Beta Decay of 32 Phosphorus - Is It Positively Charged?

beta man
Messages
2
Reaction score
0
Hi all,

when an atom goes through a beta decay, say 32 phosphorus. The final state is then 16 protons, 16 neutrons, and 15 electrons. This seems to be an ion of sulfur.

My question is, does the atom remain in a positively charged state? or does it ionize it suuroundings and captures an additional electron?

Best

Beta man
 
Physics news on Phys.org
beta man said:
My question is, does the atom remain in a positively charged state?

For all eternity? No.
 
So for how long?

In principle if I have a crystal of 32 phsophor in a large vacuum tube, with walls that can only absorb electrons. Then after few atom decays into sulfur the crystal will become positivly charge.

Will it stay like this for infinite time? since there is no gas to ionize.

Will this inhibit the decay of all the crystal?



Beta man
 
It stays that way until it finds an electron to capture. In ordinary materials, that happens quickly.
 
beta man said:
In principle if I have a crystal of 32 phsophor in a large vacuum tube, with walls that can only absorb electrons. Then after few atom decays into sulfur the crystal will become positivly charge.

Will it stay like this for infinite time?

Eventually the crystal gains enough net positive charge that it can attract the emitted electrons back before they reach the walls of the tube. These electrons combine with (some of) the sulfur ions produced by the decay, to yield neutral sulfur atoms.
 

Thread 'Toponium Discovered'

Toponium is a hadron which is the bound state of a valance top quark and a valance antitop quark. Oversimplified presentations often state that top quarks don't form hadrons, because they decay to bottom quarks extremely rapidly after they are created, leaving no time to form a hadron. And, the vast majority of the time, this is true. But, the lifetime of a top quark is only an average lifetime. Sometimes it decays faster and sometimes it decays slower. In the highly improbable case that...
View full post »

Thread 'Dirac-Delta from Normalization of Continuous Eigenfunctions'

I'm following this paper by Kitaev on SL(2,R) representations and I'm having a problem in the normalization of the continuous eigenfunctions (eqs. (67)-(70)), which satisfy \langle f_s | f_{s'} \rangle = \int_{0}^{1} \frac{2}{(1-u)^2} f_s(u)^* f_{s'}(u) \, du. \tag{67} The singular contribution of the integral arises at the endpoint u=1 of the integral, and in the limit u \to 1, the function f_s(u) takes on the form f_s(u) \approx a_s (1-u)^{1/2 + i s} + a_s^* (1-u)^{1/2 - i s}. \tag{70}...
View full post »

Similar threads

B Beta Plus Decay: What's Left for the Electron?
Replies
8
Views
2K
I Decay constant of Different Elements and Isotopes?
Replies
3
Views
2K
I From what locations do radiated electrons start their movement in Beta decay?
Replies
21
Views
2K
I How Does Beta Decay Relate to the Role of W Bosons in Weak Nuclear Force?
Replies
4
Views
4K
A "Reversal" of Nuclear Decay in Beta Emitters
Replies
4
Views
2K
B Tritium, beta decay, spatial parity
Replies
2
Views
2K
A What Are the Final Electronic and Ionic States of 72Ga After Decay to 72Ge?
Replies
3
Views
2K
I Does the mass of a neutron vary?
Replies
19
Views
3K
I Why is Proton Radiation this Rare in Nuclear Fission Decay?
Replies
9
Views
3K
I Why use the mass of 2 electrons in calculation of Q for beta
Replies
10
Views
5K

Hot Threads

Recent Insights

Back
Top