 Valence electrons  Electromagnetic Spectrum  Light characteristics  Electrons and Light.

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Presentation transcript:

 Valence electrons  Electromagnetic Spectrum  Light characteristics  Electrons and Light

 Fe – 1s 2 2s 2 2p 6 3s 2 3p 6 4s 2 3d 6 {2 valence e - }  Rb – 1s 2 2s 2 2p 6 3s 2 3p 6 4s 2 3d 10 4p 6 5s 1 {1 valence e - }  Cl – 1s 2 2s 2 2p 6 3s 2 3p 5 {7 valence e - }  These are the electrons that are involved in bonding and chemical reactions!!!!!!!

 When you add energy to an element (perhaps by heating it up), the valence e - get “excited”. In other words they jump up to a higher energy level or orbital.  BUT… they are unstable up there. So they release that added energy in the form of colored light!  Huh?

 Light moves in wave from the light source to you eye or other detector!  Waves have several characteristics!

Speed of light = wavelength × frequency speed of light = 300,000,000 meters/ sec. Since the speed of light is constant, then if wavelength increases, then frequency has to decrease!

 Moving along those waves, there are little packets of energy called photons. › Photons have specific amounts of energy as determined by the frequency of the light. › Energy= Planck’s constant × frequency › The higher the frequency of the light, the more energy the light has.

 When you add energy to an element, it’s valence e - absorb that packet of energy & become unstable. In order to return to stability (lower their energy) they “spit out” that energy in the form of a photon that has a frequency in the visible light part of the electromagnetic spectrum that we can see.

 Light Bunsen burner.  Take a soaked wooden splint from the bottle. (note the 1 st element in the solution.)  Hold splint in flame. Observe flame color and record.  Rinse splint in water.  Dispose of all used splints in trash. Turn off Bunsen burner.