What is the most accurate way to represent the heavy nucleus of an element?

[John37309]

I'm sure everyone here will be familiar with the usual graphic or image used to show what an atomic nucleus might look like. Here are two typical images used today;

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Everybody has seen those images. But in reality, we have no picture of an atomic nucleus, we can only draw the picture based on the properties of the elements in the periodic table.

But, if the protons themselves stayed together as little particles on their own inside the nucleus, the positive charge in the protons would prevent the nucleus from ever forming in the first place. Same thing would happen with the neutrons because we know from neutron decay, the neutron is almost identical to the proton except its slightly heavier and has no charge, and it can decay into a proton. As a result of this, there can't be lots of little proton balls and lots of little neutron balls. They must be one ball that just gets slightly bigger and slightly heavier as we go through the periodic table up to the heavy elements.

My question;
So if you were drawing pictures of the nucleus of the heavier elements, as the elements get heavier going from Hydrogen all the way up to uranium, what are they most likely to look like. Or do you think the image with the little balls is a good representation of what a heavy nucleus would look like? Could we draw a heavy nucleus in a better way to better represent the properties of a heavy nucleus?

What I'm really getting at is that a uranium nucleus would look exactly like a deuterium, 1 proton and 1 neutron, but the uranium nucleus would just be bigger and heavier. But the uranium nucleus would be much closer to being two balls of energy, the proton ball and the neutron ball. It would not look like 92 proton balls and 92 neutron balls as shown in the above images.

John.

 

[ZapperZ]

It appears that you have completely neglected the role of the strong force and the Standard Model of elementary particles, and then made up your own hypothesis of the nucleus without it. Is there a reason for this, or do you just simply not accept the presence of the strong force? We have given the Nobel Prize for it!

Zz.

 

[John37309]

No, don't get me wrong. I think the standard model is great. I'm just suggesting that the visual representation of heavy nucleus's could be drawn in a way to better represent the properties we observe in experiments.

Critically, in heavy elements, using Iron as an example, we don't observe anything to suggests that Iron-52, with 26 protons and 26 neutrons, has 52 little individual bits stuck together by the strong force. What we do observe is a heavy nucleus, that physically gets bigger roughly by the cube of its mass. And with all the various fission, fusion, isotopes, and decay modes, we observe a nucleus that displays properties much closer to two bundles stuck together by the strong force. That's a bundle of protons and a bundle of neutrons, separate, but stuck together by the strong force.

I drew this image as a better representation of the properties we observe;

That image shows a Carbon, Iron and a Uranium nucleus. Below each image is an Isotope of each element with more neutrons than protons. So i displayed the neutrons in the isotope as being just a bit larger than the proton bundle. This image is physically a better representation of the properties we observe in heavy elements than the image with the single bundle of dots suggesting Iron-52 has 52 separate little bits stuck together.

John.

 

[ZapperZ]

No, don't get me wrong. I think the standard model is great. I'm just suggesting that the visual representation of heavy nucleus's could be drawn in a way to better represent the properties we observe in experiments.

Critically, in heavy elements, using Iron as an example, we don't observe anything to suggests that Iron-52, with 26 protons and 26 neutrons, has 52 little individual bits stuck together by the strong force. What we do observe is a heavy nucleus, that physically gets bigger roughly by the cube of its mass. And with all the various fission, fusion, isotopes, and decay modes, we observe a nucleus that displays properties much closer to two bundles stuck together by the strong force. That's a bundle of protons and a bundle of neutrons, separate, but stuck together by the strong force.

I drew this image as a better representation of the properties we observe;

That image shows a Carbon, Iron and a Uranium nucleus. Below each image is an Isotope of each element with more neutrons than protons. So i displayed the neutrons in the isotope as being just a bit larger than the proton bundle. This image is physically a better representation of the properties we observe in heavy elements than the image with the single bundle of dots suggesting Iron-52 has 52 separate little bits stuck together.

John.

This "picture" is not better. You clumped all the protons together, and all the neutrons together. This isn't the case. We know that such a configuration (a nuclear with all protons or all neutrons) are extremely unstable and don't exist. So it makes no sense to make such a picture. There's also nothing to indicate, based on all our experiments, that such a picture is more accurate. In fact, there are indications (based on what I mentioned earlier), that such a picture is not accurate at all.

This is almost like insisting on using the Rutherford model for the atom. It may be "easier" to visualize than the actual QM description, but just because it is easier to draw and picture, it doesn't make it accurate.

Zz.

 

[John37309]

Let me try to explain this better. I'm sure you are familiar with the image of the single proton. From particle collisions, we know the proton has 3 quarks. 2 up quarks and one down quark. When we discuss sub-atomic particles, we might draw the proton with the 3 quarks inside the proton like this;

But you will never see a chemical engineer drawing that image because the 3 quarks all act as one bundle, and we call it a proton. And we draw it as one circle because in the vast majority of experiments, protons display the properties of being one bundle of energy. And its extremely difficult to split that proton into smaller components. The proton never displays the properties of having 3 bits inside it. We only know it has 3 quarks inside it because we smash them in accelerators. But this is rare and we only do it for experimental purposes.

So the same thing applies to heavier Nuclei. They do not display any properties to suggest they have tonnes of little bits inside them. They act like two bundles, a bundle of protons and a bundle of neutrons, stuck together by the strong force as i drew in my image.

John.

 

[SpectraCat]

So the same thing applies to heavier Nuclei. They do not display any properties to suggest they have tonnes of little bits inside them. They act like two bundles, a bundle of protons and a bundle of neutrons, stuck together by the strong force as i drew in my image.

John.

Nope .. I don't agree with that at all. It doesn't account for known properties like fission, alpha and beta decay, nuclear shell structure, neutron emission, Mossbauer spectroscopy, nuclear angular momentum, etc. etc.

The usual model of a nucleus as being an inhomogeneous mixed mass of protons and neutrons was developed to explain these properties. Just pick up a book on nuclear physics and you will begin to understand why your model makes much less sense. It is incredibly difficult (if not impossible) to find a diproton (i.e. a He-2 nucleus), let alone a big mass of positive charge all smashed together, and holding a ball of pure neutrons together requires a massive external force like the gravitational field of a neutron star.

 

[ZapperZ]

So the same thing applies to heavier Nuclei. They do not display any properties to suggest they have tonnes of little bits inside them. They act like two bundles, a bundle of protons and a bundle of neutrons, stuck together by the strong force as i drew in my image.

John.

How do you know that same thing applies to heavy nuclei? How do you know they do not display such properties? You have not been following the results from RHIC and ALICE? Nothing of what you said here is consistent with nuclear theory AND experiment. Thus, it makes your picture a fiction toy model.

Zz.

 

[John37309]

Yea, ok. Just wanted to see if anyone agreed with the theory.

In my mind, it still make more sense to think about it the way i just described. But maybe its just me. Thanks for the input guys!

John.

 

[Drakkith]

Yea, ok. Just wanted to see if anyone agreed with the theory.

In my mind, it still make more sense to think about it the way i just described. But maybe its just me. Thanks for the input guys!

John.

Are you viewing the particles as classical "balls" or as quantum particles involving wave functions and such?

So the same thing applies to heavier Nuclei. They do not display any properties to suggest they have tonnes of little bits inside them. They act like two bundles, a bundle of protons and a bundle of neutrons, stuck together by the strong force as i drew in my image.

Actually the fusing and fissioning of nuclei is an example of the nucleus acting like many little bits. The quarks inside a nucleon don't act like such, as they are never emitted during a decay process. There are a few different models for the nucleus, none of which fully explain everything observed. (Wikipedia states that there are 37 models stated in N.D. Cook (2010). Models of the Atomic Nucleus (2nd ed.))

 

[DaveC426913]

Perhaps the gist of John's thread is that he sees no evidence that the protons and neutrons in the nucleus have an experimentally verifiable position within the nucleus. (i.e. that some are, say, at the top outside, whereas others are at the equator near the core).

Since this does not seem to be a correct way of modeling the nucleus, perhaps it should not be illustrated this way.

Any illustration is going to be inaccurate, his submission is simply inaccurate in a different way. His argument is that his might be less conceptually misrepresentative.

... or so it seems to me...

 

[Drakkith]

Perhaps the gist of John's thread is that he sees no evidence that the protons and neutrons in the nucleus have an experimentally verifiable position within the nucleus. (i.e. that some are, say, at the top outside, whereas others are at the equator near the core).

Since this does not seem to be a correct way of modeling the nucleus, perhaps it should not be illustrated this way.

Any illustration is going to be inaccurate, his submission is simply inaccurate in a different way. His argument is that his might be less conceptually misrepresentative.

... or so it seems to me...

Don't nucleons occupy particular spots or orbits or something in the nucleus? After all they are fermions and obey the Pauli Exclusion Principle, which is why nuclei differ in size as you add more nucleons, similar to adding more electrons. It seems like it is similar to electrons in that they occupy different orbitals and those orbitals define the likelihood of finding the particle at particular spots.

 

[John37309]

Are you viewing the particles as classical "balls" or as quantum particles involving wave functions and such?

Yes, i do imagine the nucleus as being a classical little ball. But i see it as a little ball of wavy energy, not solid, just wavy energy.

Its the mass of the ball and the charge of the ball that tells us what that element is. With Iron-52, if i fire neutrons at the nucleus, i can create a heavier isotope like Iron-56. But the neutrons will only stick to the "neutron" ball inside the nucleus. I can't create cobalt by firing neutrons at the nucleus hoping the neutrons will stick to the proton ball. In other words, i can't create a heavier element by firing neutrons at the nucleus. So in many situations, in my mind anyway, the nucleus of heavy elements just acts like two balls stuck together by the strong force.

But i do agree with you guys too. There are pro's and con's to drawing the nucleus in different ways depending on what someone is explaining. There is good and bad in my method.

John.

 

[Drakkith]

Its the mass of the ball and the charge of the ball that tells us what that element is. With Iron-52, if i fire neutrons at the nucleus, i can create a heavier isotope like Iron-56. But the neutrons will only stick to the "neutron" ball inside the nucleus. I can't create cobalt by firing neutrons at the nucleus hoping the neutrons will stick to the proton ball. In other words, i can't create a heavier element by firing neutrons at the nucleus.

Sure you can. That's how they create Plutonium and such. A neutron is absorbed by the nucleus, which then decays to a proton. And neutrons do not stick ONLY to other neutrons. They stick to both neutrons and protons. If it weren't for the fact that individual neutrons stick to individual protons, nuclei would be much much more unstable.

 

[John37309]

Sure you can. That's how they create Plutonium and such. A neutron is absorbed by the nucleus, which then decays to a proton. And neutrons do not stick ONLY to other neutrons. They stick to both neutrons and protons. If it weren't for the fact that individual neutrons stick to individual protons, nuclei would be much much more unstable.

You make a very valid point.

John.

 

[danR]

It's the shifting from fairly precise descriptions and images to an expression like 'little ball of wavy energy' that throws me. I cannot relate the expression with the images.

In any event, for all the models of a nucleus that are out there, putting all the protons together (if that's what we are 'actually' doing) seems the least likely candidate. Protons can only stand so much same-charge association for long. "Two's company, three's a crowd."

And I can't see any analogy of quark bag-containment with a nucleus model.

A deeper problem for any model is the nature of 'space' and 'location' at the quantum scale of a nucleus, and the wave-function of a nucleon: it only has a probability of being here or there in the nucleus, if we have any meaning for 'here' or 'there'.

"There is no 'there' there." --Gertrude Stein

 

[John37309]

It's the shifting from fairly precise descriptions and images to an expression like 'little ball of wavy energy' that throws me. I cannot relate the expression with the images.

Hi Dan,
If i could have drawn the nucleus's in my image as kind of wavy, i would have. So i drew them as perfect circles only because its a limitation of my image software. With my image software, i would have made a hash of the drawing if i tried to make the circles wavy.

Do you see any logic in what I'm suggesting Dan?

John.

 

[BruceW]

Unfortunately, the nucleus is tricky to model, which is why there are so many models on the nucleus.
What we do know is that the nucleus is roughly spherical (not two spheres joined together).
Also, the strong force does not depend on isospin, therefore the proton and neutron inside the nucleus can be viewed as two quantum states of the same particle. This gave rise to the term nucleon (neutron or proton), because we can't point at a nucleon inside the nucleus and say "its a proton" or "its a neutron".
So although you can say "there are 5 protons and 4 neutrons inside that nucleus", you can't say which are the protons and which are the neutrons.

 

[danR]

Hi Dan,
If i could have drawn the nucleus's in my image as kind of wavy, i would have. So i drew them as perfect circles only because its a limitation of my image software. With my image software, i would have made a hash of the drawing if i tried to make the circles wavy.

Do you see any logic in what I'm suggesting Dan?

John.

You should understand that my field is linguistics, and the way people map words and phrases to meaning and reality. That sort of thing. Physics is very interesting in the way it uses words, and physicists are very careful to define their terms, and re-define terms to apply to microscopic worlds in special way. When we draw circles (or spheres), or make them look 'wavy' and say the represent a nucleus, we are throwing around an incredible amount of terminology and conceptualization that may not apply at very small scales, or may have no meaning whatever.

If I teach adult Koreans English, I know they have no internalized mapping of preposition-phrases to concrete objects and relationships whatsoever. Because they have no 'prepositions' to speak of. 'In the car' is grammatical/syntactic object that they may have a very good formalist grasp, but in saying 'in the car', I bring up no image in their minds that would immediately be formed in an American's mind.

Likewise, my 'realist' knowledge of the strange world of microscopic scales is approximately zero, and I have to map your own use of terms to my own understanding of those terms to my non-understanding of the alien world of nuclei.

And then someone says there are umpteen theories about the architecture of nuclei, all devised by postgraduate students and professors of physics who have spent x hundred person-years thinking very deeply about the subject. So, as a layman in the jury box, I'm inclined to give a great deal of weight to those theories, and less weight to a theory that 'appears' to leave protons all together for certain length of time. I suppose there are times that the wave functions of protons may temporarily (quantum-speaking) be all on one 'side' (whatever that means), and yes, those may be the times when atom-bombs are more likely to be effective.

For most atoms, most of the time, I would be more agreeable to some averaged (time-wise or shell-wise) distribution of nucleons.

 

[John37309]

You should understand that my field is linguistics, and the way people map words and phrases to meaning and reality. That sort of thing...

Interesting Dan.

I'm a bit like you Dan. I myself have a keen interest in how scientists map there mathematics and words into images. You talk about teaching a foreign student a different language and how best the words and ideas can be communicated between two languages. Well I'm a bit like that. I read the scientific text and mathematics and then translate that to images. The funny thing about science is that when people get used to seeing a particular representation of something, its very difficult to change their mind. Even though the image might be a very poor representation of what someone is explaining, people just get used to the image and don't want to change it.

Hence very few people in this thread saw any merit at all in the case i presented here. Even though the images i drew here are an almost perfect copy of an image created by a very eminent scientist. Nobody even made the connection. I found this very interesting.

John.

 

[DaveC426913]

The funny thing about science is that when people get used to seeing a particular representation of something, its very difficult to change their mind. Even though the image might be a very poor representation of what someone is explaining, people just get used to the image and don't want to change it.

Hence very few people in this thread saw any merit at all in the case i presented here.

You assumed that people saw no merit because they don't want to change their ideas, and you ignored the possibility that people saw no merit because, say, the idea had no merit.

Even though the images i drew here are an almost perfect copy of an image created by a very eminent scientist. Nobody even made the connection. I found this very interesting.

So what? Eminent scientists propose ideas all the time. That doesn't make them right. Additionally, without context, there is no indication that those images apply here at all.

 

[ZapperZ]

Hence very few people in this thread saw any merit at all in the case i presented here.

There's no merit to it because the images are WRONG! You have been given several explanations on why they are wrong. Do you think your images trump over the physics? Since when?

Even though the images i drew here are an almost perfect copy of an image created by a very eminent scientist.

What "eminent scientist"? Please provide exact references. If you want to do science, then you have to know how to cite references, rather than present unverified statements.

The puzzling thing about this whole thread is that you asked for our opinions! When you got what you did not expect, you now think that we are the ones at fault for not accepting your picture. If you can't accept what you asked for, you shouldn't have asked in the first place.

Zz.

 

[AmagicalFishy]

I'm curious to see said source as well.

 

[Drakkith]

John, also remember that the images created vary with the target audience. Just because an image is created by a great scientist doesn't mean it was supposed to be as accurate as possible.

Also, you asked:

My question;
So if you were drawing pictures of the nucleus of the heavier elements, as the elements get heavier going from Hydrogen all the way up to uranium, what are they most likely to look like. Or do you think the image with the little balls is a good representation of what a heavy nucleus would look like? Could we draw a heavy nucleus in a better way to better represent the properties of a heavy nucleus?

So you asked us what it would most likely look like, and we gave you our best answer. I'm sorry you didn't like it.

 

[John37309]

Yep, i just wanted to see what you guys thought of the idea. And as you guys said, ye didn't like the idea. So that's fine. If you prefer the nucleus with lots of bits inside the nucleus, then that's what you want to see.

Unfortunately i can't quote my source in this particular case. But i drew the images myself, its my personal art work.

John.

 

[ZapperZ]

Yep, i just wanted to see what you guys thought of the idea. And as you guys said, ye didn't like the idea. So that's fine. If you prefer the nucleus with lots of bits inside the nucleus, then that's what you want to see.

And take note, we not only told you why we didn't like it, we gave you physics reasons why! You never gave any physical basis why your picture is better. All you cared about was that it is easier to visualize or conceptualize, regardless on whether it matches the physics of what we know about the nucleus. This is putting the cart before the horse, and forcing nature to conform to what you want it to look like. As scientists, this is the worst thing in the world to do. Yet, you think we do not accept your picture because we simply do not want to give up a picture that we are "familiar" with. That is the criticism that I will not let slide by without challenge.

Zz.

 

[John37309]

... That is the criticism that I will not let slide by without challenge.

Zz.

Master Zapper,
Ok, i suggest pistols at dawn. Time square, New York would be a suitable venue. Attire should be formal top coats and hats. Fight till the death

Its just a discussion, don't take it so seriously my friend.

John.

 

[JaredJames]

Its just a discussion, don't take it so seriously my friend.

This is a website whose aim is teaching and to do so only allows mainstream published science.

As such, it is important to take baseless claims that don't conform to the mainstream very seriously.

As per the rules, if you want to claim your image is correct you must support it with relevant sources. You cannot just assert it is correct because you find it easier.

 

[John37309]

This is a website whose aim is teaching and to do so only allows mainstream published science.

As such, it is important to take baseless claims that don't conform to the mainstream very seriously.

As per the rules, if you want to claim your image is correct you must support it with relevant sources. You cannot just assert it is correct because you find it easier.

Jarid,
Its just a public forum. Don't treat it like a science journal. Yes, its very good to beat out any scientific argument to come to a proper conclusion about something, or to resolve a problem. But PF is whatever the people using the forum make it. What's discussed in a public forum is not going to change the world, its just discussion of scientific topics. Lots of people with different backgrounds and levels of education.

John.

 

[JaredJames]

Jarid

Jared - as per the username.

Its just a public forum. Don't treat it like a science journal. Yes, its very good to beat out any scientific argument to come to a proper conclusion about something, or to resolve a problem. But PF is whatever the people using the forum make it. What's discussed in a public forum is not going to change the world, its just discussion of scientific topics. Lots of people with different backgrounds and levels of education.

John.

Correction, it's a private forum, under the rules the owners dictate.

Whether you like it or not, this website is designed around discussion of mainstream science only and teaching people about it. This is all well outlined in the rules you agreed to on signup.

You are not allowed to push your own theories and ideas unless you can support them with published science.

 

[John37309]

Jared - as per the username.


Correction, it's a private forum, under the rules the owners dictate.

Whether you like it or not, this website is designed around discussion of mainstream science only and teaching people about it. This is all well outlined in the rules you agreed to on signup.

You are not allowed to push your own theories and ideas unless you can support them with published science.

Well now Jarid, i had no idea this forum was such a serious place. Thats really good to know!

John.

 

[JaredJames]

Well now Jarid

Ooh, bad choice. Exceptionally bad choice.

 

[Drakkith]

Well now Jarid, i had no idea this forum was such a serious place. Thats really good to know!

John.

Then you are missing the entire purpose of the forum. To educate people on the current views of science. You wouldn't go to a Ford Truck Fan forum and be allowed to stay if you were constantly bashing Fords. That isn't what the forum is for! It is for people that like Ford Trucks!

Also, even if it this wasn't a serious forum, your defense of your picture was pretty serious...

 

[edguy99]

No, don't get me wrong. I think the standard model is great. I'm just suggesting that the visual representation of heavy nucleus's could be drawn in a way to better represent the properties we observe in experiments.

Critically, in heavy elements, using Iron as an example, we don't observe anything to suggests that Iron-52, with 26 protons and 26 neutrons, has 52 little individual bits stuck together by the strong force. What we do observe is a heavy nucleus, that physically gets bigger roughly by the cube of its mass. And with all the various fission, fusion, isotopes, and decay modes, we observe a nucleus that displays properties much closer to two bundles stuck together by the strong force. That's a bundle of protons and a bundle of neutrons, separate, but stuck together by the strong force.

I drew this image as a better representation of the properties we observe;

That image shows a Carbon, Iron and a Uranium nucleus. Below each image is an Isotope of each element with more neutrons than protons. So i displayed the neutrons in the isotope as being just a bit larger than the proton bundle. This image is physically a better representation of the properties we observe in heavy elements than the image with the single bundle of dots suggesting Iron-52 has 52 separate little bits stuck together.

John.

To me your pictures strongly represent a couple of important features of the nucleus, but also tend to misrepresent other features.

Good: right away it represents weight vs size very visually and I think it also gives the idea of about the same number (or more) of neutrons then protons.

Not good: for small numbers of neutrons and protons (less then 20) the size rule (relative to cube of mass) is not correct.

Not good: it seems to imply some sort of "compartment" for the protons and neutrons being separated that way, in fact the strong force applies to each proton and neutron individually and mixing them together (as the picture in the 1st post) more strongly suggests that in a visual way.

Currently, the only other style that does not seem to evoke too many complaints is the Lewis style of atoms, you often see the nucleus (protons and neutrons and non-valence electrons) as one circle (53 picometers for hydrogen, larger for other atoms). The various circles are shown bound with dots representing the valence electrons.

 

[John37309]

Thank you edguy99 for some constructive scientific criticism, much appreciated!

Good: right away it represents weight vs size very visually and I think it also gives the idea of about the same number (or more) of neutrons then protons

Thanks, that's one of the points i was trying to make. When discussing isotopes in a visual sense, this type of image has benefits. This type of image can also be adapted to more easily explain various decay modes for the nucleus.

Not good: for small numbers of neutrons and protons (less then 20) the size rule (relative to cube of mass) is not correct.

I didn't actually spend time getting the exact scale correct. It was just a quick image to discuss the topic.

Not good: it seems to imply some sort of "compartment" for the protons and neutrons being separated that way, in fact the strong force applies to each proton and neutron individually and mixing them together (as the picture in the 1st post) more strongly suggests that in a visual way.

Yea, maybe. I would disagree with you though. That compartmentalisation is also implied from the big cluster image of the nucleus. The cluster image implies that none of the protons mix together in any way. Same with the neutrons. But in reality, there is no evidence to suggest that in a heavy nucleus, the protons stay separate from each other. Or that the neutrons stay separate from each other. There is evidence to suggest that the wave functions mix together kinda like electron orbital hybridisation.

Currently, the only other style that does not seem to evoke too many complaints is the Lewis style of atoms, you often see the nucleus (protons and neutrons and non-valence electrons) as one circle (53 picometers for hydrogen, larger for other atoms). The various circles are shown bound with dots representing the valence electrons.

Now that's a really good point. Let's take the Lewis structures as an example. Lewis structures have nothing what-so-ever to do with reality. But they are a really great way to explain what's happening with molecules in chemistry. So i guess that's really the point I'm making here. My type of drawing can be good for explaining some things, but not others.

Thanks for the feedback edguy99,
John.

 

[Drakkith]

Yea, maybe. I would disagree with you though. That compartmentalisation is also implied from the big cluster image of the nucleus. The cluster image implies that none of the protons mix together in any way. Same with the neutrons. But in reality, there is no evidence to suggest that in a heavy nucleus, the protons stay separate from each other. Or that the neutrons stay separate from each other. There is evidence to suggest that the wave functions mix together kinda like electron orbital hybridisation.

What do you mean no evidence? I could have swore the like charges of electrons greatly affect their orbitals, and similarly the like charges of protons greatly affect their positions or orbitals in the nucleus.

Now that's a really good point. Let's take the Lewis structures as an example. Lewis structures have nothing what-so-ever to do with reality. But they are a really great way to explain what's happening with molecules in chemistry. So i guess that's really the point I'm making here. My type of drawing can be good for explaining some things, but not others.

Thanks for the feedback edguy99,
John.

The fact that your drawing can be good at certain things was never in question. I think it is fine depending on who your target audience is and what it is trying to explain.

 

[BruceW]

I just made a picture to represent the Woods-Saxon potential, which gives an empirical potential describing the nucleus. The basic idea is that the deeper the potential, the more likely the nucleons are to be there. The potential is deepest in the middle of the nucleus, (where its whiter), so nucleons are more likely to be in the centre.
This is probably the most scientifically accurate picture of the nucleus I have heard of. Hopefully the picture uploads correctly.

 

[John37309]

I just made a picture to represent the Woods-Saxon potential, which gives an empirical potential describing the nucleus. The basic idea is that the deeper the potential, the more likely the nucleons are to be there. The potential is deepest in the middle of the nucleus, (where its whiter), so nucleons are more likely to be in the centre.
This is probably the most scientifically accurate picture of the nucleus I have heard of. Hopefully the picture uploads correctly.

Bruce,
It kinda looks like the way people are currently drawing the electron, kinda like a cloud, as opposed to a solid particle that is orbiting at high speed. I would give that image quite high merit. I like the line of thought that suggests atoms, electrons, and even the quarks inside them are just wavy energy clouds. I like it!

John.

 

[BruceW]

Thanks, I guess the difficulty is that you can either describe the potential of the nucleus in general, or talk about what each particle is doing individually, but it's not easy to draw a picture which explains both of them..

 

[John37309]

Thanks, I guess the difficulty is that you can either describe the potential of the nucleus in general, or talk about what each particle is doing individually, but it's not easy to draw a picture which explains both of them..

Yep, that's very true Bruce! Its a good picture, it does explain many properties of a nucleus!

There are billions of Iron atoms in an iron bar you buy in your hardware store. But its looks and acts like an Iron bar, it has the properties of an Iron bar, so we draw it as an Iron bar.

John.

 

[danR]

Bruce,
It kinda looks like the way people are currently drawing the electron, kinda like a cloud, as opposed to a solid particle that is orbiting at high speed. I would give that image quite high merit. I like the line of thought that suggests atoms, electrons, and even the quarks inside them are just wavy energy clouds. I like it!

John.

I suspect this is a picture of a potential, a probability, of where a nucleon may be found, rather than a picture or depiction of what a nucleus looks like.

Regarding the electron cloud-pictures: they are not intended to imply that electrons have cloud-like or 'wavy' structure (they may, who knows, but that's not what they are intended to show); the shading indicates the degree of probability that an electron may be somewhere, or other.

 

[danR]

I hope you don't take some of the comments that have been presented too harshly, but the way (pictorially and verbally) you are presenting your theory is extremely common. And very baffling to unravel for experts. I don't mean your theory itself. I mean the way you explain it. They see this sort of presentation hundreds, even thousands of times, and each time they have to go through the same wearisome steps to understand it, explain why it is probably inaccurate, and too often explain that it doesn't really mean anything all.

So people get frustrated.

 

[John37309]

Dan,
i do like a good scientific debate, its productive. I'm not put off at all by peoples comments. If everyone patted you on the back for great suggestions, then science would be no fun.

John.

 

[edguy99]

... When discussing isotopes in a visual sense, this type of image has benefits. This type of image can also be adapted to more easily explain various decay modes for the nucleus.

I like this one, as it more properly models the binding forces and conveys the idea of coupled protons and neutrons (they don't contribute to spin). Basically these are layers of protons (blue) separated by neutron layers (grey). The only rule is you must have an insulating neutron between any two protons and the proton starts at the top (http://www.animatedphysics.com/element_spin.jpg" ).

 

[danR]

Dan,
i do like a good scientific debate, its productive. I'm not put off at all by peoples comments. If everyone patted you on the back for great suggestions, then science would be no fun.

John.

It's best to leave the debating part of science theory to specialists. I was in a science for liberal arts course at the university here, and often, because I have a very curious and active mind, would talk a lot, and question and dispute things. The prof had a mixed blessing: a non-major that actually had keen interest in physics, but often had too much to say, and too little knowledge.

It is also almost certainly true that the past century has never seen any fundamental physics contribution from an intelligent layperson. You only have to type "nucleus" "nucleon" into Google scholar, and look at the sheer mountain of very imposing documents, papers, dissertations. It's not like you're in the deep end of the pool, you're in the Mariana trench. If people will excuse me for this small Google sample from some 110,000 entries:

Coupling effects in the elastic scattering of the exotic nucleus 6He on protons
[PDF] from cea.frV Lapoux, N Alamanos, F Auger, Y Blumenfeld… - Physics Letters B, 2001 - Elsevier

... Nucleus–nucleon elastic scattering can be described using the complex microscopic
JLM potential [6] which only depends on the scattering energy and on the neutron
and proton densities of the nucleus. The potential is deduced ...
Cited by 45 - Related articles - Get at CISTI - All 17 versions

Nucleon-nucleus optical-model parameters, A> 40, E< 50 MeV
FD Becchetti Jr… - Physical Review, 1969 - APS
Proton-nucleus and neutron-nucleus standard optical-model parameters are given that
represent, quite well, much of the elastic scattering data in the range A>40, E<50 MeV. These
parameters were determined by fitting simultaneously a large sample of the available ...
Cited by 951 - Related articles - All 4 versions

Projectile Fragmentation of the Extremely Neutron-Rich Nucleus^{11} Li at 0.79 GeV/nucleon
T Kobayashi, O Yamakawa, K Omata… - Physical Review Letters, 1988 - APS
Projectile fragmentations of 11 Li, 8 He, and 6 He have been measured at 0.79
GeV/nucleon. Production cross sections and momentum distributions of the produced isotopes
(Z≥2) are measured inclusively. Transverse-momentum distributions of 9 Li from the ...
Cited by 343 - Related articles - All 5 versions

Gluon production in current-nucleus and nucleon-nucleus collisions in a quasi-classical approximation* 1
[PDF] from arxiv.orgYV Kovchegov… - Nuclear Physics B, 1998 - Elsevier
We calculate gluon production in deep inelastic scattering of the current off a large nucleus and
in nucleon-nucleus collisions. In a covariant gauge calculation the transverse momentum spectrum
of the gluon is determined by the final state interactions of the gluon with the nucleons in ...
Cited by 329 - Related articles - Get at CISTI - All 6 versions

Dirac-Equation Impulse Approximation for Intermediate-Energy Nucleon-Nucleus Scattering
BC Clark, S Hama, RL Mercer, L Ray… - Physical Review Letters, 1983 - APS
In this application of Dirac phenomenology a relativistic impulse approximation is used to describe
proton-nucleus elastic scattering at intermediate energies. The results demonstrate the superiority
of this relativistic treatment over the nonrelativistic impulse approximation, especially with ...
Cited by 271 - Related articles - All 4 versions

 

[SpectraCat]

I like this one, as it more properly models the binding forces and conveys the idea of coupled protons and neutrons (they don't contribute to spin). Basically these are layers of protons (blue) separated by neutron layers (grey). The only rule is you must have an insulating neutron between any two protons and the proton starts at the top (http://www.animatedphysics.com/element_spin.jpg" ).

I don't think it explains all that much ... it is just intended to help understand the microstates arising from spin coupling. For example, why aren't the spins of the lower two neutrons in lithium-7 paired? I also don't understand what you mean by "more properly models the binding forces".

 

[edguy99]

I don't think it explains all that much ... it is just intended to help understand the microstates arising from spin coupling. For example, why aren't the spins of the lower two neutrons in lithium-7 paired? I also don't understand what you mean by "more properly models the binding forces".

They don't have a proton line between them. Do you use any visual image in your mind to remember nuclear spin?

I mean by "more properly models the binding forces" that it helps you remember for instance that Helium4 is very tightly bound whereas other isotopes are less well bound - bond strength for one proton and one neutron (Hydrogen2) is about 1.1 MeV, Helium4 bond strength is almost 30 MeV (over 7 MeV per nucleon).

 

[SpectraCat]

They don't have a proton line between them. Do you use any visual image in your mind to remember nuclear spin?

No, I don't think that has anything to do with it. I think they are unpaired because they are fermions in degenerate energy levels, according to the nuclear shell model. The usual rules for populating such states is to put one fermion in each degenerate state before pairing any of them .. this is because there is an energy penalty associated with pairing them. This is definitely how electrons are added to atomic and molecular states (Hund's rule of maximum multiplicity), however I am not certain that this is the case for nucleons.

I mean by "more properly models the binding forces" that it helps you remember for instance that Helium4 is very tightly bound whereas other isotopes are less well bound - bond strength for one proton and one neutron (Hydrogen2) is about 1.1 MeV, Helium4 bond strength is almost 30 MeV (over 7 MeV per nucleon).

Right, but that has more to do with the shell model than the spin-pairing. Helium is so much more stable because it has a completely filled shell for both protons and neutrons.