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Scientific practices in the classroom

Scientific practices in the classroom. Katherine LeVan PhD Candidate Holway Invasion Ecology. “Science is an organized body of knowledge and a method of proceeding to an extension of this knowledge by hypothesis and experiment.” --Dr. Glenn Seaborg. A primer on the process of science.

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Scientific practices in the classroom

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  1. Scientific practices in the classroom Katherine LeVan PhD Candidate Holway Invasion Ecology

  2. “Science is an organized body of knowledge and a method of proceeding to an extension of this knowledge by hypothesis and experiment.” --Dr. Glenn Seaborg

  3. A primer on the process of science • Codifies reasoning that we all do everyday • Advantages include: • Removal of bias • Encourages multiple lines of evidence

  4. Read an article about something

  5. Read an article about something Ex: I found an article that says plants need nutrients like nitrogen, phosophorus and potassium to grow.

  6. LITERATURE I have an idea that…

  7. LITERATURE I have an idea that… Giving plants lots of nutrients will make them grow bigger, faster, have more fruit/flowers

  8. LITERATURE HYPOTHESIS P1 P2 P3

  9. LITERATURE HYPOTHESIS P1 Plants with more nitrogen added will be bigger P2 Plants with more nitrogen added will get larger, faster P3 Plants with more nitrogen added will make more fruit

  10. LITERATURE HYPOTHESIS P1 T1 P2 T2 P3 T3

  11. = Nitrogen added LITERATURE HYPOTHESIS P1 T1 P2 T2 P3 T3

  12. = Nitrogen added LITERATURE HYPOTHESIS Experimental Control P1 T1 P2 T2 P3 T3

  13. = Nitrogen added LITERATURE HYPOTHESIS P1 T1 Plant mass will be heavier P2 T2 P3 T3

  14. = Nitrogen added LITERATURE HYPOTHESIS Week 1 Week 2 P1 T1 P2 T2 Plants will grow faster P3 T3

  15. = Nitrogen added LITERATURE HYPOTHESIS P1 T1 P2 T2 17 beans 7 beans P3 T3 Plants will make more fruit

  16. LITERATURE HYPOTHESIS P1 T1 Statistics/Data analysis P2 T2 P3 T3

  17. LITERATURE HYPOTHESIS P1 T1 Statistics/Data analysis P2 T2 Is there a difference? Is that difference biologically important? P3 T3

  18. LITERATURE HYPOTHESIS P1 T1 Statistics/Data analysis WRITE A NEW ARTICLE P2 T2 P3 T3

  19. LITERATURE HYPOTHESIS P1 T1 Statistics/Data analysis WRITE A NEW ARTICLE P2 T2 P3 T3

  20. Science is self correcting • Science works because multiple groups are trying to uncover the same true phenomena

  21. Science is self correcting • Science works because multiple groups are trying to uncover the same true phenomena • If someone gets a weird result that isn’t right, other studies will show that it was a freak occurrence

  22. Science is self correcting • Science works because multiple groups are trying to uncover the same true phenomena • If someone gets a weird result that isn’t right, other studies will show that it was a freak occurrence • Different people approach the same question multiple ways • If multiple types of evidence point to the same conclusion, then we accept a fact as true

  23. Types of experiments • Manipulative experiments • See previous example • Control vs. treatment • Observational studies • Collect data on existing organisms • Problem: hard to attribute cause and effect

  24. Reproduction in plants Plants have a variety of strategies for reproducing. Annuals vs. Perennials

  25. Reproduction in plants Plants have a variety of strategies for reproducing. Annuals vs. Perennials

  26. Reproduction in plants Plants have a variety of strategies for reproducing. Annuals vs. Perennials

  27. Echinopsisgrusonii-Golden barrel cactus

  28. Data collection: methods • Determine size of cactus • Height, circumference • Count the number of flowers (active/senesced) • Count the number of bees visiting in 2 mins

  29. Let’s go into the field!

  30. Communicating science:writing a lab report • Intro • Tell us a little bit about the subject of interest • What was your hypothesis? Predictions?

  31. Communicating science:writing a lab report • Methods • What is the minimum amount of information someone needs to replicate what you did?

  32. Communicating science:writing a lab report • Methods • What is the minimum amount of information someone needs to replicate what you did? • “Ten cacti were surveyed”

  33. Communicating science:writing a lab report • Methods • What is the minimum amount of information someone needs to replicate what you did? • “Ten cacti were surveyed”

  34. Communicating science:writing a lab report • Methods • What is the minimum amount of information someone needs to replicate what you did? • “Four people measured each cactus”

  35. Communicating science:writing a lab report • Methods • What is the minimum amount of information someone needs to replicate what you did? • “Four people measured each cactus”

  36. Communicating science:writing a lab report • Results • What story do your data tell you? How will you plot the data? How will you label the axes?

  37. Communicating science:writing a lab report • Results • What story do your data tell you? How will you plot the data? How will you label the axes? Note: NEVER put ‘raw’ data into a lab report NEVER interpret your results in this section.

  38. Communicating science:writing a lab report • Discussion • What do the data mean in light of what you expected? What others have found? Interpret your findings and draw connections.

  39. Comparison of your data & mine By collecting data on reproduction in closely related species, we can find out how prevalent one strategy is over another

  40. Coast Barrel Cactus in San Diego

  41. Coast Barrel Cactus in San Diego

  42. Classroom applications • Science is about explaining “observed, measured, and predicted” phenomena (K+)

  43. Classroom applications • Science is about explaining “observed, measured, and predicted” phenomena (K+) • It’s not science until you share it! Via drawings/reports (K+)

  44. Classroom applications • Science is about explaining “observed, measured, and predicted” phenomena (K+) • It’s not science until you share it! Via drawings/reports (K+) • Represent data with bar graphs (1st+), scatterplots (3rd+), histograms (3rd+)

  45. Classroom applications • Science is about explaining “observed, measured, and predicted” phenomena (K+) • It’s not science until you share it! Via drawings/reports (K+) • Represent data with bar graphs (1st+), scatterplots (3rd+), histograms (3rd+) • Repeated sampling is important! (3rd+)

  46. Classroom applications • Conduct an observational (K+) or experimental study (4th+)

  47. Classroom applications • Conduct an observational (K+) or experimental study (4th+) • Introduce independent/dependent variables (5th)

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