure to asbestos. The mesothelioma eventually took his life.  He was a man that ate healthy every day of his life.  He exercised and did everything he was supposed to do.  However, cancer still took his life.  Will I continue to eat healthy? Yes    However, I will also be aware of the environmental factors that can cause cancer.  The chemicals we spray in our house each day.  The pesticides we spray on our crops.  The materials we choose to build with and decorate our homes.

References
Howard Hughes Medical Institute (2012). Ask a scientist.  Retrieved fromhttp://www.askascientist.org

Li, R. (2012). Can a nutrtious diet help prevent cancer?  Retrieved from http://www.fitday.com

University of Iowa Health Care(2012). Can your diet prevent cancer?  Retrieved from    http://www.unihealthcare.com

Presentation Tools

I have reviewed two presentation tools.  The following is a summary of each of the tools I selected.

The first presentation tool I reviewed is Prezentit.  I liked the looks of Prezentit right away.

What I liked most about Prezentit:

* The site is very user friendly. To add a new slide you just push the plus sign.

*Team members can work on the presentation simultaneously

* You do not have to have an Internet connection to download your presentation

What I did not like about Prezenit:

*The site is limited, no music or video capabilities

* I only saw ten fonts to use for presentations

The next presentation tool I reviewed is Animoto

*What I liked most about Animoto:

*The graphics are high quality

*You can upload music and videos

*You can download your presentation to a DVD, Facebook or email

*There is a video tutorial to help you create your video

What I did not like about Animoto:

*It cost 5 dollars a month or 30 dollars a year if you want to create a full

  Length video

*Free videos are only 30 seconds

Engaging in Guided Inquiry

Originally Posted on March 11, 2012

\

     I began my experiment by gathering my materials.  My materials are a toy car, ruler, 1 x 4 board, tin box and books.  My hypothesis was that the greater slope and mass would cause my tin box to move the furthest.   I set my books at a height of 20 and 35 cm to create the varying slopes.  I used quarters to add mass to my car.  I first completed each experiment with no added mass.  Then I added a quarter for each experiment.  I completed three trails each time I added mass.  I continued this when I increased the slope.  The results of my experiment are as follows:

20 cm height of slope	Trail 1	Trail 2	Trail 3
No mass added to car	3.5 cm	4.5 cm	4 cm
One quarter added	5.5 cm	6.cm	5 cm
Two quarters added	8cm	7.5 cm	7.5 cm
Three quarter added	8.5 cm	9 cm	8 cm

35 cm height of slope	Trail 1	Trail 2	Trail 3
No mass added to car	9 cm	9 cm	8.5 cm
One quarter added	11 cm	11.5 cm	12 cm
Two quarters added	12.5 cm	12 cm	13 cm
Three quarters added	14 cm	13.5 cm	13 cm

     The results of my experiment confirm my hypothesis that the increased slope and mass would cause the tin box to move the furthest.   Tillery, Enger & Ross (2008) states,  it takes longer to stop something, when it has more momentum.  The increase in the slope and mass caused the car to gain more momentum as it traveled down the slope.  The students in Ms. Blight’s class realized that momentum increases with mass.  However, from my observations, I found that slope has a greater effect than mass.  When the slope is increased in addition to the mass, the distance the tin box traveled was almost double.

     If I were to conduct this experiment in my class, I would have the students change the mass of the tin box I used in my experiment.  The mass of the tin box I used was slightly greater than my car even with the added quarters.  I would have the students choose an item with an equal mass and then a much greater mass.  The students could then further test Newton’s third law of motion, “whenever two object interact, the force exerted on one object is equal in strength and opposite in direction to the force exerted on the other object” (Tillery, Enger, & Ross, 2008).

     There are so many possibilities with this experiment.  The greatest lesson I learned from this inquiry is the importance of conducting inquiry lessons in the classroom.   Just reading Newton’s laws of motion and watching videos are not a substitute for hands on inquiry.  Inquiry lessons provide students the opportunity to move toward a deeper understanding of science (Branch & Bell, 2010).  Inquiry lessons answer questions and allow for discovery among students.  Long (2011) states that inquiry lessons allow students to take ownership for their problems they create, or the discoveries that they make. In other words, science without inquiry is not complete understanding.

References

Banchi, H., & Bell, R. (2008). The many levels of inquiry. Science & Children, 46(2), 26–29.

Laureate Education Inc. (Producer). (2012)  Newton’s Amusement Land: Race Track.  Retrieved from http://mym.cdn.laureate-media.com

Long, C.M. (2011). Designing inquiry oriented science lab activities.  Middle School Journal. Vol. 43, Issue 1, p. 6-15.

Teaching Thermodynamics in the 21st Century Classroom

Tillery, Enger, and Ross (2008) state that thermodynamics is the study of heat and its connection to mechanical energy.  This includes the study of heat engines and all types of energy transformation.  Teaching thermodynamics in a 21^st century classroom requires the use of technology, engineering, and cooperative groups.  However, incorporating current technology into the classroom can be difficult.  The use of technology like I pad, Skype and Facebook are not assessable in most classrooms.  Students spend most of their free time on ipads, twitter, Facebook and Skype.  However, schools are limited by the use of these 21^st century tools.  Currently the only technology at my school is an interactive whiteboard, computers and flip cameras.  My school does not even have wireless internet capabilities.  Therefore, implementing current 21^st century tools in a unit on thermodynamics can be challenging.

    I would use Flip cameras to record the student’s journey into the understanding of thermodynamics.   I found a great opening idea at ehow.com.  Peter (2011) suggests introducing thermodynamics by having students work in cooperative groups to see how energy is transferred in a rubber band.  The experiment requires rubber bands, an infrared thermometer, and a computer.  The students stretch the rubber bands in one minute intervals, each time taking the temperature of the rubber band.  The students could graph their temperature readings on a computer using excel or word.  Peter (2011) states that the students will understand how the work that is stretching the rubber bands is converted into heat.   This would be a great cooperative learning activity where students could help each other learn about thermodynamics.  They could record their experiment using the flip cameras.  This would allow the students to evaluate their participation and understanding of the experiment.  The flip cameras could also be used for peer evaluations of the experiment.

The next step would be to implement engineering into this unit of study.  I found two great activities where students could learn hands on about thermodynamics.  Students could first create a pop-pop boat ( http://www.ehow.com/how_12002602_make-poppop-boats.html).

 The construction of the boat can vary from simple to complex.  The students could work in cooperative groups to create their boats in a guided inquiry or open inquiry.   The students could also challenge each other by experimenting on how to increase the speed of their boat.  Cooperative groups could run trails and graph their information on the computer.  The students could then create a blog of their experiment.  The students could include step by step instructions on how to make the boat and include the results of their experiment on their blog.  The students could input pictures to help others re-create their boat.  I also found a good site where students could create their own steam engine (http://www.blm.gov/wo/st/en/res/Education_in_BLM/Learning_Landscapes/For_Teachers/science_and_children/steel_rails_and_iron/posterback.print.html).

 This engineering activity is a little more complex; however I feel that students would gain insightful knowledge on how a steam engine works.  If my school had the capability, I would use Skype for this activity.  The students could Skype to schools across the country. They could show the students how they made their boats and show how their boat works. They could then ask for suggestions and feedback on their experiment.

 Hopefully, one day schools will be caught up with the 21^st century technology that surrounds us.  Until then, using what is available at your school is better, than not using any technology at all.

References

Peter, M. (2011). Science projects in thermodynamics.  Retrieved from ehow.com

Newman, S. (2012). Full steam ahead-How to build a miniature steam engine.  Retrieved fromhttp://www.blm.gov/wo/st/en/res/Education_in_BLM/Learning_Landscapes/For_Teachers/science_and_children/steel_rails_and_iron/posterback.print.html.

Tillery, B. W., Enger, E. D., & Ross, F. C. (2008). Integrated science (4th ed.). New York: McGraw-Hill.

 Vossos, T.(2011). How to make pop-pop boats. Retrieved from http://www.ehow.com/how_12002602_make-poppop-boats.htm