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Be sure to catch up with last week's class
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Remember please do not interrupt
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#WizardoftheDay
Ludwig Boltzmann
#LearningToFly Chapter 12, Part 5
#Electrogravitics101
#Magneto_Thermodynamics101
Last week, we covered the scientific and societal controversy surrounding Maxwell's demon, and briefly touched on two devices that exhibit anti-entropic behavior.
In part 2 we shall take an in-depth look at the mechanism responsible for anti-entropic behavior in the laser. This mechanism is called a population inversion, and until the mid twentieth century, was considered little more than a quaint mathematical curiosity, with no basis in physical reality.
In order to lay a proper foundation for discussion of inverted populations, a short review of classical thermodynamics is included.
https://t.me/AzazelNews/243711
Ludwig Boltzmann
#LearningToFly Chapter 12, Part 5
#Electrogravitics101
#Magneto_Thermodynamics101
Last week, we covered the scientific and societal controversy surrounding Maxwell's demon, and briefly touched on two devices that exhibit anti-entropic behavior.
In part 2 we shall take an in-depth look at the mechanism responsible for anti-entropic behavior in the laser. This mechanism is called a population inversion, and until the mid twentieth century, was considered little more than a quaint mathematical curiosity, with no basis in physical reality.
In order to lay a proper foundation for discussion of inverted populations, a short review of classical thermodynamics is included.
https://t.me/AzazelNews/243711
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Degrees of Freedom:
At it's most basic level, the science of thermodynamics is a statistical study of vibration and movement in populations of atoms or molecules. In order to numerically quantify a population, it is necessary to understand how many different ways or modes of vibration and/or movement are available to the population. For instance, a population of molecules that have magnetic properties, when under the influence of a magnetic field, may be constrained to movement in a single direction, and yet in the absence of a magnetic field, this same population may have nearly unlimited directions of movement. In thermodynamics we use the term "degrees of freedom" to describe the number of available modes of vibration and/or directions of movement. Alternately, degrees of freedom can be viewed as the set of locations available to a population of atoms or molecules when it moves or vibrates. This set of available locations is called the population's "phase space".
At it's most basic level, the science of thermodynamics is a statistical study of vibration and movement in populations of atoms or molecules. In order to numerically quantify a population, it is necessary to understand how many different ways or modes of vibration and/or movement are available to the population. For instance, a population of molecules that have magnetic properties, when under the influence of a magnetic field, may be constrained to movement in a single direction, and yet in the absence of a magnetic field, this same population may have nearly unlimited directions of movement. In thermodynamics we use the term "degrees of freedom" to describe the number of available modes of vibration and/or directions of movement. Alternately, degrees of freedom can be viewed as the set of locations available to a population of atoms or molecules when it moves or vibrates. This set of available locations is called the population's "phase space".
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Temperature, energy, and entropy:
The concept of temperature arose from a need to quantify the human perception of hot and cold. However at the beginning of the 19th century, no scientist was sure what temperature was really measuring. It was well known that expending energy (doing work), such as drilling a hole, or bending sheet metal caused the material to get hot, so heat was related to energy in some manner. But what was heat? Some believed it was a discrete substance, separate from matter (they called it caloric), while others believed it was an inherent property of matter, like mass or volume.
Boltzmann and the Bridge Between Two Worlds
https://www.youtube.com/watch?v=uJGyTcehW18
The concept of temperature arose from a need to quantify the human perception of hot and cold. However at the beginning of the 19th century, no scientist was sure what temperature was really measuring. It was well known that expending energy (doing work), such as drilling a hole, or bending sheet metal caused the material to get hot, so heat was related to energy in some manner. But what was heat? Some believed it was a discrete substance, separate from matter (they called it caloric), while others believed it was an inherent property of matter, like mass or volume.
Boltzmann and the Bridge Between Two Worlds
https://www.youtube.com/watch?v=uJGyTcehW18
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Boltzmann's controversial equation, Eq. 1 relates the entropy of an atomic or molecular population to it's phase space (disorder). As a side note, this equation was engraved on his tombstone...
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The utility of Eq. 1 is that it defines entropy (disorder) as the ratio of energy to temperature.
Looked at another way, given a population with a constant energy content, as entropy declines, temperature rises.
In other words, as the degrees of freedom available to a population diminish, those few degrees of freedom still available, MUST contain the entire energy content of the population, and this causes the temperature of the population to rise.
Looked at another way, given a population with a constant energy content, as entropy declines, temperature rises.
In other words, as the degrees of freedom available to a population diminish, those few degrees of freedom still available, MUST contain the entire energy content of the population, and this causes the temperature of the population to rise.
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Eq. 2b
Where:
S = Entropy (disorder).
Q = Energy in Joules.
T = Absolute temperature in degrees Kelvin
Eq. 2b implies that for any population with a non-zero energy content, as entropy approaches zero (one degree of freedom), the temperature of the population approaches infinity.
Where:
S = Entropy (disorder).
Q = Energy in Joules.
T = Absolute temperature in degrees Kelvin
Eq. 2b implies that for any population with a non-zero energy content, as entropy approaches zero (one degree of freedom), the temperature of the population approaches infinity.
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Maximum disorder:
Is there an upper limit to disorder? The answer to this question depends on the degrees of freedom available to a population of atoms or molecules. For most populations, and in the most general sense of the question, the answer is "no". This answer has a practical consequence. It implies there is no upper limit to temperature, since there will always be another dimension in phase space (degree of freedom), to which we can add another increment of energy, and thereby raise the temperature of the population.
However, if a population has a limited set of dimensions in phase space (limited degrees of freedom), there is a definite upper limit to disorder.
Surprisingly, the limit will be reached when exactly half of the dimensions in phase space are occupied by the population. It is obvious that when a population of atoms or molecules contain no energy, they do not vibrate or move, and therefore all members of the population occupy a single point in phase space (no disorder).
Is there an upper limit to disorder? The answer to this question depends on the degrees of freedom available to a population of atoms or molecules. For most populations, and in the most general sense of the question, the answer is "no". This answer has a practical consequence. It implies there is no upper limit to temperature, since there will always be another dimension in phase space (degree of freedom), to which we can add another increment of energy, and thereby raise the temperature of the population.
However, if a population has a limited set of dimensions in phase space (limited degrees of freedom), there is a definite upper limit to disorder.
Surprisingly, the limit will be reached when exactly half of the dimensions in phase space are occupied by the population. It is obvious that when a population of atoms or molecules contain no energy, they do not vibrate or move, and therefore all members of the population occupy a single point in phase space (no disorder).
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Figure 1 - Temperature versus phase space occupancy
Now consider the opposite condition.
I.E. Every member of the population is vibrating or moving in every available degree of freedom (all dimensions of phase space are occupied). Again, all members of the population are exactly alike, and again there is no disorder.
Therefore maximum disorder (and entropy) is achieved when exactly 50% of the dimensions in phase space are occupied.
As a consequence of this remarkable situation Eq. 2b implies the temperature of a population at maximum disorder is infinite, and the temperature of any population where more than 50% of phase space is occupied is negative AND hotter than infinity. Figure 1 shows the relationship between temperature and phase space occupancy for a population with limited degrees of freedom.
Now consider the opposite condition.
I.E. Every member of the population is vibrating or moving in every available degree of freedom (all dimensions of phase space are occupied). Again, all members of the population are exactly alike, and again there is no disorder.
Therefore maximum disorder (and entropy) is achieved when exactly 50% of the dimensions in phase space are occupied.
As a consequence of this remarkable situation Eq. 2b implies the temperature of a population at maximum disorder is infinite, and the temperature of any population where more than 50% of phase space is occupied is negative AND hotter than infinity. Figure 1 shows the relationship between temperature and phase space occupancy for a population with limited degrees of freedom.
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Quantum populations:
While classical physics allows populations of atoms or molecules to have nearly unlimited modes of vibration and movement (with corresponding degrees of freedom), quantum electrodynamics is a different story altogether.
Consider the electron orbits of a Hydrogen atom. The allowed orbital values are discreet, and defined by Eq. 3. Therefore electron orbits represent a population with very limited degrees of freedom (dimensions in phase space).
While classical physics allows populations of atoms or molecules to have nearly unlimited modes of vibration and movement (with corresponding degrees of freedom), quantum electrodynamics is a different story altogether.
Consider the electron orbits of a Hydrogen atom. The allowed orbital values are discreet, and defined by Eq. 3. Therefore electron orbits represent a population with very limited degrees of freedom (dimensions in phase space).
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Eq 3.
MVR= N*h / (2*Pi)
Where:
M = Electron Mass.
V = Orbital velocity.
R = Orbital radius.
N = Quantum number. (1,2,3,…)
h = Plank's constant
As a consequence of Eq. 3, an atom will only absorb (or emit) electromagnetic energy at those frequencies corresponding to the difference in energy between allowed orbits.
MVR= N*h / (2*Pi)
Where:
M = Electron Mass.
V = Orbital velocity.
R = Orbital radius.
N = Quantum number. (1,2,3,…)
h = Plank's constant
As a consequence of Eq. 3, an atom will only absorb (or emit) electromagnetic energy at those frequencies corresponding to the difference in energy between allowed orbits.
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Bohr Model of the Hydrogen Atom
https://www.youtube.com/watch?v=au2HCVn9IJI
An atom will only absorb (or emit) electromagnetic energy at those frequencies corresponding to the difference in energy between allowed orbits. In a population of Hydrogen atoms at room temperature, the vast majority of electrons are in the orbit N = 1, and the effective temperature of the orbital population is very close to zero. Now suppose we pass a controlled electric current through the Hydrogen atoms, thereby raising the majority of electrons into the orbit N = 2. We now have a population with only 2 degrees of freedom (two dimensional phase space) N = 1, and N = 2. Further, since the majority of electrons (greater than 50%) are in the orbit N = 2, the population of electron orbits is at a negative temperature (see figure 1 above), and therefore hotter than infinity.
In thermodynamics terms, this is known as a population inversion, and under the rules of classical thermodynamics, was considered a physical impossibility...
https://www.youtube.com/watch?v=au2HCVn9IJI
An atom will only absorb (or emit) electromagnetic energy at those frequencies corresponding to the difference in energy between allowed orbits. In a population of Hydrogen atoms at room temperature, the vast majority of electrons are in the orbit N = 1, and the effective temperature of the orbital population is very close to zero. Now suppose we pass a controlled electric current through the Hydrogen atoms, thereby raising the majority of electrons into the orbit N = 2. We now have a population with only 2 degrees of freedom (two dimensional phase space) N = 1, and N = 2. Further, since the majority of electrons (greater than 50%) are in the orbit N = 2, the population of electron orbits is at a negative temperature (see figure 1 above), and therefore hotter than infinity.
In thermodynamics terms, this is known as a population inversion, and under the rules of classical thermodynamics, was considered a physical impossibility...
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NB: Negative kelvin is hotter than infinite temperature, not because it would feel hotter, but because heat flows from the negative temperature object to the positive temperature object because we can demonstrate mathematically that the negative temperature object is in a higher energy state.
https://en.wikipedia.org/wiki/Negative_temperature#:~:text=A%20substance%20with%20a%20negative,is%20hotter%20than%20infinite%20temperature.
https://en.wikipedia.org/wiki/Negative_temperature#:~:text=A%20substance%20with%20a%20negative,is%20hotter%20than%20infinite%20temperature.
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Theodore H. Maiman. The world´s first functioning Laser
https://www.youtube.com/watch?v=_3m_PZBKp9s
The Laser:
In 1960, based on the thermodynamic principal of population inversion, Theodore Maiman invented the laser (U.S. Pat 3,353,115). An intense source of light or electric current is used to excite electron orbits into a population inversion. The only way these electrons can cool down is to emit a beam of electromagnetic energy (photons) at a single wavelength, equal to the energy difference between electron orbits . Since the population of photons in the laser beam is of one wavelength (monochromatic), they have exactly one degree of freedom, for any non-zero energy, when S = 0 (W = 1 in Eq. 1), T is infinite.
The laser uses the population inversion of electron orbits as a "daemon-like, trap door" to convert low temperature energy into a coherent beam of light, hot enough to burn a hole through the Sun
https://www.youtube.com/watch?v=_3m_PZBKp9s
The Laser:
In 1960, based on the thermodynamic principal of population inversion, Theodore Maiman invented the laser (U.S. Pat 3,353,115). An intense source of light or electric current is used to excite electron orbits into a population inversion. The only way these electrons can cool down is to emit a beam of electromagnetic energy (photons) at a single wavelength, equal to the energy difference between electron orbits . Since the population of photons in the laser beam is of one wavelength (monochromatic), they have exactly one degree of freedom, for any non-zero energy, when S = 0 (W = 1 in Eq. 1), T is infinite.
The laser uses the population inversion of electron orbits as a "daemon-like, trap door" to convert low temperature energy into a coherent beam of light, hot enough to burn a hole through the Sun
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Theodore H. Maiman. The world´s first functioning Laser
https://www.youtube.com/watch?v=_3m_PZBKp9s
The Laser:
In 1960, based on the thermodynamic principal of population inversion, Theodore Maiman invented the laser (U.S. Pat 3,353,115). An intense source of light or electric current is used to excite electron orbits into a population inversion. The only way these electrons can cool down is to emit a beam of electromagnetic energy (photons) at a single wavelength, equal to the energy difference between electron orbits . Since the population of photons in the laser beam is of one wavelength (monochromatic), they have exactly one degree of freedom, for any non-zero energy, when S = 0 (W = 1 in Eq. 1), T is infinite.
The laser uses the population inversion of electron orbits as a "daemon-like, trap door" to convert low temperature energy into a coherent beam of light, hot enough to burn a hole through the Sun
https://www.youtube.com/watch?v=_3m_PZBKp9s
The Laser:
In 1960, based on the thermodynamic principal of population inversion, Theodore Maiman invented the laser (U.S. Pat 3,353,115). An intense source of light or electric current is used to excite electron orbits into a population inversion. The only way these electrons can cool down is to emit a beam of electromagnetic energy (photons) at a single wavelength, equal to the energy difference between electron orbits . Since the population of photons in the laser beam is of one wavelength (monochromatic), they have exactly one degree of freedom, for any non-zero energy, when S = 0 (W = 1 in Eq. 1), T is infinite.
The laser uses the population inversion of electron orbits as a "daemon-like, trap door" to convert low temperature energy into a coherent beam of light, hot enough to burn a hole through the Sun
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Reference to "daemon-like, trap door" class
Wizard James C. Maxwell
#LearningToFly Chapter 12,, Part 4
#Electrogravitics101
#Magneto_Thermodynamics101
https://t.me/AzazelNews/240356
Wizard James C. Maxwell
#LearningToFly Chapter 12,, Part 4
#Electrogravitics101
#Magneto_Thermodynamics101
https://t.me/AzazelNews/240356
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2nd Law of thermodynamics - Principles of Refrigeration
https://www.youtube.com/watch?v=dDQgOvmSXCE
The second law of thermodynamics states that:
"In any cyclic process, the entropy must either increase or remain the same".
Consider a steam engine. Steam engines can not convert all of the energy contained in the boiler to useful work. Some of the energy must be dumped into a condenser. The reason for this prerequisite is that extracting energy from a boiler lowers the entropy of the boiler, however dumping a smaller quantity of energy into a condenser (at a lower temperature) raises the entropy of the condenser more than entropy was lowered by extracting the larger quantity of energy from the boiler ( Eq. 2a). In other words, a condenser is needed to meet the requirements of the second law of thermodynamics.
https://www.youtube.com/watch?v=dDQgOvmSXCE
The second law of thermodynamics states that:
"In any cyclic process, the entropy must either increase or remain the same".
Consider a steam engine. Steam engines can not convert all of the energy contained in the boiler to useful work. Some of the energy must be dumped into a condenser. The reason for this prerequisite is that extracting energy from a boiler lowers the entropy of the boiler, however dumping a smaller quantity of energy into a condenser (at a lower temperature) raises the entropy of the condenser more than entropy was lowered by extracting the larger quantity of energy from the boiler ( Eq. 2a). In other words, a condenser is needed to meet the requirements of the second law of thermodynamics.
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For steam engines, or any other engine that operates on the principal of heat extraction, the second law of thermodynamics IS absolute (much to the benefit of OPEC). If steam engines could break the second law of thermodynamics, then a steam engine could convert all of the energy from a boiler operating at room temperature, without needing a lower temperature condenser to dump waste energy.
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Inverted populations:
Consider an engine extracting energy from a boiler containing an inverted population of atoms or molecules.
Since the act of energy extraction, raises the entropy of the boiler, this engine DOES NOT require a condenser, and this engine will convert ALL of the extracted energy into useful work. In other words, ANY boiler operating on the right hand side of figure 1 (beyond 50% phase space occupancy), is also operating beyond the point of maximum entropy (disorder), and unlike a conventional boiler, entropy increases as energy is extracted from an inverted population boiler. Therefore no other step is required to meet the condition imposed by the second law.
We have just uncovered a loop hole in the second law of thermodynamics.
Consider an engine extracting energy from a boiler containing an inverted population of atoms or molecules.
Since the act of energy extraction, raises the entropy of the boiler, this engine DOES NOT require a condenser, and this engine will convert ALL of the extracted energy into useful work. In other words, ANY boiler operating on the right hand side of figure 1 (beyond 50% phase space occupancy), is also operating beyond the point of maximum entropy (disorder), and unlike a conventional boiler, entropy increases as energy is extracted from an inverted population boiler. Therefore no other step is required to meet the condition imposed by the second law.
We have just uncovered a loop hole in the second law of thermodynamics.