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Quantization part 2 –particles as waves ch 37. The world – a) matter - atoms nucleus of tightly packed protons and neutrons. Protons-positive charge electrons.

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Presentation on theme: "Quantization part 2 –particles as waves ch 37. The world – a) matter - atoms nucleus of tightly packed protons and neutrons. Protons-positive charge electrons."— Presentation transcript:

1 quantization part 2 –particles as waves ch 37

2 The world – a) matter - atoms nucleus of tightly packed protons and neutrons. Protons-positive charge electrons orbiting negative charge charges come in bits e=1.602 x 10 -19 C “quantized”

3 The World: Light We have a crazy new idea LIGHT IS A PARTICLE ….  These things are called photons h a constant – Plank’s constant h=6.625 x 10-34 J-s 1eV=1.602 x 10 -19 J

4 How is light made? absorbed? idea!

5 Trouble: Why discreet?? Emission spectrum Absorption spectrum Like a Merry go round that can only go 1mph, 3mph, 5mph and NOTHING IN BETWEEN

6 Why do we exist at all????

7 electrons are waves Crazy possibility #2 – Bohr: electrons are waves now take this in a circle here is what the book says (It doesn’t help me much) Think of a bugle

8 Bohr 1 electron as wave in a circle 2πr=nλelectron

9 Quantization of orbitals So only certain orbitals are OK, and NOTHING in between.  We require 2 πr=nλ electron (whatever λ electron is…)  States are stationary  For orbitals in between, the electron goes around and interferes destructively with itself. 2πr=nλ electron

10

11 Now lets see if we can figure out the energies of these orbitals Starting Stuff  Relativity  Einstein E=hf Waves c=f λ Mechanics  F=ma  circular motion _ E&M 2πr=nλ electron

12 But what is λ electron ??? back to light as particle  Relativity  mass of light?? mass of photon?? =0 p= h/ λλ=h/p  E=pc=hf=hc/ λ SO p= h/ λ or λ=h/p Now to electron as wave  λ electron =h/p electron

13 Now lets see if we can figure out the energies of these orbitals (Hydrogen) F=ma 2πr=nλ e from here we get L=mvr=nh/2 π the quantization of angular momentum here we get

14 quantization of the energy levels We get

15 The Rydberg constant and Bohr radius a B ~ size of atom ~10 -10 m

16 quantized energy, radius, velocity

17 What about the spectral lines? Emission spectrum Absorption spectrum Balmer forumla

18 Only photons with certain energies allowed! bohrbohr photons

19 Energy of the photons the Balmer formula

20 Some names for hydrogen m

21 Binding energy, ionization energy 13.6 eV 13.6/n 2 eV

22 The Davison Germer Experiment If electrons are really waves, they should diffract. The Davison Germer Experiment

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