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Our Nuclear Physics All Wrong!

chanrasjid

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Our Nuclear Physics All Wrong!

Our current theory to explain nuclear energy is very likely all wrong. The readers may immediately respond with : "If nuclear energy physics is all wrong, how come we still could build nuclear reactors?" Physics theory and technology are two different aspects. In 1945, they would still have succeeded in developing the atomic bomb whether E=mc² was correct or fictitious; their knowledge of nuclear physics then was empirical, without yet a theoretical basis. They knew that huge energy were released in the fission of U-235. It is the same with gunpowder. The ancients need no theory of chemistry of the elements as they knew that sulfur, fine charcoal and saltpeter (potassium nitrate) would combine to produce gunpowder. But having a correct nuclear physics theory should be better than holding on to a fictitious theory. A correct theory may point to the way to real advancement in physics; it may be our "bad" nuclear physics that is the cause that our tokamak fusion reactors (to produce unlimited clean fusion energy from water) deliver only "news" and not any tangible results - news and more news - despite 7 decades and billions of dollars spent.

The real culprit is the mass spectrometer - with their most sophisticated equipment on planet earth like the Penning trap, used to weigh atoms. These ultra high-end equipment of nuclear physics proves to be not reliable after all! They weigh atoms and deliver atomic mass values which the particle physicists embrace wholeheartedly. So the physicists found that when U-235 splits into smaller fragments, some mass goes missing, leading them to formulate a "theory of mass defect". They happily put the "missing mass" in the famous Einstein equation E=mc² and transformed it into a huge figure for energy and - "Eureka! I have unraveled the mystery of nuclear energy!". The Almighty God created the world perfect with nothing missing! God made sure that when atoms redistributed themselves during nuclear reactions, He still consider each and every atom uniquely his creature with their mass well preserved.

For the past months, I was examining mass spectrometry, a very advanced technique in physics that could sort charged particles and ions, e.g. electrons, protons, ²H⁺, He²⁺, ¹²C⁺, and then to compare the masses of two of the particles giving their relative atomic mass. Today, the physics community has their experimental measurements of the atomic masses of every possible nucleus of atoms and their isotopes collected into a shared CODATA database. One has just to look up the open database to know the atomic mass of an element; e.g the 2012 data has:

neutron 1.008 664 915 850 amu (atomic mass units)
H-1, hydrogen 1.007 825 032 231
H-2, deuterium 2.014 101 778 120
He-4, helium 4.002 603 254 130
U-235 235.0439301

I Have a 10 page paper (unpublished), the pdf file of which is available for download at my website:
"Is Mass Spectrometry Accurate?"
http://www.emc2fails.com

From the official site of ITER (International Thermonuclear Energy Research) :
https://www.iter.org

"UNLIMITED ENERGY

Fusion, the nuclear reaction that powers the Sun and the stars, is a potential source of safe, non-carbon emitting and virtually limitless energy. Harnessing fusion's power is the goal of ITER, which has been designed as the key experimental step between today's fusion research machines and tomorrow's fusion power plants."
When will tomorrow arrive? And the "potential" may be diminished to a very low figure with "bad" nuclear physic's backing.

Some basics. In nuclear physics, their basic unit for mass is the amu and we have a knowledge about its conversion to kilogram. In earlier days, the chemists started with Hydrogen as 1 amu; so oxygen weighs 16, nitrogen 14. Today we take the amu scale to have carbon-12 as 12 exact; then oxygen-16 (the most abundant natural isotope, 99.8%) is no more a whole number, but
15.99491461957(17). This "(17)", 17 in bracket, represents the uncertainty in the last two figures.

Even before the 20th century (mass spectrometry invented about 1920), chemists already had the ability to "weigh" atoms. They analyzed the ratio of the amount of elements that would combine to form a compound. As they had already knowledge of their chemical reactions, they could also find the "relative atom mass" - say of oxygen/hydrogen, about 16. The could do electrolysis of water and collect the gases released, oxygen and hydrogen; as the formula of water is H₂O, they could weigh the amounts of hydrogen and oxygen collected and they would be able to calculate the ratio of one atom oxygen to one atom hydrogen. The figure they got in 1900 was 15.87; they could get only about 2 decimals as the accuracy of their balances - as well as technology then - were limited.

Then in the 1920's, they invented mass spectrometry. Mass spectrometry relies on the fact that if a charged particles or ions (say an atom of oxygen with one electron removed would have a +1 positive charge, as ¹⁶O⁺, a positive ion of oxygen-16) are injected into a uniform magnetic field, they would be deflected by amounts that depend on their masses. In this manner, they could sort and identify ions according to their atomic masses. They then developed the method to compare atomic masses of the various atoms. The precision of their technique kept improving until they were able the weigh atoms more precisely then their chemists counterparts. The chemist then could at most weigh atoms to the 2nd or 3rd decimal place (eg, H = 1.008, C = 12.01), but the new technique soon surpassed the chemist and it could reach precision to the 4th or 5th decimals.

An English chemist William Prout in 1815 found that the atoms of elements all seemed to have a mass that are whole numbers of the mass of the hydrogen atom - the so called ‘whole number rule’ of atomic weights known as Prout’s hypothesis. When the mass spectrometers started to weigh atoms more "accurately", they found that the mass figures "don't add up properly" - something's missing. They expected the helium atom to weigh 4 times that of the hydrogen, but hydrogen has mass 1.008, but helium was just about 4; there was a loss of mass in the synthesis from hydrogen to helium. The physics community then accepted this "mass deficit" or "missing mass" to be correct. They could just stuff this missing mass into Einstein's famous equation : E = mc² (E = energy, m= mass, c = light speed) to explain nuclear fusion/fission to be the new source of energy of the sun. What E=mc² means that if you could transform mass to pure energy, the formula would give you the figure! because c² is a huge factor, a little "missing" mass converted to energy became enormous (you could try calculating if planet earth could survive if someone could completely convert 1 kg of rice fully into pure energy!). When U-235 splits into smaller fragments due to radioactivity, only a tiny fractions of the mass involved gets converted to energy - not the whole U-235 atoms! That's how extremely "dirty" fission reactors work.

Well, when they first found the "missing mass", no one then entertained that it was their new fancy spectrometers that could be playing tricks! There never was any experimental test to verify if their spectrometers were reliable - not ever! The little (about 0.1%) missing mass could well be their weighing scales were only approximately good. It could even be that if they were to be able to weigh atoms with our verified and high precision beam chemical balances of today, all atoms would have atomic masses equal to that of the mass number (a whole number equal to the number of protons+neutron) in atomic mass units! If this is true, then it would mean the law of mass conservation is again revived - there is not need of E=mc² to combine mass and energy to our current "law of mass-energy conservation". It is just mass alone being conserved - and much simplified without being entangled with energy. This would mean a total collapse of the nuclear physics theory of today. The country that first changes its direction in nuclear physics research may have the early advantage.

Until today, the accuracy of mass spectrometer that weigh atoms to 10¯¹⁰ has not been verified to be reliable. They could only give precision reached in their measurements - but precision and accuracy are two independent aspects. The most prestigious equipment today for mass spectrometry is the Penning trap that could trap a single particle/ion in a small space of about 1 - 5 centimeters. It seems China is just still building ONE Penning trap (the first) called the LPT (Lanzhou Penning Trap) - we can imagine how costly this piece of equipment should be. You would read news in the media every so often as, in 2017, physicists from Germany and Japan of RIKEN determined the mass of the proton to the "highest precision" to date:
https://phys.org/news/2017-07-precise-proton-mass.html
"The resulting mass of the proton, determined to be 1.007276466583(15) three times more precise than the presently accepted value."

If any of you were to care to stop for a minute and ponder quietly about what 1.007276466583 means - I believe very few did. The particle physicists are infringing into a domain that once were the preserve of the gods! I can't express with words what it means to "weigh an atom to 11 decimal places!" - you have to use your imaginations. It should be no wonder that such particle physicists from the top universities are commanding such respects and prestige - even the ancient sage emperors of China Yao and Sun could not achieve such prestige with their magical powers! It is no wonder the whole world now bows in humility to the present day sages with their command of their miraculous science. Fortunately - or unfortunately depending on which side you are on - there is a simple chemical experiment that could be done to conclusively decide if mass spectrometry is correct, or wrong which may mean a full revival of the law of mass conservation; this latter outcome would mean a total collapse our nuclear physics theory.

The relative atomic mass of Na/F based on the current atomic mass from mass spectrometry is : 22.989769/18.998403 or 1.210089; this figure may be taken to be without uncertainty as the atomic masses have no uncertainty in the 6th decimal. The ratio of the mass number of Na/F is : 23/19 or 1.210526. So the problem reduces to doing a chemical analysis of sodium fluoride NaF using our chemical balance to determine the relative atomic mass of Na/F, whether it agrees with 1.210089 or with 1.210526. Our analytical balances today has enough precision for the experiment, it could measure 1 gram to 1 part in 100,000 or a million. With a fresh analysis of NaF today, we could come out with a value of : 1.210089 ± 0.000012 confirming the accuracy of mass spectrometry; or the value may be 1.210526 ± 0.000012 rejecting mass spectrometry and confirming the law of mass conservation - unequivocally.

Best regards,
Chan Rasjid Kah Chew,
Singapore,
website: http://www.emc2fails.com

ABSTRACT . Mass spectrometry currently measures atomic masses giving precision in the order of 10¯¹⁰ , but this accuracy has not been established experimentally to be correct - precision and accuracy are two independent aspects. The Lorentz force law itself - the formula underlying mass spectrometry - has not been verified. In the 1920’s, the atomic masses of some elements measured through the early mass spectrometers showed some discrepancies from the ‘whole-number-rule’ of atomic weights. The physics community accepted the discrepancies from whole numbers to be correct; they proposed the concept of ‘mass defects’. This, together with the mass energy equivalence of E = mc 2 allowed Arthur Eddington to propose a new ‘sub-atomic’ energy to account for the source of the energy of the sun to be in line with the 15 billion age of the sun in their theory. They never entertained the other simpler option - that their mass spectrometers were only approximately good. If the atomic masses of nuclides were to be just whole numbers equal to the mass number in atomic mass unit, it would be a confirmation of the law of mass conservation in the atomic and subatomic world. The key to decide the fate of nuclear physics is in sodium fluoride NaF. Sodium and fluorine occur in nature only as single stable isotopes. A chemical analysis of NaF with the current analytical balance to determine the relative atomic mass of Na/F would decide conclusively if mass spectrometry is accurate. The current relative atomic mass of Na/F is : 22.989769/18.998403 or 1.210089; the ratio of the mass number of Na/F is : 23/19 or 1.210526. The accuracy of mass spectrometry would be confirmed if the value is 1.210089 ± 0.000012. Otherwise, if the value is 1.210526 ± 0.000012, it would mean a confirmation of the law of conservation of mass. The implications of such a scenario is beyond imagination - the whole world of nuclear physics would collapse.
 
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Not wrong per se but the interpretation needs to be corrected (newtonian mechanics vs quantum and so on)
 
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There is so much we know and so little we know. We don't know what an electric field is , what a gravitational field is, what a magnetic field is etc ,we only know of their effects. We don't know what protons are, what electrons are, what neutrons are, the glues that hold them together, how they are held together ; again we only see and know of them by their actions and reactions. Yes experimental physics has always been the drive but theoretical physics has also led the way forward (LASERs, Radio waves etc).

No matter how much man boasts, there are many thing things that will remain secret by God. How matter was created, how light was and is created and how it moves through the universe, how space was created etc etc. The creation of the Universe is one secret Man cannot answer.
 
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Not wrong per se but the interpretation needs to be corrected (newtonian mechanics vs quantum and so on)
It is wrong at the most fundamental level.

Our current notion is that ALL nuclear energy (fission/fusion) comes from "missing mass" in nuclear interaction; e.g. in fission of U-235, the masses of the final fragments don't add up to the original mass of the U-235 atoms - some mass goes "missing". So when they put "m" into E=mc², they got a huge amount of energy E (because c=light speed, a huge number).

But there is actually no "missing mass" at all. The missing mass is because they "weigh" atoms using the "ultra-high-end" Penning trap. Unfortunately, these Penning trap has never been verified to weigh mass correctly - never ever verified. Whereas all our laboratory chemical balances have been verified to weight mass correctly in principle; not so with the Penning trap! If we were to be able to weigh atoms with our verified balances, then no "missing mass" would be found. So without the "missing mass", there is no way to apply Einsteins' famous E=mc² equation.

One should not be surprised now why the world has failed - since 1954 on the founding of CERN - in nuclear fusion energy. Our explanation of the nuclear energy based on E=mc² is fictitious. Our current ITER program will also end with total failure. One can find an analogy with the invention of gunpowder. The ancients know the formula of gunpowder as mixture of sulfur, carbon and potassium nitrate (saltpeter). It is empirical knowledge from experiments - they had no chemistry of the elements as we know today. But we today created great advances in material science when we get our theory correct. I believe if we throw away our current fictitious nuclear energy ideas and get to a correct understanding of how nuclear energy is released, we may finally succeed in nuclear fusion and solve the world's energy need. The country that first changes direction in nuclear energy research will have an early advantage.

Chan Rasjid,
Singapore
 
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Very interesting article... let me come back to you with some questions and comments after I have done some reading especially your article. @chanrasjid
 
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I think there has been suppression of criticism of the accuracy of mass spectrometry. From:
G.Audi. The History of Nuclidic Masses and of their Evaluation (2006).
https://arxiv.org/abs/physics/0602050
"As a matter of fact, some attempts were made to determine atomic masses with equipment used in chemistry. However, the values obtained appeared later to be at strong variance compared to modern results".​
The author did not quote any sources about the chemical determination of atomic masses. The internet search too returns no result. "strong variance" is an exceptionally strong term to use when they are quoting atomic masses to 10 decimals!

I have suggested a simple experiment that can incontrovertibly decide if our nuclear physics is right or wrong - meaning repudiated absolutely - based on just a simple chemical analysis of sodium fluoride with our very sensitive chemical analytical balance. The problem is that even if someone does the experiment and the result is against our nuclear physics, there is no peer-review journal that would publish such highly controversial findings. Very few would be willing to be the "whistle-blower" as it can cause great backlash against one's career in physics.

Even now, I can't find any way to publish my findings. No peer review journal will ever entertained such submission that tries to overturn all of nuclear physics. The physics community has spent billions building their tokamak reactors, or ITER. If I were to contact the physics professors at Tsinghua University or Peking University, they would just reject me. Many of them have Ph.D from the western universities and they are comfortably teaching as professors. They don't like to have their world overturned.

The only way I can see is to be able to get through to some powerful world leaders like Xi Jingping. Only such people can change the direction of nuclear research which commands billions of dollars of government funds. But how to talk to them unless we know of someone who has close personal reach to them. Or contact Jack Ma of Alibaba?

Chan Rasjid.
 
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