Total Object Mass is the cumulative sum of an object's atoms
in [Relativity]
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From: Dono. on 18 Jul 2010 22:14 On Jul 18, 3:53 pm, thejohnlreed <thejohnlr...(a)gmail.com> wrote: > On Jul 17, 8:03 am, "Dono." <sa...(a)comcast.net> wrote: > > > On Jul 17, 1:58 am, johnlawrencereedjr <thejohnlr...(a)gmail.com> wrote: > > > > jr writes> > > > Your using binding energy in the wrong direction. That energy is a > > > part of the total mass. Binding energy is used to explain the missing > > > total mass in the measure of the separate products of an experiment. > > > Idiot > > jr writes> > Altho youstupidity andignorance will never be evident to you, you are > insuring that your children and their children will carry this > stupidity from you for life. I suggest you refrain from public > intellectualforumsuntil you acquire the knowledge to doso. Thinkof > your progeny. > johnreed Imbecile, In modern physics mass is not additive, only energy and momentum are. So, for a system of particles: E_total=Sum(E_i) P_total=Sum(p_i) The total mass of the system is : M=1/c^2*sqrt(E_total^2-c^2*P_total^2) Now, the mass of each particle in the system is : m_i=1/c^2*sqrt(E_i^2-c^2*P_i^2) Obviously , M is not equal to Sum(m_i). Find a different hobby.
From: Dono. on 18 Jul 2010 22:18 On Jul 18, 3:53 pm, thejohnlreed <thejohnlr...(a)gmail.com> wrote: > On Jul 17, 8:03 am, "Dono." <sa...(a)comcast.net> wrote: > > > On Jul 17, 1:58 am, johnlawrencereedjr <thejohnlr...(a)gmail.com> wrote: > > > > jr writes> > > > Your using binding energy in the wrong direction. That energy is a > > > part of the total mass. Binding energy is used to explain the missing > > > total mass in the measure of the separate products of an experiment. > > > Idiot Every idiot with a blog fancies himself as a scientist.
From: PD on 19 Jul 2010 10:51 On Jul 18, 5:50 pm, thejohnlreed <thejohnlr...(a)gmail.com> wrote: [a lot of simple misconceptions] There are lots of ways to measure mass, other than on a pan balance (either one pan or two pan). You can put a quantity on the end of anything that has a spring constant and measure the frequency of oscillation. You can put it at the end of a pendulum and measure the period. You can put individual ions through a mass spectrometer. (The last, by the way, is the most common one for determining atomic masses, especially since it can discriminate between isotopes.) Only one of those has anything to do with gravitational pull with the Earth. You make numerous comments about precision. Trust me, the precision in those measurements is more than enough to show the nonlinearity of mass in the periodic table. That's where the numbers in the periodic table come from.
From: Dono. on 20 Jul 2010 09:02 On Jul 20, 2:28 am, thejohnlreed <thejohnlr...(a)gmail.com> wrote: > In modern physics mass is not additive, only energy and momentum are. > So, for a system of particles: > > jr writes> > Who has introduced particles here? A system of particles? Show me the > system of particles. Standard crackpot imbecile. > E_total=Sum(E_i) > P_total=Sum(p_i) > The total mass of the system is : > M=1/c^2*sqrt(E_total^2-c^2*P_total^2) > Now, the mass of each particle in the system is : > m_i=1/c^2*sqrt(E_i^2-c^2*P_i^2) > Obviously , M is not equal to Sum(m_i). > Find a different hobby. > > jr writes> > The above is your total argument? Of course it is, it is beginner physics textbook stuff. Since you are unable to learn it, I suggest again that you find a different hobby.
From: johnlawrencereedjr on 20 Jul 2010 10:45
PD View profile More options Jul 19, 7:51 am On Jul 18, 5:50 pm, thejohnlreed <thejohnlr...(a)gmail.com> wrote: [a lot of simple misconceptions] There are lots of ways to measure mass, other than on a pan balance (either one pan or two pan). You can put a quantity on the end of anything that has a spring constant and measure the frequency of oscillation. You can put it at the end of a pendulum and measure the period. You can put individual ions through a mass spectrometer. (The last, by the way, is the most common one for determining atomic masses, especially since it can discriminate between isotopes.) jr writes> That's good information PD. Only one of those has anything to do with gravitational pull with the Earth. jr writes> I would say that the spring oscillations are caused by the spring's response to the earth attractor (notice I did not say gravity) and the pendulum is also a response to the earth attractor (or any planet or moon attractor). You make numerous comments about precision. Trust me, the precision in those measurements is more than enough to show the nonlinearity of mass in the periodic table. That's where the numbers in the periodic table come from. jr writes> Again this is an inherent problem not with numbers of atoms that combine in a reaction but with our conversion of the atom amounts in units based on their conserved resistance. While we cannot take an unknown compound or mixture (say a scoop of dirt) and determine a number of atoms and type of atom in the scoop, on the basis of its total mass as measured on a balance scale, as long as we know the specific element we are measuring we can determine to a reasonable accuracy the number of atoms it contains. And if you have a problem with that we can define the element as consisting of one isotope. In which case, with regard to that element its mass is a reasonable determinant on which to calculate the number of atoms. In principle, what is true in this idealized case should be true even for the scoop of dirt on chemical analysis, which appears to be possible according to your good information provided above. The lack of linearity in the periodic table in terms of mass has no bearing on theprinciple I am noting. What ever the degree of error in the conversion of atoms to mass and vice versa is miniscule compared to a planet surface object and the planet. So how ever many atoms we use to represent mass resistance, we can double, triple or quadruple that number and when set against the resistance of the number of atoms in the planet, is still on the face absurd. Have a good time PD. jr |