Nuclear Fusion. STEREO Images of Extreme UV Radia6on at 1 Million C

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Darlene Thompson
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1 Nuclear Fusion STEREO Images of Extreme UV Radia6on at 1 Million C 1

2 Fusion vs. Fission Fission is the breaking apart of a nucleus what occurs during radioac6ve decay naturally occurring and happens in power plants 2

3 Fusion vs. Fission Fusion is the combining of two nuclei to form a heavier nucleus what occurs inside the core of the Sun the magic bullet for solving human energy problems or maybe not 3

4 Eddington s Sun: (1920s) Sir Arthur Eddington: Puts it all together. 1) Gravitational forces pressurize the center of the Sun. 2) Compression heats the interior (he thought to 40 million K). 3) Thermal collisions strip electrons from their nucleus, creating a plasma. 4) Free protons collide and stick to form helium nuclei. 5) The mass difference between H and He is converted to energy and released as light! There are problems with this idea: Protons are VERY hard to make fuse! Where does all the extra positive charge go???? 4

5 Overcoming the Impossible: There was still a problem though. The beginning of the process requires: p + p è D + e + The amount of thermal energy, even in the core of the Sun, is NOT enough to overcome repulsion between the two protons. How does it happen then? 5

6 Classical Mechanics vs. Quantum Mechanics Classical Picture: Think of the electron as a point par6cle. Electron moves towards the barrier. Electron bounces off of the barrier. This is NOT what happens quantum mechanically!!! 6

7 Classical Mechanics vs. Quantum Mechanics Quantum Picture: Think of the electron as a wave, which describe the probability an electron will be found at a given loca6on. Electron wave moves towards the barrier. probability wave Electron has large probability of not passing through the barrier. But it has a small probability of passing through the barrier Most of the 6me, the electron does not pass through the barrier. 7

8 Classical Mechanics vs. Quantum Mechanics Quantum Picture: Think of the electron as a wave, which describe the probability an electron will be found at a given loca6on. Electron wave moves towards the barrier. probability wave Electron has large probability of not passing through the barrier. But it has a small probability of passing through the barrier Quantum Tunneling: Occasionally the electron passes through the barrier. 8

9 A Numbers Game: How likely is it for two protons to combine in the core of the Sun? P + P è D + e + has ~1 chance in 4 x 10 16, each second! Your chances of winning the lottery are 40 BILLION times greater. Density in the solar core = 150 g/cm 3. So how does this happen? Mass of a proton = 1.7 x g. Proton density in core = 8 x p/cm 3. Thus there are ~ reactions/s-cm 3. 9

10 Hans Bethe: Hans Bethe (~1940): Developed a theory for the ways in which fusion (4H è He) could work in stars. What kind of fusion happened depended on how hot and dense the core is and how massive the star is. Very massive stars have one kind of fusion, called the CNO cycle (Weizsäcker), that involved `rare` elements (carbon, nitrogen, and oxygen). Less massive stars (like the Sun) are neither dense or hot enough for CNO fusion. Instead they fused He directly from H. He called this the Proton-Proton (P-P) chain. 10

11 Solar Fusion: The P-P Chain (p+n) Step 1: p + p D + e + + ν e e + + e - 2γ (neutrino) Reaction Rate = reactions/s-cm 3 ; once in every 1.4 x yr per pair of Ps 11

12 Solar Fusion: The P-P Chain Step 2: D + p 3 He + γ (p+n) (2p+n) Reaction Rate = occurs once every 0.6 s per D and P pair 12

13 Solar Fusion: The P-P Chain Step 3: 3 He + 3 He 4 He + 2P (2P+2n=alpha particle) Reaction Rate = once every 10 6 yr per 3 He pairs 13

14 The P- P Chain in the SUN Step 1: p + p D + e + + ν e (0.42 MeV) e + + e - 2γ (1.02 MeV) Step 2: D + p 3 He + γ (5.49 MeV) Step 3: 3 He + 3 He 4 He + 2p (12.86 MeV) Need two of Step 1 & 2 to have one of Step 3 Net: 4p + 2e - 4 He + 6γ + 2ν e (~ 26 MeV) (Where 1 MeV = 10 6 ev = 1.6 x J) (2*0.42MeV) + (2*1.02MeV) + (2*5.49MeV) + (1*12.86MeV) = MeV 14

15 The P- P Chain in the SUN 15

16 Fusion Energy on Earth The P-P chain is very hard to do on the Earth. Instead we can do: 1) D + D è T (1 MeV) + p (3 MeV) è He 3 (0.8 MeV) + n (2.5 MeV) split 50% - 50% 2) D + T è He 4 (3.5 MeV) + n (14 MeV) 3) D + He 3 è He 4 (3.7 MeV) + p (14.7 MeV) These three paths are not equal in usefulness 16

Path 3) produces the most energy, is the most efficient, and is

17 Fusion Energy on Earth Paths 1) and 2) produce fast neutrons that irradiate the containment vessel and reduce efficiency. Path 3) produces the most energy, is the most efficient, and is cleanest. There s a problem However: 3 He is not found on Earth! 17

18 Mining the Moon? The Apollo Missions found 3 He in the lunar soil. Estimates range up to 10 6 Tons of it. The energy content of 3 He is: Energy ( 3 He)= 2x10 8 kwh/kg The average person uses 250 kwh each month: 1 kg powers 10 5 people for a YEAR!! 1 kwh of Energy Costs about $ He is worth $600,000 an ounce! 10 6 Tons = 300,000 years of power!!! 18

19 Fusion Energy on Earth Lawson Criterion Plasma Density (n i ) Plasma Temperature (T i ) Energy Confinement Time (T E ) = Fusion Triple Product ITER: D + T hap:// 19

can move along field lines Electron B Posi6ve ion = Magne6c field into the

20 Plasma and Field Interac6ons Magne6c field cause moving charges to perpendicular to the field lines Charges are bound to magne6c fields Charges can move along field lines Electron B Posi6ve ion = Magne6c field into the page B Plasma is bound to the magne6c field. AND Magne6c fields are bound to the plasma. 20

21 Tokamaks 21

(ITER, NSTX, Alcator ) Stellerators Compact Torus (HIT- SI

22 Fusion Experiments: Magne6c Confinement Uses magne6c fields to confine hot plasmas Types of expt Tokamaks (ITER, NSTX, Alcator ) Stellerators Compact Torus (HIT- SI ) Innova6ve Confinement Concepts A lot of work s6ll needs to be done 22

23 Fusion Experiments: Iner6al Confinement Uses lasers to crush a full target very rapidly Types of facili6es: Solid State Lasers(NIF, NRL ) Gas Laser (NRL, PALS ) Lots of work here too 23

11/19/08. Gravitational equilibrium: The outward push of pressure balances the inward pull of gravity. Weight of upper layers compresses lower layers

11/19/08. Gravitational equilibrium: The outward push of pressure balances the inward pull of gravity. Weight of upper layers compresses lower layers Gravitational equilibrium: The outward push of pressure balances the inward pull of gravity Weight of upper layers compresses lower layers Gravitational equilibrium: Energy provided by fusion maintains