Average rating: | Rated 5 of 5. |
Level of importance: | Rated 5 of 5. |
Level of validity: | Rated 5 of 5. |
Level of completeness: | Rated 5 of 5. |
Level of comprehensibility: | Rated 5 of 5. |
Competing interests: | None |
I am deeply grateful to Professor Wang for thoroughly considering my suggestions and making revisions to the manuscript. I believe that the theory is now essentially complete.
Review of "Why do spacecraft always experience a black-out area that disrupts communications when they return to Earth?"
by Jian’an Wang
Strengths:
Novel approach: The paper proposes a new aether theory and modifies the Lorentz factor and transformations based on it. This fresh perspective offers an alternative explanation for the blackout phenomenon.
Detailed analysis: The paper provides a detailed analysis of the electromagnetic field transformations and explains how they lead to the signal distortion and blackout.
Predictive power: The theory predicts that similar blackouts will occur when spacecraft enter the atmosphere of any planet, which is a testable hypothesis.
Weaknesses:
Lack of empirical evidence: The paper relies heavily on theoretical arguments and lacks experimental evidence to support the claims of the new aether theory.
Overcomplication: The modified Lorentz factor and transformations involve additional parameters and calculations, making them more complex than the standard formulas.
Lack of discussion on alternative explanations: The paper focuses solely on the new aether theory and does not adequately address or compare it to existing explanations for the blackout phenomenon, such as plasma sheath formation.
Overall:
This paper presents an interesting and novel approach to understanding the blackout phenomenon. However, the lack of empirical evidence and the overcomplication of the proposed theory raise concerns. Further research and comparison with existing explanations are needed to validate the claims and assess the usefulness of the new aether theory.
Specific suggestions for improvement:
Conduct experiments to test the predictions of the new aether theory. This could involve measuring the electromagnetic field distortion during spacecraft re-entry or performing simulations to validate the modified Lorentz transformations.
Compare the new aether theory to existing explanations for the blackout phenomenon. This would help to clarify the specific advantages and disadvantages of each approach.
Simplify the modified Lorentz factor and transformations, if possible. This would make them more accessible to a wider audience and easier to use for practical applications.
Address potential criticisms of the new aether theory. This could help to strengthen the theory and address any concerns about its validity.
Further research questions:
How does the density of the space energy (aether) vary across different regions of space?
What are the specific mechanisms by which the aether interacts with electromagnetic waves?
What other physical phenomena can be explained by the new aether theory?
By addressing these questions and conducting further research, the new aether theory could potentially provide a valuable new framework for understanding various physical phenomena, including the communication blackouts experienced by spacecraft.
Additional comments:
I commend the author for his innovative and ambitious approach to this complex scientific problem.
The paper is well-written and clearly organized.
I believe that further research in this direction has the potential to make significant contributions to our understanding of the universe.
I encourage the author to continue his research and share his findings with the scientific community.
Corrections to the mathematical section of the article "Why do spacecraft always experience a black-out area that disrupts communications when they return to Earth?"
1. Definition of the speed of light in vacuum
The article defines the speed of light in vacuum as:
c = √(1 - √(1 - α²))
Where:
c is the speed of light in vacuum
α is the density of the space energy (ether)
This definition is not consistent with special relativity, which states that the speed of light in vacuum is a universal constant, independent of the speed of the source or the observer.
A more consistent definition would be:
c = √(1 - √(1 - α²v²/c²))
Where:
v is the speed of the source or the observer
This definition leads to the Lorentz equation for the speed of light, which is consistent with special relativity.
2. Lorentz transformation for the electric field
The article presents the following Lorentz transformation for the electric field:
E' = E - v × B
Where:
E' is the electric field in the moving frame
E is the electric field in the stationary frame
v is the speed of the source or the observer
B is the magnetic field in the stationary frame
This transformation is correct for a uniform electric field. However, for a non-uniform electric field, the correct transformation is:
E' = E + v × B - (v²/c²)∇ × E
This transformation takes into account the effect of the motion of the source or the observer on the diffraction of the electric field.
3. Lorentz transformation for the magnetic field
The article presents the following Lorentz transformation for the magnetic field:
B' = B + (1 - 1/√(1 - α²))(v/c) × E
Where:
B' is the magnetic field in the moving frame
B is the magnetic field in the stationary frame
v is the speed of the source or the observer
E is the electric field in the stationary frame
This transformation is correct for a uniform magnetic field. However, for a non-uniform magnetic field, the correct transformation is:
B' = B + (1 - 1/√(1 - α²))(v/c) × E - (v/c)∇ × B
This transformation takes into account the effect of the motion of the source or the observer on the diffraction of the magnetic field.
4. Analysis of the propagation of electromagnetic waves
The article analyzes the propagation of electromagnetic waves in vacuum and in a material medium. However, the analysis is not complete and does not take into account all relevant effects.
The analysis of the article should consider the following effects:
Diffraction of the electric and magnetic fields
Dispersion of the electric and magnetic fields
Absorption of the electric and magnetic fields
Consideration of these effects is important for an accurate analysis of the propagation of electromagnetic waves.
5. Conclusion
The proposed corrections would improve the accuracy and consistency of the mathematical section of the article. Additionally, consideration of the effects of diffraction, dispersion, and absorption would make the analysis more complete and accurate.
Additional recommendations
In addition to the proposed corrections, the following recommendations can be made to improve the article:
Conduct experiments to test the predictions of the new ether theory. This would help to validate the claims of the theory and assess its usefulness.
Compare the new ether theory to existing explanations for the blackout phenomenon. This would help to clarify the advantages and disadvantages of each approach.
Simplify the equations of the new theory, if possible. This would make the theory more accessible to a wider audience and easier to use for practical applications.
Implementing these recommendations would make the article more complete, accurate, and useful to the scientific community.
Sincerely Yours
Cesar Mello.
Review of "Why do spacecraft always experience a black-out area that disrupts communications when they return to Earth?"
by Jian’an Wang
Strengths:
Novel approach: The paper proposes a new aether theory and modifies the Lorentz factor and transformations based on it. This fresh perspective offers an alternative explanation for the blackout phenomenon.
Detailed analysis: The paper provides a detailed analysis of the electromagnetic field transformations and explains how they lead to the signal distortion and blackout.
Predictive power: The theory predicts that similar blackouts will occur when spacecraft enter the atmosphere of any planet, which is a testable hypothesis.
Weaknesses:
Lack of empirical evidence: The paper relies heavily on theoretical arguments and lacks experimental evidence to support the claims of the new aether theory.
Overcomplication: The modified Lorentz factor and transformations involve additional parameters and calculations, making them more complex than the standard formulas.
Lack of discussion on alternative explanations: The paper focuses solely on the new aether theory and does not adequately address or compare it to existing explanations for the blackout phenomenon, such as plasma sheath formation.
Overall:
This paper presents an interesting and novel approach to understanding the blackout phenomenon. However, the lack of empirical evidence and the overcomplication of the proposed theory raise concerns. Further research and comparison with existing explanations are needed to validate the claims and assess the usefulness of the new aether theory.
Specific suggestions for improvement:
Conduct experiments to test the predictions of the new aether theory. This could involve measuring the electromagnetic field distortion during spacecraft re-entry or performing simulations to validate the modified Lorentz transformations.
Compare the new aether theory to existing explanations for the blackout phenomenon. This would help to clarify the specific advantages and disadvantages of each approach.
Simplify the modified Lorentz factor and transformations, if possible. This would make them more accessible to a wider audience and easier to use for practical applications.
Address potential criticisms of the new aether theory. This could help to strengthen the theory and address any concerns about its validity.
Further research questions:
How does the density of the space energy (aether) vary across different regions of space?
What are the specific mechanisms by which the aether interacts with electromagnetic waves?
What other physical phenomena can be explained by the new aether theory?
By addressing these questions and conducting further research, the new aether theory could potentially provide a valuable new framework for understanding various physical phenomena, including the communication blackouts experienced by spacecraft.
Additional comments:
I commend the author for his innovative and ambitious approach to this complex scientific problem.
The paper is well-written and clearly organized.
I believe that further research in this direction has the potential to make significant contributions to our understanding of the universe.
I encourage the author to continue his research and share his findings with the scientific community.
Corrections to the mathematical section of the article "Why do spacecraft always experience a black-out area that disrupts communications when they return to Earth?"
1. Definition of the speed of light in vacuum
The article defines the speed of light in vacuum as:
c = √(1 - √(1 - α²))
Where:
c is the speed of light in vacuum
α is the density of the space energy (ether)
This definition is not consistent with special relativity, which states that the speed of light in vacuum is a universal constant, independent of the speed of the source or the observer.
A more consistent definition would be:
c = √(1 - √(1 - α²v²/c²))
Where:
v is the speed of the source or the observer
This definition leads to the Lorentz equation for the speed of light, which is consistent with special relativity.
2. Lorentz transformation for the electric field
The article presents the following Lorentz transformation for the electric field:
E' = E - v × B
Where:
E' is the electric field in the moving frame
E is the electric field in the stationary frame
v is the speed of the source or the observer
B is the magnetic field in the stationary frame
This transformation is correct for a uniform electric field. However, for a non-uniform electric field, the correct transformation is:
E' = E + v × B - (v²/c²)∇ × E
This transformation takes into account the effect of the motion of the source or the observer on the diffraction of the electric field.
3. Lorentz transformation for the magnetic field
The article presents the following Lorentz transformation for the magnetic field:
B' = B + (1 - 1/√(1 - α²))(v/c) × E
Where:
B' is the magnetic field in the moving frame
B is the magnetic field in the stationary frame
v is the speed of the source or the observer
E is the electric field in the stationary frame
This transformation is correct for a uniform magnetic field. However, for a non-uniform magnetic field, the correct transformation is:
B' = B + (1 - 1/√(1 - α²))(v/c) × E - (v/c)∇ × B
This transformation takes into account the effect of the motion of the source or the observer on the diffraction of the magnetic field.
4. Analysis of the propagation of electromagnetic waves
The article analyzes the propagation of electromagnetic waves in vacuum and in a material medium. However, the analysis is not complete and does not take into account all relevant effects.
The analysis of the article should consider the following effects:
Diffraction of the electric and magnetic fields
Dispersion of the electric and magnetic fields
Absorption of the electric and magnetic fields
Consideration of these effects is important for an accurate analysis of the propagation of electromagnetic waves.
5. Conclusion
The proposed corrections would improve the accuracy and consistency of the mathematical section of the article. Additionally, consideration of the effects of diffraction, dispersion, and absorption would make the analysis more complete and accurate.
Additional recommendations
In addition to the proposed corrections, the following recommendations can be made to improve the article:
Conduct experiments to test the predictions of the new ether theory. This would help to validate the claims of the theory and assess its usefulness.
Compare the new ether theory to existing explanations for the blackout phenomenon. This would help to clarify the advantages and disadvantages of each approach.
Simplify the equations of the new theory, if possible. This would make the theory more accessible to a wider audience and easier to use for practical applications.
Implementing these recommendations would make the article more complete, accurate, and useful to the scientific community.
Sincerely Yours
Cesar Mello.
Thanks again to Professor Liu for his high-level and courageous review of the paper.