Sfrgttk

Dealing with an internal ScriptKiddie

How can guns be countered by melee combat without raw-ability or exceptional explanations?

Color of alien seas

Can you say "leftside right"?

How to regain lost focus?

What if I miss a connection and don't have money to book next flight?

Why can all solutions to the simple harmonic motion equation be written in terms of sines and cosines?

Taking an academic pseudonym?

Was Opportunity's last message to Earth "My battery is low and it's getting dark"?

How can I give a Ranger advantage on a check due to Favored Enemy without spoiling the story for the player?

Why do single electrical receptacles exist?

Does Plato's "Ring of Gyges" have a corrupting influence on its wearer?

How can changes in personality/values of a person who turned into a vampire be explained?

In the Lost in Space intro why was Dr. Smith actor listed as a special guest star?

show notifications of new e-mails without displaying the content

Players preemptively rolling, even though their rolls are useless or are checking the wrong skills

Is there a way to pause a running process on Linux systems and resume later?

Isn't a semicolon (';') needed after a function declaration in C++?

Using time travel without creating plot holes

Is the percentage symbol a constant?

What is formjacking?

How to know if I am a 'Real Developer'

What does an unprocessed RAW file look like?

What can I do to encourage my players to use their consumables?

What happens to the first ionization potential when a hydrogen-like atom captures a particle?

How can difference in neutron number cause a difference in ionisation enthalpies?Finding orbit radius using the Bohr model and Rydberg equationWhy is the common magnesium ion Mg(II) and not Mg(I) when the second ionization energy is higher than the first ionization energy?What is the element with the greatest first ionization energy?Charge-transfer absorption complex - solvent sensitivityIs the first ionization energy in oxygen slightly more than nitrogen?For hydrogen like atom, find velocity from potential energyIs the energy of the orbital an electron “resides” in, considered to be a factor of that electrons ionization energy?Constructing two body Hamiltonian for Helium atom in hydrogen slater orbitals single particle basisWhat is the real structure of atom showing every ORBITALWhat is the exact definition of the radial distribution function?

2

$begingroup$

This is a textbook problem from Resonance DLPD Physical Chemistry, Page #83:

The mass of a proton is $1836$ times the mass of an electron. If a subatomic particle of mass $207$ times the mass of an electron is captured by the nucleus, what happens to the first ionization potential of H?

My answer is that it may either increase or decrease depending on the charge of the captured particle.

However, the correct answer according to my book is that the ionization potential increases.

How do I arrive at this solution?

physical-chemistry ionization-energy atomic-structure

share|improve this question

asked 2 hours ago

user69284user69284

434

$endgroup$

• 
  
  
  

  
  1
  

  
  
  
  
  
  

  
  $begingroup$
  Energy of the $n^{th}$ state (simply by Bohr's model) can be found as, $E_n = - frac{me^4Z^2}{8 epsilon_0 ^2 n^2h^2}$. Now you can apply your logic and judge the final answer.
  $endgroup$
  – Soumik Das
  1 hour ago
  
  
  

  
  
  
  

add a comment | 

2

$begingroup$

This is a textbook problem from Resonance DLPD Physical Chemistry, Page #83:

The mass of a proton is $1836$ times the mass of an electron. If a subatomic particle of mass $207$ times the mass of an electron is captured by the nucleus, what happens to the first ionization potential of H?

My answer is that it may either increase or decrease depending on the charge of the captured particle.

However, the correct answer according to my book is that the ionization potential increases.

How do I arrive at this solution?

physical-chemistry ionization-energy atomic-structure

share|improve this question

asked 2 hours ago

user69284user69284

434

$endgroup$

• 
  
  
  

  
  1
  

  
  
  
  
  
  

  
  $begingroup$
  Energy of the $n^{th}$ state (simply by Bohr's model) can be found as, $E_n = - frac{me^4Z^2}{8 epsilon_0 ^2 n^2h^2}$. Now you can apply your logic and judge the final answer.
  $endgroup$
  – Soumik Das
  1 hour ago
  
  
  

  
  
  
  

add a comment | 

$begingroup$

This is a textbook problem from Resonance DLPD Physical Chemistry, Page #83:

The mass of a proton is $1836$ times the mass of an electron. If a subatomic particle of mass $207$ times the mass of an electron is captured by the nucleus, what happens to the first ionization potential of H?

My answer is that it may either increase or decrease depending on the charge of the captured particle.

However, the correct answer according to my book is that the ionization potential increases.

How do I arrive at this solution?

physical-chemistry ionization-energy atomic-structure

share|improve this question

asked 2 hours ago

user69284user69284

434

$endgroup$

share|improve this question

asked 2 hours ago

user69284user69284

434

share|improve this question

asked 2 hours ago

user69284user69284

434

asked 2 hours ago

user69284user69284

434

asked 2 hours ago

user69284user69284

434

1 Answer
1

active

oldest

votes

2

$begingroup$

When we solve the Schrodinger equation for the hydrogen atom we general make the simplifying assumption that the proton stays fixed and the electron moves in the potential of the fixed positive charge. So when we write, for example, the $1s$ orbital as:

$$ psi_{1s} = frac{2}{a_o^{3/2}} e^{-r/a_0} tag{1} $$

the variable $r$ is the distance from the proton, and in the equation for the Bohr radius:

$$ a_0 = frac{hbar^2}{me^2} tag{2} $$

The $m$ is the mass of the electron. If you're interested in some detail this is discussed on the Physics SE in Reduced mass in quantum physics (Hydrogen Atom) but taking into account the motion of the hydrogen atom turns out to be surprisingly simple. We simply define $r$ to be the distance to the centre of mass of the atom, and the mass $m$ then becomes the reduced mass of the electron-proton system:

$$ m = frac{m_e m_p}{m_e + m_p} tag{3} $$

If we take the limit of $m_p to infty$ then the reduced mass just becomes the electron mass $m_e$, but for finite $m_p$ the reduced mass is less than $m_e$.

Given all this you can now see what the question is getting at. If the proton captures a neutral particle of mass $207m_e$ the effect is to increase the mass of the proton. This increases the mass $m_p$ we have to put in to equation (3) so it increases the reduced mass in equation (2) and hence the wavefunction (1). The end result is that in the equation for the ionisation energy:

$$ I = frac{me^4}{8 epsilon_0 ^2 n^2h^2} tag{4} $$

the reduced mass $m$ is increased slightly so the ionisation energy increases slightly.

A good example of this is to compare the ionisation energies of hydrogen, deuterium and tritium, where the increased nuclear mass of deuterium and tritium increase the ionisation energy by the mechanism discussed above. In fact there is an existing quesion discussing exactly this: How can difference in neutron number cause a difference in ionisation enthalpies?

share|improve this answer

answered 1 hour ago

John RennieJohn Rennie

1,422918

$endgroup$

add a comment | 

Your Answer

StackExchange.ifUsing("editor", function () {
return StackExchange.using("mathjaxEditing", function () {
StackExchange.MarkdownEditor.creationCallbacks.add(function (editor, postfix) {
StackExchange.mathjaxEditing.prepareWmdForMathJax(editor, postfix, [["$", "$"], ["\\(","\\)"]]);
});
});
}, "mathjax-editing");

StackExchange.ready(function() {
var channelOptions = {
tags: "".split(" "),
id: "431"
};
initTagRenderer("".split(" "), "".split(" "), channelOptions);

StackExchange.using("externalEditor", function() {
// Have to fire editor after snippets, if snippets enabled
if (StackExchange.settings.snippets.snippetsEnabled) {
StackExchange.using("snippets", function() {
createEditor();
});
}
else {
createEditor();
}
});

function createEditor() {
StackExchange.prepareEditor({
heartbeatType: 'answer',
autoActivateHeartbeat: false,
convertImagesToLinks: false,
noModals: true,
showLowRepImageUploadWarning: true,
reputationToPostImages: null,
bindNavPrevention: true,
postfix: "",
imageUploader: {
brandingHtml: "Powered by u003ca class="icon-imgur-white" href="https://imgur.com/"u003eu003c/au003e",
contentPolicyHtml: "User contributions licensed under u003ca href="https://creativecommons.org/licenses/by-sa/3.0/"u003ecc by-sa 3.0 with attribution requiredu003c/au003e u003ca href="https://stackoverflow.com/legal/content-policy"u003e(content policy)u003c/au003e",
allowUrls: true
},
onDemand: true,
discardSelector: ".discard-answer"
,immediatelyShowMarkdownHelp:true
});


}
});

draft saved

draft discarded

Sign up or log in

StackExchange.ready(function () {
StackExchange.helpers.onClickDraftSave('#login-link');
});

Sign up using Google

Sign up using Facebook

Sign up using Email and Password

Post as a guest

Name

Email

Required, but never shown

StackExchange.ready(
function () {
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fchemistry.stackexchange.com%2fquestions%2f110000%2fwhat-happens-to-the-first-ionization-potential-when-a-hydrogen-like-atom-capture%23new-answer', 'question_page');
}
);

Post as a guest

Name

Email

Required, but never shown

2

$begingroup$

When we solve the Schrodinger equation for the hydrogen atom we general make the simplifying assumption that the proton stays fixed and the electron moves in the potential of the fixed positive charge. So when we write, for example, the $1s$ orbital as:

$$ psi_{1s} = frac{2}{a_o^{3/2}} e^{-r/a_0} tag{1} $$

the variable $r$ is the distance from the proton, and in the equation for the Bohr radius:

$$ a_0 = frac{hbar^2}{me^2} tag{2} $$

The $m$ is the mass of the electron. If you're interested in some detail this is discussed on the Physics SE in Reduced mass in quantum physics (Hydrogen Atom) but taking into account the motion of the hydrogen atom turns out to be surprisingly simple. We simply define $r$ to be the distance to the centre of mass of the atom, and the mass $m$ then becomes the reduced mass of the electron-proton system:

$$ m = frac{m_e m_p}{m_e + m_p} tag{3} $$

If we take the limit of $m_p to infty$ then the reduced mass just becomes the electron mass $m_e$, but for finite $m_p$ the reduced mass is less than $m_e$.

Given all this you can now see what the question is getting at. If the proton captures a neutral particle of mass $207m_e$ the effect is to increase the mass of the proton. This increases the mass $m_p$ we have to put in to equation (3) so it increases the reduced mass in equation (2) and hence the wavefunction (1). The end result is that in the equation for the ionisation energy:

$$ I = frac{me^4}{8 epsilon_0 ^2 n^2h^2} tag{4} $$

the reduced mass $m$ is increased slightly so the ionisation energy increases slightly.

A good example of this is to compare the ionisation energies of hydrogen, deuterium and tritium, where the increased nuclear mass of deuterium and tritium increase the ionisation energy by the mechanism discussed above. In fact there is an existing quesion discussing exactly this: How can difference in neutron number cause a difference in ionisation enthalpies?

share|improve this answer

answered 1 hour ago

John RennieJohn Rennie

1,422918

$endgroup$

add a comment | 

2

$begingroup$

When we solve the Schrodinger equation for the hydrogen atom we general make the simplifying assumption that the proton stays fixed and the electron moves in the potential of the fixed positive charge. So when we write, for example, the $1s$ orbital as:

$$ psi_{1s} = frac{2}{a_o^{3/2}} e^{-r/a_0} tag{1} $$

the variable $r$ is the distance from the proton, and in the equation for the Bohr radius:

$$ a_0 = frac{hbar^2}{me^2} tag{2} $$

The $m$ is the mass of the electron. If you're interested in some detail this is discussed on the Physics SE in Reduced mass in quantum physics (Hydrogen Atom) but taking into account the motion of the hydrogen atom turns out to be surprisingly simple. We simply define $r$ to be the distance to the centre of mass of the atom, and the mass $m$ then becomes the reduced mass of the electron-proton system:

$$ m = frac{m_e m_p}{m_e + m_p} tag{3} $$

If we take the limit of $m_p to infty$ then the reduced mass just becomes the electron mass $m_e$, but for finite $m_p$ the reduced mass is less than $m_e$.

Given all this you can now see what the question is getting at. If the proton captures a neutral particle of mass $207m_e$ the effect is to increase the mass of the proton. This increases the mass $m_p$ we have to put in to equation (3) so it increases the reduced mass in equation (2) and hence the wavefunction (1). The end result is that in the equation for the ionisation energy:

$$ I = frac{me^4}{8 epsilon_0 ^2 n^2h^2} tag{4} $$

the reduced mass $m$ is increased slightly so the ionisation energy increases slightly.

A good example of this is to compare the ionisation energies of hydrogen, deuterium and tritium, where the increased nuclear mass of deuterium and tritium increase the ionisation energy by the mechanism discussed above. In fact there is an existing quesion discussing exactly this: How can difference in neutron number cause a difference in ionisation enthalpies?

share|improve this answer

answered 1 hour ago

John RennieJohn Rennie

1,422918

$endgroup$

add a comment | 

$begingroup$

When we solve the Schrodinger equation for the hydrogen atom we general make the simplifying assumption that the proton stays fixed and the electron moves in the potential of the fixed positive charge. So when we write, for example, the $1s$ orbital as:

$$ psi_{1s} = frac{2}{a_o^{3/2}} e^{-r/a_0} tag{1} $$

the variable $r$ is the distance from the proton, and in the equation for the Bohr radius:

$$ a_0 = frac{hbar^2}{me^2} tag{2} $$

The $m$ is the mass of the electron. If you're interested in some detail this is discussed on the Physics SE in Reduced mass in quantum physics (Hydrogen Atom) but taking into account the motion of the hydrogen atom turns out to be surprisingly simple. We simply define $r$ to be the distance to the centre of mass of the atom, and the mass $m$ then becomes the reduced mass of the electron-proton system:

$$ m = frac{m_e m_p}{m_e + m_p} tag{3} $$

If we take the limit of $m_p to infty$ then the reduced mass just becomes the electron mass $m_e$, but for finite $m_p$ the reduced mass is less than $m_e$.

Given all this you can now see what the question is getting at. If the proton captures a neutral particle of mass $207m_e$ the effect is to increase the mass of the proton. This increases the mass $m_p$ we have to put in to equation (3) so it increases the reduced mass in equation (2) and hence the wavefunction (1). The end result is that in the equation for the ionisation energy:

$$ I = frac{me^4}{8 epsilon_0 ^2 n^2h^2} tag{4} $$

the reduced mass $m$ is increased slightly so the ionisation energy increases slightly.

A good example of this is to compare the ionisation energies of hydrogen, deuterium and tritium, where the increased nuclear mass of deuterium and tritium increase the ionisation energy by the mechanism discussed above. In fact there is an existing quesion discussing exactly this: How can difference in neutron number cause a difference in ionisation enthalpies?

share|improve this answer

answered 1 hour ago

John RennieJohn Rennie

1,422918

$endgroup$

share|improve this answer

answered 1 hour ago

John RennieJohn Rennie

1,422918

answered 1 hour ago

John RennieJohn Rennie

1,422918

answered 1 hour ago

John RennieJohn Rennie

1,422918