The positron was discovered in 1932, did physicist have any knowledge or assumed that matter could be annihilated into energy at the start of XX century?
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1Does "E = mc^2" count? which is to say, matter/energy conversion has a lot more avenues than antiparticles. – Carl Witthoft Aug 23 '18 at 13:12
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1Annihilation is a more specific concept than matter-to-energy conversion. The former requires antimatter, first theorised c. 1930 from the Dirac equation. But the fact that all exothermic reactions are due to converting mass to energy followed from special relativity in 1905. For example, chemicals undergo small changes in reactions. How much of a change are you looking for? Does chemistry count? Do nuclear reactions? – J.G. Aug 23 '18 at 18:50
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@CarlWitthoft,...such as? – user157860 Aug 24 '18 at 05:49
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@J.G., The question means: before 1905 and relativity. What was knownbefore that date? – user157860 Aug 24 '18 at 05:51
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Heat from a 'non chemical' source was known. See https://hsm.stackexchange.com/questions/7475/when-was-it-first-noticed-or-demonstrated-that-radioactive-material-became-war/7482#7482 – Jon Custer Aug 24 '18 at 18:24
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Let us consider the following info on developments prior to 1905.
Before 1905 (The forthcoming of $E = mc^2$) 1881 J. J. Thompson proposed that a charged conductor in motion increases its mass by $\frac{4}{15} e^2/a$
1904 H. A. Lorentz proposed that $m_L = m_0 (1 – v^2/c^2)^{-3/2}$ based on deformable spherical charge.
1904 Hasenöhrl derived an apparent mass increase of a moving cavity containing electromagnetic energy E, obtaining $m_e = \frac{8}{3} E/c^2$.
1905 On Abraham’s suggestion, Hasenöhrl corrected this to $m_e = \frac{4}{3} E/c^2$
Based on the study of the historical development of concepts, one may deduce that the equation $E = mc^2$ would have been discovered by other physicists sooner or later. However, it is likely that Einstein merely accelerated the development. ref.- >https://files.eric.ed.gov/fulltext/EJ848449.pdf
our contention is that though annihilation of particles was not an acceptable concept prior to 1905 but other ways of energy conversion of mass was being attempted.
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1@uhoh-many thanks for the editing..with MathJax it looks good...somehow I am not conversant with it..though its simple... – drvrm Sep 24 '18 at 04:33
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1@uhoh-thanks sir..i am 76 yr old and barely write with one finger..i will try.. – drvrm Sep 24 '18 at 05:33
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well you certainly write some thoughtful and authoritative answers with that finger! I don't know if you like to drift to other SE sites, but I have a math history question that hasn't received enough attention so far: How has the definition of the complex logarithm evolved since Cotes (1682-1716)? – uhoh Sep 24 '18 at 06:30
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thanks ...basically, I am a nuclear physics person but have used maths as a tool-i will try to look up...my experience in using complex logarithm is very limited – drvrm Sep 24 '18 at 08:36
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here's a tough one then: Has a nuclear “neutron halo” been measured directly? Anything other than “breaks easily”? – uhoh Sep 24 '18 at 08:46
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@uhoh-just came across a study on neutron halo interaction-pl.seehttps://www.sciencedirect.com/science/article/pii/S0370269316304890 – drvrm Sep 24 '18 at 13:42
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Oh, it's fairly recent and open access as well, thanks! Still though, it's about how easily the nucleus breaks ((total) interaction cross sections). I'd still like to see if there are any other observables besides this but that should be done in Physics SE not here. Thanks for your help! – uhoh Sep 24 '18 at 14:30