Difference between revisions of "K-12 Outreach Introduction"

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<td style="text-align: center; width: 33%">[[Main_Page#K-12 Outreach Kits|K-12 Outreach Kits]]</td>
<td style="text-align: center; width: 33%">[[Main_Page#K-12 Outreach Kits and Labs|K-12 Outreach Kits and Labs]]</td>
<td style="text-align: right; width: 33%">[[Basic Optics - Outreach Kit|Next Topic]]</td>
<td style="text-align: right; width: 33%">[[Basic Optics - Outreach Kit|Next Topic]]</td>
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These kits are being assembled for loan to CMDITR members to enhance their outreach activities. Each kit contains materials for several demonstrations and in some cases hands-on materials that are suitable for various grade levels. There is one kit for one general interest area.  
These kits are being assembled for loan to CMDITR members to enhance their outreach activities. Each kit contains materials for several demonstrations and in some cases hands-on materials that are suitable for various grade levels. There is one kit for one general interest area.  
[http://depts.washington.edu/cmditr/media/Outreach_kits.docx Download complete manuals for 3 kits]


As a scientist who is deeply immersed in your research it is easy to overestimate the sophistication and content background of children. Even common events that you might consider everyday students may have not encountered. One of the reason of doing hands-on demos is to give students a shared concrete experience on which to build understanding and connections.
As a scientist who is deeply immersed in your research it is easy to overestimate the sophistication and content background of children. Even common events that you might consider everyday students may have not encountered. One of the reason of doing hands-on demos is to give students a shared concrete experience on which to build understanding and connections.


The table below suggests the topics that might be appropriate for each audience. Note: sometimes the materials in a kit might be quite impressive to kids even when the scientific explanation is inappropriate at lower levels. We assume you will be adjusting your presentation to make it fit the audience and venue. If you are wondering what is taught at various grade levels check the National Science Education Standards, AAAS Project 2061 and the link to Science standards for all states below.
The table below suggests the topics that might be appropriate for each audience. Note: sometimes the materials in a kit might be quite impressive to kids even when the scientific explanation is inappropriate at lower levels. We assume you will be adjusting your presentation to make it fit the audience and venue.


=== Outreach Kits Topic Matrix ===
=== Outreach Kits Topic Matrix ===
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!  High School Topics
!  High School Topics
|-
|-
|  Basic Optics and Lasers
[[Basic Optics - Outreach Kit]]
|  Light goes straight, Color mixing
|  Light goes straight, Color mixing
|  Lenses, optics, refraction, reflection, absorption
|  Lenses, optics, refraction, reflection, absorption
|  Polarization, Diffraction, emission spectra, dye sensitized solar cell
|  Polarization, Diffraction, emission spectra, dye sensitized solar cell
|-
|-
|  Photovoltaics
[[Photovoltaics- Outreach Kit]]
|  Solar car, Batteries
|  Solar car, Batteries
|  Angle /area dependence, Types of PV cells
|  Angle /area dependence, Types of PV cells
|  Total efficiency, measuring VC curves, color absorption
|  Total efficiency, measuring VC curves, color absorption
|-
|-
Light and Telecommunications
[[Lasers and Telecommunication- Outreach Kit]]
|  Optical fiber, water stream demo,
|  Optical fiber, water stream demo,
|  Total internal reflection, Tyndal effect
|  Total internal reflection, Tyndal effect
|  Polarization, Interferometer, Index of refraction, optical networks
|  Polarization, Interferometer, Index of refraction, optical networks
|-
|  [[Nanocrystalline - Dye Solar Cell Kit]]
|  Total efficiency, measuring VC curves, color absorption, oxidation-reduction,
|}
|}


=== The Kits ===
=== The Kits ===
Line 50: Line 57:
*[[Nanocrystalline - Dye Solar Cell Kit]]
*[[Nanocrystalline - Dye Solar Cell Kit]]
<br clear='all'>
<br clear='all'>
=== Assembling the Kits ===
#To build your own kits start by ordering the components listed at the end of the wiki for each kit. Most of the materials in the original kits are provided in quantities for a table top demo (1-2 copies). If you know that you are going to want to do a larger group where everyone needs a polarizing filter for example then order enough for a class. Be warned that that if you pass out something cool to everyone in a class you are probably not going to get them all back!
#Print the manual with a color printer and assemble with a 1 1/2" three ring binder with separators for each activity.
#Place materials for each activity in three ring, zip lock binder bags so they are organized with each activity. You may want to keep the additional product info and lessons that come with each component at the end of the binder.
#Keep all the materials and binder in a plastic snap case from Storables. The box needs to be 17"x13"x6".
[http://www.storables.com/Shop/Office/Hobby-Cases--Photo-Storage/?launch_pg=itemPage&launch_sel=1001905&launch_pg_sp=true&title=Large+Snap+Case Storables- Large Snap Case $7.95]


===Education Standards===
===Education Standards===
Science classroom time is packed full and teachers have many specific educational objective that are dictated by their districts and states. One key to being welcomed to the classroom is to relate your presentation to specific content they have to cover anyway. Even if your specific science is not covered you can switch the activity format to address general process skills such as observation, hypothesing, designing an experiment and interpreting results. Careers and the connect between science, technology and society are also hooks that tie into must curricula.
To learn what is taught at various grade levels check the National Science Education Standards, AAAS Project 2061 and the links to state Science below.
[http://www.nap.edu/openbook.php?record_id=4962&page=104 National Science Education Standards - Grade level Content]
[http://www.nap.edu/openbook.php?record_id=4962&page=104 National Science Education Standards - Grade level Content]


Line 63: Line 83:


=== More Hands On Demos and Activity Ideas ===
=== More Hands On Demos and Activity Ideas ===
*[http://depts.washington.edu/cmditr/media/Educ_demo_suppliers.docx List of suppliers for education kit materials]
[http://depts.washington.edu/cmditr/media/Educ_demo_suppliers.docx List of suppliers for education kit materials]


[http://www.hands-on-optics.org/resources/ HANDS ON OPTICS- (from OSA, SPIE and NOA0]
[http://www.hands-on-optics.org/resources/ HANDS ON OPTICS- (from OSA, SPIE and NOA0]
Line 82: Line 102:
   
   
[http://www.osa.org/educationresources/youtheducation/classroommaterials/default.aspx OSA classroom materials including the Optics Suitcase]
[http://www.osa.org/educationresources/youtheducation/classroommaterials/default.aspx OSA classroom materials including the Optics Suitcase]
[http://www.tryscience.org/experiments/experiments_home.html Try science demonstrations ]
'''Lab Interfacing'''
Using a computer to connect to measurement probes is very common in research. In demonstrations it gives you the chance to generated a data display on the fly while you are doing a demo to get students more engaged. Voltage, current, light and temperature probes are available and there are simple analog to digital converters that can plug into your USB interface.
[http://k8.vernier.com/products/interfaces/  Vernier Go!Link USB interface and voltage/current probe]
[http://store.pasco.com/pascostore/showdetl.cfm?did=9&partnumber=PS-2100A&detail=1 Pasco USBlink]
[http://sites.google.com/a/flosscience.com/probeware/Home/build-your-own Audacity Oscilloscope using sound card]
[http://depts.washington.edu/cmditr/media/voltmetercs3.swf Experimental Flash Voltmeter using microphone input- .5 volts or less]
Marcum-Dietrich, N.I. &amp; Ford, D.J. (2002). The Place for the Computer Is in the Laboratory: An Investigation of the Effect of Computer Probeware on Student Learning. Journal of Computers in Mathematics and Science Teaching. 21 (4), pp. 361-379. Norfolk, VA: AACE.


=== Resources for Informal Science Education ===
=== Resources for Informal Science Education ===
Line 87: Line 123:


[http://www.astc.org/ Association of Science and Technology Centers- Main clearinghouse for museum exhibit and demo technologies.]
[http://www.astc.org/ Association of Science and Technology Centers- Main clearinghouse for museum exhibit and demo technologies.]
{{author
|AuthorFullName= cmditr
|AuthorName=cmditradmin}}

Latest revision as of 09:29, 21 September 2010

K-12 Outreach Kits and Labs Next Topic

Outreach Overview

These kits are being assembled for loan to CMDITR members to enhance their outreach activities. Each kit contains materials for several demonstrations and in some cases hands-on materials that are suitable for various grade levels. There is one kit for one general interest area.

Download complete manuals for 3 kits

As a scientist who is deeply immersed in your research it is easy to overestimate the sophistication and content background of children. Even common events that you might consider everyday students may have not encountered. One of the reason of doing hands-on demos is to give students a shared concrete experience on which to build understanding and connections.

The table below suggests the topics that might be appropriate for each audience. Note: sometimes the materials in a kit might be quite impressive to kids even when the scientific explanation is inappropriate at lower levels. We assume you will be adjusting your presentation to make it fit the audience and venue.

Outreach Kits Topic Matrix

Kit Elementary Topics Middle School / Public Topics High School Topics
Basic Optics - Outreach Kit Light goes straight, Color mixing Lenses, optics, refraction, reflection, absorption Polarization, Diffraction, emission spectra, dye sensitized solar cell
Photovoltaics- Outreach Kit Solar car, Batteries Angle /area dependence, Types of PV cells Total efficiency, measuring VC curves, color absorption
Lasers and Telecommunication- Outreach Kit Optical fiber, water stream demo, Total internal reflection, Tyndal effect Polarization, Interferometer, Index of refraction, optical networks
Nanocrystalline - Dye Solar Cell Kit Total efficiency, measuring VC curves, color absorption, oxidation-reduction,

The Kits

AssembledCell small.JPG



Assembling the Kits

  1. To build your own kits start by ordering the components listed at the end of the wiki for each kit. Most of the materials in the original kits are provided in quantities for a table top demo (1-2 copies). If you know that you are going to want to do a larger group where everyone needs a polarizing filter for example then order enough for a class. Be warned that that if you pass out something cool to everyone in a class you are probably not going to get them all back!
  2. Print the manual with a color printer and assemble with a 1 1/2" three ring binder with separators for each activity.
  3. Place materials for each activity in three ring, zip lock binder bags so they are organized with each activity. You may want to keep the additional product info and lessons that come with each component at the end of the binder.
  4. Keep all the materials and binder in a plastic snap case from Storables. The box needs to be 17"x13"x6".

Storables- Large Snap Case $7.95

Education Standards

Science classroom time is packed full and teachers have many specific educational objective that are dictated by their districts and states. One key to being welcomed to the classroom is to relate your presentation to specific content they have to cover anyway. Even if your specific science is not covered you can switch the activity format to address general process skills such as observation, hypothesing, designing an experiment and interpreting results. Careers and the connect between science, technology and society are also hooks that tie into must curricula.

To learn what is taught at various grade levels check the National Science Education Standards, AAAS Project 2061 and the links to state Science below.

National Science Education Standards - Grade level Content

AAAS 2061 Benchmarks - The Physical Setting

Education World State Standards Links

McREL Content Knowledge

National Science Teachers Association- Science Scope and Coordination

More Hands On Demos and Activity Ideas

List of suppliers for education kit materials

HANDS ON OPTICS- (from OSA, SPIE and NOA0

APS Project Sol- Animation explains silicon solar solar cells

Solar Cell Kit-How to build your own solar cell

Innovative Methods to Teach Optics in the Grade 5- (including jello optics)

Exploratorium - Snacks are simple demo ideas - this is the premier organization for hands-on demos and learning

Institute for Chemical Education- Source for kits

Video labs in Nanotechnology from Univ. Wisconsin MRSEC

Rochester Optics demonstrations for Eday

OSA classroom materials including the Optics Suitcase

Try science demonstrations

Lab Interfacing

Using a computer to connect to measurement probes is very common in research. In demonstrations it gives you the chance to generated a data display on the fly while you are doing a demo to get students more engaged. Voltage, current, light and temperature probes are available and there are simple analog to digital converters that can plug into your USB interface.

Vernier Go!Link USB interface and voltage/current probe

Pasco USBlink

Audacity Oscilloscope using sound card

Experimental Flash Voltmeter using microphone input- .5 volts or less

Marcum-Dietrich, N.I. & Ford, D.J. (2002). The Place for the Computer Is in the Laboratory: An Investigation of the Effect of Computer Probeware on Student Learning. Journal of Computers in Mathematics and Science Teaching. 21 (4), pp. 361-379. Norfolk, VA: AACE.

Resources for Informal Science Education

Informal Science Education - Good resource to see what museums are doing with outreach activities.

Association of Science and Technology Centers- Main clearinghouse for museum exhibit and demo technologies.

The main author of this article is cmditr
Please note that others may also have edited the contents of this article.