丘乔羽: Scientific Research

丘乔羽: Scientific Research: "The Time Dilation Factor Could Not Obtain a Negative Time Qiao Yu Qiu** School of Materials Science and Engineering, University of New South..."

丘乔羽: Testing Time Dilation By Sunrays

丘乔羽: Testing Time Dilation By Sunrays: "AbstractSince the relativity theory published, the time dilation attracted the great interested. The time dilation had caused the debates fo..."

Testing Time Dilation By Sunrays

Abstract

Since the relativity theory published, the time dilation attracted the great interested. The time dilation had caused the debates for more than 100 years. It is difficult to do an experiment to test the time dilation on Earth. In this paper, we test the time dilation by an imagined experiment with Sunrays. The result shows that one would create paradoxes if he/she stands on different reference frameworks. Human being does not have the time dilation because they are in one reference framework only. The conclusion is that the time dilation can only be obtained in between two different reference frameworks.

Keywords: time dilation; relativity; unjustifiable hypotheses.

I. Introduction

The relativity theory predicts the time dilation of a transported clock. Einstein gave two unjustifiable hypotheses in his relativity[1]. Based on these two unjustifiable hypotheses he derived the Lorentz transformation and obtained the time dilation factor. Recently, many experts discussed the time dilation in details[2-10]. Jefimenko considered that the time dilation is a dynamic cause-and-effect phenomenon and not merely a kinematic effect[11]. Reinhardt et al. had tested the time dilation with fast optical atomic clocks[12]. Saathoff et al. had done an improved test of the time dilation using laser spectroscopy on fast ions at the heavy-ion storage-ring in Heidelberg[8]. Petit et al. had discussed the relativistic time dilation contribute to the divergence of universal time and ephemeris[10]. Peerally had detected the possible occurrence of a proportionality between the time dilation effects of special and general relativity in free-fall motion in Keplerian orbits[13]. The time dilation factor gives us a hope that one might find a way to go into the past of the world. Stephen W. Hawking pointed out this situation in his book “a brief history of time”[14]: “While this would be fine for writers of science fiction, it would mean that no one’s life would be safe: someone might go into the past and kill your father or mother before you were conceived!” Due to it is difficult to do an experiment to test the time dilation on Earth, let us do an imagined experiment with Sunrays to test the time dilation.

II. Analysis

The concept of the time dilation in relativity theory comes from two unjustifiable hypotheses. Einstein gave these two unjustifiable hypotheses in his relativity[1]:

(1)    The time-interval (time) between two events is independent of the condition of motion the body of reference.

(2)    The space-interval (distance) between two points of a rigid body is independent of the condition of motion of the body of reference.

Based on these two unjustifiable hypotheses, the time dilation factor γ can be obtained as follows[1]:

    (1)

Where v is the velocity of the motion, and c is the light speed.

Since Einstein published the formula of the time dilation factor, it caused the debates for more than 100 years. One will probably produce many paradoxes from the formula of the time dilation. The well-known example of misunderstanding the time dilation is the Twin Paradox. It says that X and Y are twins. While twin X travels in a high-speed rocket to outer space, twin Y remains on Earth. Many years later, twin X returns to Earth and reunites with twin Y. From twin Y’s point of view (on Earth), twin X has time dilation and twin X should be younger than twin Y when they reunite. From twin X’s point of view, twin Y has time dilation and twin Y should be younger than twin X when they reunite. The Twin Paradox had been discussed in many articles[15-41]. However, the Twin Paradox is produced from the viewpoints of different reference frameworks. Let us do an imagined experiment with Sunrays to test the time dilation.

We imagine that two beams of Sunrays begin to transmit from the Sun to the Earth at the same time. From our point of view (on Earth), two beams of Sunrays should arrive the Earth at the same time. We believe that both of them take 8 minutes. However, from ray1’s point of view, the time of ray2 is independent of the condition of motion the body of reference. Ray2 will have the time dilation and arrive the Earth earlier than ray1. Vice verse, from ray2’s point of view, the time of ray1 is independent of the condition of motion the body of reference. Ray1 will have the time dilation and arrive the Earth faster than ray2. It is clear that the paradox comes from the different viewpoints. We have to emphasize here that the time dilation can only be obtained in between two different reference frameworks in the relativity theory. From the viewpoint of one reference framework, one will obtain the time dilation on the other reference framework. Once the two different reference frameworks meet each other, the difference will disappear. There is no time dilation in one reference framework.

From the above Sunrays experiment, we can find that the Twin Paradox comes from the viewpoints of two different reference frameworks. Human being has the only one reference framework on Earth. When the Sunrays arrive the Earth, the two different reference frameworks become one reference framework on Earth. From Eq.(1) we can find that γ=1 at v=0. It is clear that human being does not have the time dilation when two different reference frameworks meet each other. Therefore, two beams of Sunrays will arrive the Earth at the same time.

Let us see the Twin Paradox. When twin X arrives the Earth to reunite with twin Y, they are in the same reference framework (on Earth). Once twin X arrives the Earth, the two different reference frameworks become one reference framework. They won’t have the time dilation on Earth. Thus, they are the same age while they reunite.

III. Conclusion

We conclude that the time dilation can only be obtained in between two different reference frameworks. Once the two different reference frameworks meet each other, the difference will disappear. There is no time dilation in one reference framework.

References:

[1]            A. Einstein, Relativity The Special and the General Theory, 1916).

[2]            R. Kanai, C. L. E. Paffen, H. Hogendoorn, et al., Journal of Vision 6, 1421 (2006).

[3]            A. Gjurchinovski, American Journal of Physics 74, 838 (2006).

[4]            J. R. Bray, Ieee Antennas and Propagation Magazine 48, 109 (2006).

[5]            J. J. New and B. J. Scholl, Journal of Vision 9 (2009).

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[8]            G. Saathoff, S. Karpuk, U. Eisenbarth, et al., Physical Review Letters 91 (2003).

[9]            G. Saathoff, S. Reinhardt, H. Buhr, et al., Canadian Journal of Physics 83, 425 (2005).

[10]         G. Petit and S. Klioner, Astronomical Journal 136, 1909 (2008).

[11]         O. D. Jefimenko, American Journal of Physics 64, 812 (1996).

[12]         S. Reinhardt, G. Saathoff, H. Buhr, et al., Nature Physics 3, 861 (2007).

[13]         A. Peerally, South African Journal of Science 104, 221 (2008).

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Scientific Research

The Time Dilation Factor Could Not Obtain a Negative Time

Qiao Yu Qiu*

* School of Materials Science and Engineering, University of New South Wales, Sydney,

NSW 2052, Australia

e-mail: qiaoyuqiu@gmail.com

A fundamental concept of the relativity theory is the time dilation of a transported clock. Einstein derived the Lorentz transformation to obtain the time dilation factor. The time dilation factor gives us a hope that one might find a way to go into the past. This prediction had caused the debates for more than 100 years. Can we control the time dilation to go into the past? According to the relativity theory, the time dilation can be created in between two different reference frameworks. However, one could not obtain a negative time from the dilation factor in any circumstance. In the same framework (on earth), human being could not go into the past. Therefore, the time arrow on earth is towards the future only.

Einstein predicted the time dilation of a transported clock in his relativity¹. He had given two unjustifiable hypotheses and derived the Lorentz transformation to obtain the time dilation factor γ. Recently, many experts discussed the time dilation^2-10 in details. Jefimenko considered that the time dilation is a dynamic cause-and-effect phenomenon and not merely a kinematic effect¹¹. Reinhardt et al. had tested the time dilation with fast optical atomic clocks¹². Saathoff et al. had done an improved test of the time dilation using laser spectroscopy on fast ions at the heavy-ion storage-ring in Heidelberg⁸. Petit et al. had discussed the relativistic time dilation contribute to the divergence of universal time and ephemeris¹⁰. Peerally had detected the possible occurrence of a proportionality between the time dilation effects of special and general relativity in free-fall motion in Keplerian orbits¹³. The time dilation factor gives us an image that one might find a way to go into the past. Stephen W. Hawking pointed out this situation in his book “a brief past

of time”¹⁴: “While this would be fine for writers of science fiction, it would mean that no one’s life would be safe: someone might go into the past and kill your father or mother before you were conceived!” Many scientists are trying to control the time dilation. Can we control the time dilation to go into the past? In this paper, we control the velocity of the motion to work out whether we can obtain a negative time from the time dilation factor or not.

How can we control the time dilation?  Einstein had given two unjustifiable hypotheses in his relativity¹:

1.       The time-interval (time) between two events is independent of the condition of motion the body of reference.

2.       The space-interval (distance) between two points of a rigid body is independent of the condition of motion of the body of reference.

Based on these two unjustifiable hypotheses, the time dilation factor γ can be derived as follows¹

               (1)

           

Where v is the velocity of the motion, and c is the light speed.

The only thing we can control in Eq.(1) is the velocity of the motion “v”. The relationship between the present time T_p and the past time T_h is

   (2)                       

Where T_x is time which we want to control. We try to control T_x and find a way to go into the past. Einstein first predicted the time dilation of a transported clock in his 1905 paper¹⁵. We imagine that we control the time dilation with a transported clock. From Eq.(2), one can have

                (3)

Based on the Lorentz transformation, the relationship between the time in motion t’ and the time at rest t is¹

                      (4)

Now, we try to control T_x with very high velocity of the motion v.

                                                  (5)

Where t_r is the time at rest (t_r >0).

The above Eq.(5) shows that values of v, t_r and c are positive. If v<c, T_x is positive. If v>c, T_x is a complex number. When v=c, one would have

               (6)

The above Eq.(6) shows that the limit time one can control is zero. One could not control v and t_r to obtain a negative time T_x. From Eq(2), one can find that human being could not control T_x to make T_p become T_h. It means human being cannot control the time dilation to go into the past.

According to the relativity theory, the time dilation can be created only in between two different reference frameworks. Our framework is the earth. The past is the past time of the earth. We are in the present time of the earth. In the same framework (on earth), human being could not have the time dilation. We imagine that we travel in a rocket in very high speed to outer space. The rocket and the earth are two different reference frameworks. According to the relativity theory, one would have time dilation in the rocket framework. However, the past of the earth is not in the outer space. If one wants to go into the past of the earth, one must return to the earth. Once the rocket arrive the earth, the rocket and the earth become the same reference framework. Furthermore, even the rocket have time dilation, it could not obtain a negative time. From Eq.(6) one can find that one could not breakthrough the time dilation limit to obtain a negative time. Human being could not obtain a negative time in any circumstance.

It is concluded that the time dilation has been proven that it could be created in between two different reference frameworks only. The time dilation factor could not obtain a negative time. In the same framework (on earth), human being could not go into the past. Therefore, the time arrow on earth is towards the future only.

References

1.         Einstein, A. Relativity The Special and the General Theory, (1916).

2.         Kanai, R., Paffen, C.L.E., Hogendoorn, H. & Verstraten, F.A.J. Time dilation in dynamic visual display. Journal of Vision 6, 1421-1430 (2006).

3.         Gjurchinovski, A. Relativistic addition of parallel velocities from Lorentz contraction and time dilation. Am. J. Phys. 74, 838-839 (2006).

4.         Bray, J.R. From Maxwell to Einstein: Introducing the time-dilation property of special relativity in undergraduate electromagnetics. Ieee Antennas and Propagation Magazine 48, 109-114 (2006).

5.         New, J.J. & Scholl, B.J. Subjective time dilation: Spatially local, object-based, or a global visual experience? Journal of Vision 9(2009).

6.         Saathoff, G., et al. Toward a new test of the relativistic time dilation factor by laser spectroscopy of fast ions in a storage ring. Hyperfine Interactions 146, 71-75 (2003).

7.         Saathoff, G., et al. Experimental test of time dilation by laser spectroscopy on fast ion beams. in Special Relativity: Will it Survive the Next 101 years?, Vol. 702 (eds. Ehlers, J. & Lammerzahl, C.) 479-492 (2006).

8.         Saathoff, G., et al. Improved test of time dilation in special relativity. Physical Review Letters 91(2003).

9.         Saathoff, G., et al. Test of time dilation by laser spectroscopy on fast ions. Canadian Journal of Physics 83, 425-434 (2005).

10.       Petit, G. & Klioner, S. Does relativistic time dilation contribute to the divergence of universal time and ephemeris time? Astronomical Journal 136, 1909-1912 (2008).

11.      Jefimenko, O.D. Direct calculation of time dilation. Am. J. Phys. 64, 812-814 (1996).

12.       Reinhardt, S., et al. Test of relativistic time dilation with fast optical atomic clocks at different velocities. Nature Physics 3, 861-864 (2007).

13.       Peerally, A. A law of time dilation proportionality in Keplerian orbits. S. Afr. J. Sci. 104, 221-224 (2008).

14.       Hawking, S.W. A Brief History of Time, (1988).

15.       Einstein, A. The electrodynamic moving body. Annalen Der Physik 17, 891-921 (1905).