peter paul 02/24/05phy313-cei544 spring-051 phy313 - cei544 the mystery of matter from quarks to the...
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Peter Paul 02/24/05
PHY313-CEI544 Spring-05 1
PHY313 - CEI544The Mystery of Matter
From Quarks to the CosmosSpring 2005
Peter Paul
Office Physics D-143
www.physics.sunysb.edu PHY313
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What have we learned last time I• We studied the nucleus. It is made up of a
dense package of neutrons and protons, i.e. nucleons. The protons produce the positive charge Z that identifies the element, the N neutrons add to the mass number A = N+Z.
• Nucleons interact by the strong force, which is ~ 100 time stronger than the electromag-netic (EM) force. It has a range of only ~ 1 fm, about the same as the size of a nucleon.
• Yukawa invented the concept of the force being mediated by the exchange of specific particles, in this case pi mesons. These exchange particles are created out of nothing, as virtual particles that live for a time given by the Heisenberg Uncertainty Relation
• The nuclei derive their binding from the combined effect of all the nucleons inside the nucleus.
• The nucleons are packed together like water molecules in a liquid drop. Thus the volume (size) of the nucleus increases linearly with the number of nucleons, A, and the radius goes like the cube root of A:
• The binding energy increases as we add more nucleons, to a peak of 8.8 MeV/nucleon at the Fe (Iron) nucleus. As we add more protons the Coulomb repulsion between protons diminishes the binding of heavier nuclei.
• In nuclei past Pb (lead) the large Coulomb energy makes the nuclei prone to fission. After Thorium nuclei are not stable anymore.
2// cmEt
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What have we learned last time II• Nuclei can transform themselves
spontaneously by radioactive decay. Beta decay is the emission of a negative or positive electron and a neutrino. It changes a neutron into a proton or vice versa. It is mediated by the weak interaction and thus the half lives are quite long.
• Radioactive decay can be used for radioactive dating, by comparing the intensity left over after a given time to that predicted by the half life of the isotope.
• Positron emitters can be used for PET scanning of isotope distribution inside a human/animal body.
• To produce new isotopes or new elements one uses the fusion reaction. In this reaction two nuclei can be fused together, if they have sufficient energy to overcome their mutual Coulomb repulsion. This normally requires an accelerator.
• Neutrons, because they are not charged, can fuse with a nucleus at very low energy.
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The Nucleus as Energy Source: Fission
• It was already realized before WW-II that the fission process can provide a huge source of energy.
• This energy is obtained without fossil fuel combustion. It does not produce CO2 which is the source for global warming.
• The challenges were at first considered technical: Produce a controlled fission reaction, in a safe vessel that contains all radioactivity. Then find a a way to deposit and safeguard the radioactive waste that has life times of tens of thousands of years.
• Soon, however, the challenges were more a matter of public acceptance and policy.
First electricity producing reactor At INEEL in the U.S. 1951
Modern nuclear reactors
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The fission process
• The fission process for 235U:
• This process releases 173 MeV directly, and overall about 202 MeV, per reaction.
• It also produces 3 neutrons for each one that it used.
• More precisely, the neutron excess for different nuclei is
235U 2.432 new neutrons239Pu 2.874 new neutrons
• These numbers are crucial for the production of a chain reaction.
nKrBaUUn 38936
14456
*23692
235
• http://lectureonline.cl.msu.edu/~mmp/applist/chain/chain.htm
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Neutron cross sections
• Cross section area is a pictorial expression for the probability of a projectile interacting with a target nucleus.
• A Boron nucleus has a size RB~ 2.6 fm and a nucleon has a radius Rn ~ 1.2 fm
Thus we expect A ~ (RB+Rn)2 =
14 x10-26 cm2 = 0.14 bn• A cross section area of = 10-24 cm2 is
called a barn (bn) because it is as easy for neutrons to hit as a barn door.
• In fact Boron has a neutron capture cross section at 0.1 eV of 3,800 bn = 35,000 times what one expects: Why??
• It follows from the wave nature of the neutron that is important at low energies.
• If we take about Rn ~ the cross section can be A = 2400 bn
fmEmc
MeVfm
n
4
21028
2
1240
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Neutron reactions
• Neutron scattering as a function of neutron energy
• Neutron capture shows distinct resonances where the n is captures into excited nuclear states.
MeVCnCn
CnCn
4.4' 1212
1212
fissionUUn 236235
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Multiplication factor for chain reactions
• Neutron multiplication factor
• If k =1 chain reaction is critical• If k< 1 chain reaction is sub critical• If k> 1 chain reaction is supercritical• Explanation of factors in the equation: = number of fission neutrons of any
energy per initial thermal neutron absorbed in the fuel
• f = fraction of thermal secondary neutrons absorbed in the fuel
• p = number of neutrons that escape from being thermalized
= fast fission enhancement factor • PL = neutron loss factor from volume
• These values are for pure isotopes. For natural uranium the 235U fraction is 0.72%; “weapons grade” uranium, the235U is enriched to at least 3%
• Typical values for a 3% enriched thermal-neutron reactor:
= 1.65
f = 0.71
P = 0.87
= 1.02
PL = 0.96
• The values produce k = 1
• For a chain reaction to build up k must be > 1.
http://lectureonline.cl.msu.edu/~mmp/applist/chain/chain.htm.
LPpfk
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Neutron Moderation
• In the fission process neutrons are emitted with energies between 1 and 2 Me. They must be “moderated” down to thermal energies
• This is done in elastic collisions with so-called moderator material that surrounds the Uranium.
• The energy loss = final average neutron energy/ initial neutron energy
• The lighter the scattering material is the more energy the light neutron is losing in the collision:
= 0.5 for hydrogen, 0.86 for Carbon, 0.99 for Uranium
• Thus light (H2O) and heavy (D2O) water are the best moderators. However, because of its propensity to absorb neutrons light water is not very good, D2O is in effect 100 time better, Graphite is next.
• Light and heavy water can also be used as a coolant, but not graphite.
• BNL heavy water- moderated HFBR research reactor:
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Plutonium Breeding, Xenon Poisoning & Control Material
• n-capture on 238U can breed 239Pu, which is an even better fission energy source than 235U.
• Thus reactors produce their own fuel while they produce energy.
• Materials that absorb neutrons very effectively act either as poisons –stopping the reactor, or as control elements-keeping the power of the chain reaction in check
http://library.thinkquest.org/17940/texts/java/Reaction.html
• Xenon-135 was an early poison that almost stopped the Pu production at the Hanford reactors in 11943 ~ 7 hours after its start. 135 Xe has a cross section of 2.65 barns for slow neutrons.
• Good control materials are 10B (cross section 3800 bn) and 113 Cd (20,000 bn). These materials serve in control rods that are inserted into or withdrawn from the core to absorb more or fewer neutrons.
PuUUn decay 239239238
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Light-water reactors
• The most widely used reactor types use water for cooling of the reactor core during the fission reaction.
• The water is either boiling or under pressure.
• In the BWR the steam
heated in the reactor core
directly drives the steam
turbine which produces the
Electricity.
• A typical reactor generates
about 1000 MW of electricity.
http://www.ida.liu.se/~her/npp/demo.html
http://www.eia.doe.gov/cneaf/nuclear/page/at_a_glance/reactors/states.html
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The core of the reactor is an engineering marvel
• But it is not physically complicated. It has few moving parts, mainly the control rods.
• They cannot ever be allowed to get stuck in the pulled-out position or the reactor could not be controlled
• The most critical parts are the cooling water pumps. If the cooling water stops the reactor will overheat and the fuel rods can melt.
• Automatic safety precautions as fallbacks are incorporated into the reactor design, but these have not always been effective
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Some facts about the fuel cycle
• Typically a reactor has about 280 fuel rods in a bundle. Typically fuel rods are changed when they become “poisoned” and replaced with new ones. The spent fuel can be re-processed and Pu can be extracted.
• A modern reactor has a thermal efficiency for the production of electricity of ~32%. Thus a 1000 MWe reactor needs to produce 3100 MW of heat.
• Uranium provides “burn-up” energy of ~ 40 GWd/ton at 3.75% enrichment
• 1 GWe-year requires 1.2 tons of 235U, or 32 tons of total Uranium (3.75% enrichment)
• Fuel is changes about 3 tomes/year
• This requires ~ 200 tons of natural uranium. Present world demand for Uranium is ~ 60,000 tons/years, corresponding to a power production of 300 GW-years. The price of ~$260/kg or $260,000/ton.
• Spent fuel can be re-processed, with 99.8% extraction of Uranium and Pu.
• The remainder needs to be stored somewhere to cool down thermally and in terms of radiation.
Yukka Mountain
Repository
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Nuclear Reactors in the world
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Global warming
• production from burning fossil Energy fuels produces CO2 which slowly accumulates in the upper atmosphere.
• CO2 transmits the sun‘s radiation to earth but absorbs the heat radiation emitted from earth and reflects it back. This leads to global warming.
• The emssion of CO2 could be significantly reduced by use of nucler enrgy production.
• Global warming has
happened before in the
Earth‘s history, but leads
to serious climate
changes
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The Three-Mile Island Accident
• 3MI reactor unit 2 (~800 MW) had a serious accident on March 28, 1979 when the main cooling water pumps stopped working. The reactor fuel overheated and melted.
• Although the containment vessel was not breached the publics faith in nuclear power was badly shaken.
• The cause of the accident was human error, design deficiencies and component failures.
• Today the 3MI-II reactor is defueled and decommis-sioned.
• Total cost of accident ~ $1 Billion
• Time line: March 1979: Accident happenedJuly 1980: 43,000 Ci of Krypton vented July 1980: First human entry into
reactor buildingOct 1985: Defueling begunJan 1990: Defueling completedApril 1991: Evaporation of 2.23
Million g of contaminated water begins
August 1993: Water removal completed
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Some commercial power statistics
Source World (2001) US(2002)
Fossil 346 86% 83.8 86%
Renewable 30 7.4% 5.8 6%
Nuclear 26 6.5% 8.1 8.3%
Total 397 100% 98 100%
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World Growth of Nuclear Power
Gross generation (GWyr)
World Western Europe
Asia US France Japan
1973 22 8.4 1.4 10 1.7 1.1
1980 71 24 11 30 7.0 9.5
1990 202 84 32 69 36 22
2000 260 102 57 89 47 37
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Next-Generation Reactors• The U.S. Government is beginning a
program to design the next generation nuclear reactors: Generation-IV program.
• This program is studying 6 reactor concepts with the goal of having designs ready for construction by 2030.
• It has dedicated the Idaho National Laboratory to this reactor development.
• The Japanese are also developing advanced concepts: The Reduced Moderation Light water Reactor: This reactor type leaves more energetic neutrons in the core that “burn away” heavy radioactive isotopes
• In addition there is development of Thorium fueled reactors which do not produce Pu and are thus proliferation-proof.
• Gas-Cooled Fast Reactor (GFR)features a fast-neutron-spectrum, helium-cooled reactor and closed fuel cycleINEEL contact: Kevan Weaver, [email protected]
• Very-High-Temperature Reactor (VHTR)a graphite-moderated, helium-cooled reactor with a once-through uranium fuel cycleINEEL contact: Finis Southworth, [email protected]
• Supercritical-Water-Cooled Reactor (SCWR)a high-temperature, high-pressure water-wooled reactor that operates above the thermodynamic critical point of waterINEEL contact: Jacopo Buongiorno, [email protected]
• Sodium-Cooled Fast Reactor (SFR)features a fast-spectrum, sodium-cooled reactor and closed fuel cycle for efficient management of actinides and conversion of fertile uraniumINEEL contact: John Ryskamp, [email protected]
• Lead-Cooled Fast Reactor (LFR)features a fast-soectrum lead of lead/bismuth eutectic liquid metal-cooled reactor and a closed fuel cycle for efficient conversion of fertile uranium and management of actinidesINEEL contact: Kevan Weaver, [email protected]
• Molten Salt Reactor (MSR)produces fission power in a circulating molten salt fuel mixture with an epithermal-spectrum reactor and a full actinide recycle fuel cycle
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Reduced-Moderation Water Reactor (RMWR)• As a candidate of advanced light-water reactors, JAERI is now
developing RMWR.• RMWR has a possibility of a high conversion ratio of more
than 1.0.• Gap spacing between each fuel rod is required to be only about
1 mm. • To attain the gap spacing of 1 mm, a tight-lattice core with
triangular fuel rod arrangement can be needed. This requires very precise computer modeling
separator
drier
core
control rod seed fuel blanket fuel
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Nuclear weapons
• For a bomb the neutrons are not very well contained; in addition one needs a rapid build-up of the chain reaction, before the material flies apart.
• For a nuclear bomb the uranium is highly enriched in 235U, between 60% and 90%.
• The minimum Uranium requirement is between 10 and 25 kg. For Pu bomb the minimum requirement is ~5 kg.
• If these “critical” amounts of material are in close proximity the nuclear reaction will explode.
• Two types of assembly:
1.The gun-type where an explosive charge drives a sub-critical mass into a second sub-critical mass at high speed.
2.A compression type where a spherical charge compresses the nuclear fuel from a low density to a high density where it becomes critical.
LPpfk
Uranium fuel
Pu fuel
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Some archive pictures
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Energy from Fusion in the Sun
HeHH 312
HHHeHeHe 11433
eHHH 211 eHHH 211
ee ee
HeHH 312
4 1H + 2 e- 4He +2 n + 6 + 26.7 MeV energy per reaction at ~ 100 Million K temperature
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Fusion energy in the Laboratory
• The best fusion reaction is d + t +n with an energy output of 17.6 MeV.
• D and T present the lowest Coulomb barrier to fusion, and thus the lowest temperature. But it requires ~ the temperature at the core of the sun, ~100 Million degrees. At this Temperature the electrons separate from the nuclei: a Plasma
http://www.jet.efda.org/
• In a thermonuclear bomb (hydrogen bomb, this temperature is produced through a fission explosion which then detonates the fusion reaction.
• For steady state operation the material needs to be held in a magnetic bottle
• Both the ions and
the electrons in the
plasma can be held
by magnetic fields.
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Advantages and disadvantages of Fusion
• Deuterium is available from sea water, about 10x 1012 tons. Tritium can be produced from Li through the reaction:
• Sea water contains thousands of years supply of Li.
• No long-lives radioactive material is created”: Tritium half life =32 years
• Fusion reactors could be continuously loaded: no poisoning of fuel.
• Fuel consumption extremely low because of huge energy production per kg of fuel.
TLin 7
Disadvantage: The complexity of plasma confinement and heating has held back development for 40 years!
http://fire.pppl.gov/fire_program.htm
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10 - 20 keVIs optimum
~ (plasma pressure)2 Need 10 atmospheres @ 10 keV
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Confinement of plasma particles by magnetic fields
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Toroidal Magnetic Confinement
Charged particles have helical orbits in a magnetic field; they describe circular orbits perpendicular to the field with gyro-radius rl=v/Ω, where Ω=qB/mc
“TOKAMAK”
(Russian abbreviation for “toroidal chamber” with magnetic fields); includes an induced toroidal plasma current to form, heat and confine the plasma
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Product of fuel density, plasma lifetime and temperature is the “figure of merit”.
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As the step to ignition ITER ready to be build
Toroidal Field CoilNb3Sn, 18 coils
Poloidal Field CoilNb-Ti, 6 coils
Central SolenoidNb3Sn, 6 modules
Blanket Module421 modules
Vacuum Vessel9 sectors
Cryostat24 m high x 28 m dia.
Port Plug6 heating3 test blankets2 limitersrem. diagnostics
Divertor54 cassettes
500 MW of power in the plasma, plasma volume 840m3
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Quarks
Cosmic Timeline for the Big BangCosmic Timeline for the Big BangCosmic Timeline for the Big BangCosmic Timeline for the Big Bang
proton, neutronsdeuterons
He nuclei( particles)
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How are the light elements produced in stars
• Three minutes after the Big Bang the universe consisted of
75% Hydrogen,
25% 4He
less than 0.01% of D, 3He and 7Li.
• The sun began to burn the available H into additional 4He, as we learned and heated itself up.
• Once there was sufficient 4He available the reaction 4He + 4He+ 4He 12 C + 8 MeV
became efficient. It heated the sun up still further
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Energy from Fusion in the Sun
HeHH 312
HHHeHeHe 11433
eHHH 211 eHHH 211
ee ee
HeHH 312
4 1H + 2 e- 4He +2 n + 6 + 26.7 MeV energy per reaction at ~ 100 Million K temperature
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From Helium to Carbon
• When the start has used up its hydrogen, the refraction stops and the star cools and contracts. If the star is heavy enough the contraction will produce enough heat near the core where the 4He has accumulated to start helium burning.
• Because of gravity the heavier elements always accumulate in the core of the star.
• The star now has 4 layers: at the center accumulates the Carbon, surrounded by a He fusion layer, surrounded by a hydrogen fusion layer, surrounded by a dilute inert layer of hydrogen
CHeBe
BeHeHe1248
844 ;
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The CNO Cycle
• Once sufficient 12C is available it uses H nuclei to produce all the nuclei up to 16O in a reaction cycle.
• When sufficient 16O is available and the star has heated up muich more, the star breaks out of the CNO cycle by capture of a 4He or a proton. This forms all the nuclei up to 56Fe.
• In this process energy is produced to heat the star further because the binding energy/ nucleon is still increasing.
• Hans Bethe (Cornell) and Willy Fowler (Caltech) obtained Nobel Prizes for these discoveries
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Relative Elemental Abundances of the Solar SystemRelative Elemental Abundances of the Solar System
.At least 4 processes generate heavier elements..At least 4 processes generate heavier elements.
1.E-12
1.E-10
1.E-08
1.E-06
1.E-04
1.E-02
1.E+00
1.E+02
0 10 20 30 40 50 60 70 80 90 100
Z
% a
bu
nd
an
ce
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Supernova explosion produces heavy elements
• When a star has burned all
its light fuel, it cools and
contracts under the gravitatio-
nal pressure. It then explodes. During the explosion huge numbers
of neutrons are produced and
captured rapidly by the exis-
ting elements (r-process).
• Beta decay changes neutrons into protons and fills in the elements
• The new elements are blasted into space and are collected by newly formed stars.
• Binary stars which are very hot can also produce the heavy elements.
Neutron star
“normal”donor star
Accretion disk
Neutron star
“normal”donor star
Accretion disk
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Chart of the Chart of the NucleiNuclei
Chart of the Chart of the NucleiNuclei
N
Z
““Magic” proton Magic” proton numbersnumbers
2,8,20,28,50,822,8,20,28,50,82
““Magic” proton Magic” proton numbersnumbers
2,8,20,28,50,822,8,20,28,50,82 N=Z
““Magic” Magic” neutron neutron numbersnumbers
...+126...+126
““Magic” Magic” neutron neutron numbersnumbers
...+126...+126
Location of the r-process in the nuclear mass table
The r-process works its way up the mass table on the neutron-rich side . There are other processes on the proton rich side
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•Heavy elements are also created in a slow neutron capture Heavy elements are also created in a slow neutron capture process, called the “s” process.process, called the “s” process.
•The site for this process is in specific stage of stellar evolution, The site for this process is in specific stage of stellar evolution, known as the Asymptotic Giant Branch(AGB) phase. known as the Asymptotic Giant Branch(AGB) phase.
•It occurs just before an old star expels its gaseous envelope It occurs just before an old star expels its gaseous envelope into the surrounding interstellar space and sometime thereafter into the surrounding interstellar space and sometime thereafter dies as a burnt-out, dim "white dwarf“dies as a burnt-out, dim "white dwarf“
•They often produce beautiful nebulae like the They often produce beautiful nebulae like the "Dumbbell Nebula"..
•Our Sun will also end its active life this way, probably some 7 Our Sun will also end its active life this way, probably some 7 billion years from now.billion years from now.
•Heavy elements are also created in a slow neutron capture Heavy elements are also created in a slow neutron capture process, called the “s” process.process, called the “s” process.
•The site for this process is in specific stage of stellar evolution, The site for this process is in specific stage of stellar evolution, known as the Asymptotic Giant Branch(AGB) phase. known as the Asymptotic Giant Branch(AGB) phase.
•It occurs just before an old star expels its gaseous envelope It occurs just before an old star expels its gaseous envelope into the surrounding interstellar space and sometime thereafter into the surrounding interstellar space and sometime thereafter dies as a burnt-out, dim "white dwarf“dies as a burnt-out, dim "white dwarf“
•They often produce beautiful nebulae like the They often produce beautiful nebulae like the "Dumbbell Nebula"..
•Our Sun will also end its active life this way, probably some 7 Our Sun will also end its active life this way, probably some 7 billion years from now.billion years from now.
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Fifth Homework Set, due March 3, 2005
1. Which two nuclei are used most often in nuclear fission reactors. How are these nuclei made to fission?
2. The most widely used reactor type is a lit-water reactor. What purposes does the water serve in the operation of the reactor?
3. What reaction does a fusion reactor use to produce energy and what are the principal advantages of a fusion reactor over a fission reactor that follow from using this reaction?
4. What is a nuclear chain reaction; how can it be started and can it be stopped?
5. How is the plasma in a fusion reactor kept away from the walls of the reactor vessel? What is the shape of the “bottle” that holds the plasma ?
6. What fuel does the sun burn to produce its power, and what is the “ash” left behind from the burning?