Exploring Our Universe: From the Classrom to Outer Space
I. SPECTROSCOPY

This series of Educational Kits ``Exploring Our Universe: from The Classroom to Outer Space'', is being developed as an initiative of the FUSE (Far Ultraviolet Spectroscopic Explorer) Project's Public Outreach and Education program. The purpose of these education kits is to help secondary school students develop an understanding of how the content they are exposed to in science/math classes relates to the world in which they live, and how it applies to modern science and technology. This first kit, ``Spectroscopy: the study of light'' focuses on how astronomers study and use light to learn about the universe, its origin, its evolution, its fate. This puts basic concepts about light and the electromagnetic spectrum into a practical and exciting context, relating classroom activities to a NASA mission that will shortly be launched, and that will provide children the opportunity of following/sharing important exciting events.

One problem commonly encountered in school education is the disassociation of content material from real world applications, and the lack of enthousiasm that can derive from purely academical exercises. In this kit, students will see how the study of light and its properties link to the work of professional astronomers. Many exciting discoveries about the nature of the universe are unfolding on an almost daily basis, largely because of our ability to launch telescopes into orbits above most of the Earth's atmosphere. Astronomy is unique among the sciences in its ability to appeal to a wide audience. People of all ages and backgrounds are fascinated by what we have learned thus far about our place in the universe. Topics in astronomy can be used effectively as a "hook" to capture students' interest, and to communicate many basic scientific principles that have a wide range of applications. It is hoped that this kit, and others in this series, can be used as an effective tool toward this end.

An important event in this field will be the launch of FUSE- the Far Ultraviolet Spectroscopic Explorer satellite, in the spring of 1999. This mission will open a new region of the electromagnetic spectrum to intensive scientific scrutiny. Access to the far-ultraviolet range (which extends beyond the range accessible to the Hubble Space Telescope) will permit the study of many important atoms, ions and molecules existing in the Universe, unable to be investigated by any other means. The launching of a space telescope such as FUSE provides an excellent opportunity to generate enthusiasm for science in young people, and to direct this excitement toward their education.

This kit will help educators introduce basic principles concerning light and spectroscopy, and link them to the scientific objectives of the FUSE mission at levels appropriate to middle and high school science curricula. The fact sheet (background information) and the activities in this kit were developed to conform with the National Science Education Standards (National Academy Press, 1996) and the Benchmarks for Science Literacy (Oxford University Press, 1993). Both of these documents are invaluable resources for all who seek to raise science education in this country to levels of excellence.

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Each education kit of this series contains a fact sheet with background information, several classroom activities that can be incorporated into the physics science curriculum at both middle and high school levels, notes to the teachers for use of the material and correlation to the National Science Education Standards, a list of resources for expanding the topic, a glossary of useful terms, and an evaluation form that we urge you to complete and send back to us.

The topic of this first kit is about ``Spectroscopy''- the study of light- and includes: an introduction to the concept of electromagnetic spectrum (light at different wavelengths, visible and "non-visible" light), the technique of light analysis called spectroscopy, and some of its applications, with a focus on the FUSE mission in particular.

The activities in this kit have various degrees of difficulty, and require different materials from basic to more sophisticated. The activities do not need to be used in the exact sequence. They can be selected based on specific topics covered by the teacher during the unit on light, with consideration of available time and resources. Some of the activities are written as comprehensive lesson plans; others consist mainly of students worksheets, designed to supplement classroom discussions or to be given as home assignments. Several of the activities aim to enforce and develop scientific skills (such as unit conversion, scientific notation and problem solving using formulas) that facilitate the study of the electromagnetic spectrum and spectroscopy but also strenghten science skills in general.

Recommended Materials for Spectroscopy Activities:

Specific materials needed for each activity are specified in the Activity Sheet. A classroom set of hand-held diffraction gratings is strongly recommended for studying light; they are inexpensive and can be ordered from any science supply catalog (e.g. Flinn Scientific, 1-800-452-1261, or Edmund Scientific, 1-800-728-6999).

Other recommended materials include:

• Triangular prisms
• Spectrographs
• Various light sources:
  
  • Incandescent bulbs (continuous spectrum)
  • fluorescent tubes (coated tubes will yield a continuous spectrum)
  • "black light" tube (uncoated tube for a discrete spectrum)
  • spectrum tubes for different elements (discrete spectra)
  (Note: if the light source is a long thin tube or filament, you can avoid the need to put a slit in front of the source.)
• Color filters
• Slides with line emitting gaseous nebulae

The information and activities in the kit address the following content standards from the National Science Education Standards (National Academy Press, 1996), for Middle School and High School respectively.

Content Standard A:

As a result of activities in grades 5-8, all students should develop:

• Abilities necessary to do scientific inquiry
  
  • Identify questions that can be answered through scientific inquiry
  • Use appropriate tools and techniques to gather, analyze and interpret data
  • Communicate scientific procedures and explanations
  • Use mathematics in all aspects of scientific inquiry
• Understandings About Scientific Inquiry
  • Different kinds of questions suggest different kinds of scientific inquiry
  • Technology used to gather data enhances accuracy and allows scientists to analyze and quantify results of investigations

Content Standard B:

As a result of their activities in grades 5-8, all students should develop an understanding of:

• Properties and Changes of Properties in Matter
  • A substance has characteristic properties.
  • A mixture of substance often can be separated into the original substances using one or more of the characteristic properties
• Transfer of Energy
  • Energy is a property of many substances;
  • Energy is transferred in many ways
  • Light interacts with matter by transmission (including refraction), absorption, or scattering (including reflection) *The sun's energy arrives as light with a range of wavelengths, consisting of visible light, infrared and ultraviolet radiation

Content Standard G:

As a result of activities in grades 5-8, all students should develop understanding of [the] Nature of Science

• Scientists formulate and test their explanations of nature using observation, experiments, and theoretical and mathematical models
• In areas where active research is being pursued, it is normal for scientists to differ with one another about the interpretation of the evidence or theory being considered.

Content Standard A:

As a result of activities in grades 9-12, all students should develop:

• Abilities necessary to do scientific inquiry
  • Formulate and revise scientific explanations and models using logic and evidence
  • Communicate and defend a scientific argument
• Understandings about scientific inquiry
  • Scientists rely on technology to enhance the gathering and manipulation of data
  • Mathematics is essential in scientific inquiry

Content Standard B:

As a result of their activities in grades 9-12, all students should develop an understanding of:

• Motions and Forces
  • Laws of motion are used to calculate precisely the effects of forces on the motion of objects
  • Gravitation is a universal force that each mass exerts on any other mass
• Interaction of Energy and Matter
  • The energy of electromagnetic waves is carried in packets whose magnitude is inversely proportional to the wavelength
  • Each kind of atom or molecule can gain or lose energy only in particular discrete amounts and thus can absorb and emit light only at wavelengths corresponding to these amounts.
  • These wavelengths can be used to identify the substance

Content Standard D:

As a result of their activities in grades 9-12, all students should develop an understanding of:

• Origin and Evolution of the Universe
  • The "big bang" theory places the origin between 10 and 20 billion years ago
  • Stars produce energy from nuclear reactions. These and other processes in stars have led to the formation of all the elements

Content Standard G:

As a result of activities in grades 9-12, all students should develop understanding of

• [the] Nature of Scientific Knowledge
  • Because all scientific ideas depend on experimental and observational confirmation, all scientific knowledge is, in principle, subject to change as new evidence becomes available.

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