What are Isobars?
In the year 1918, a British Chemist and a part-time novelist suggested the term isobars (originally isobares) for different atoms having a similar number of nucleons.
Isobars are atoms or nuclides of different elements that contain the same number of nucleons. For example, nuclides of Argon and Calcium bear the same number of nucleons.
In nuclear Physics, the atoms having the same number of nucleons carry a varying number of protons and neutrons.
In this article, we will learn about isobar nuclear Physics and isobar isotone in detail.
What Is Nuclear Physics?
Nuclear physics is one of the well-known branches of Physics that deals with the structure of the atomic nucleus and the radiation emitted from the unstable nuclei. Around 10,000 times smaller than the atom, the constituent particles of the nucleus, protons, and neutrons, attract one another so strongly by the nuclear forces that nuclear energies are approximately 1,000,000 times larger than the normal atomic energies. We need to be thorough with Quantum theory for understanding nuclear structure.
For a subject like nuclear Physics, we have two terms involved in this case, and they are isobars and isotones. In this article, we will understand these two.
Isobar Nuclear Physics
If we talk about elements like Chlorine and Argon; these two elements have the same number of nucleons but they vary in the number of neutrons and protons.
However, if we bring our focus on isobar isotone, isobar varies with isotone because isobar talks of a set of elements having different neutrons, and isotone is the set of elements that have the same number of neutrons.
So, isobar isotone carries a huge difference in their meanings and significance.
Most Stable Nuclide of an Isobar
If A is the mass number of an element and Z is its atomic number, then we have:
M (A, Z) = Z mP + (A - Z) mN - \[\frac{Eb(A,Z)}{C^{2}}\]
At first, for any mass number ‘A’, the most stable nuclide of the isobar is the one with the least mass. However, it should be the one with a proton number Z. Then:
∂M(A, Z) / ∂Z = 0
i.e.,
mP - mN - \[\frac{1}{C^{2}}\left ( \frac{\delta Eb(A,Z)}{\delta Z} \right )=0\]
After searching for the most stable isobar, it was found that isobars have the greatest binding energy, meaning only that Z satisfies and the equation for this statement is as follows:
\[\left ( \frac{\delta Eb(A,Z)}{\delta Z} \right )=0\]
So, our test failed here. This may be because the difference is just a (small) constant, i.e., Z and A. Let us assume that Zm is the value Zm the one obtained by minimizing M and Z is obtained by maximizing E, the graph plotted for the same is as follows:
[Image will be uploaded soon]
Here, Z begins to separate for large A. For example, for
A = 209
Zm (209) = 3.36 ≈ 83, and
ZE (209) = 82.22 ≈ 82
Isotone
Isotone is a term used in nuclear Physics. When two or more species of nuclei or atoms have exactly the same number of neutrons, the two atoms are isotones.
For example, chlorine-37 and potassium-39 are isotones, because the nucleus of chlorine contains 17 protons and 20 neutrons, whereas the nucleus potassium contains 19 protons and 20 neutrons.
So, we conclude that two nuclides are isotones if they have the same number of neutrons but different proton numbers, i.e., Z.
Another example, the nuclei of both Boron-12, and Carbon-13 contain 7 neutrons, and so they are isotones.
Nuclear Physics and Atomic Physics
A basic difference between nuclear and atomic physics is that nuclear physics deals with the nucleus whereas atomic physics deals with an entire atom.
Atomic physics deals with all the properties of atoms, mainly due to their electronic configuration.
On the other end, nuclear Physics deals mainly with nuclei, their properties, structure, reactions, and interactions. In nuclear Physics, atoms make up all the matter in the universe.
After understanding the concepts of quarks and gluons, we can easily understand the forces related to nuclear physics.
We find the application of nuclear physics largely in the field of power generation using nuclear energy. Once the force holding the nucleus is understood, we start performing splitting and fusing neutrons.
The energy evolved during the process can be used in the splitting of the nucleus to generate energy in Nuclear Fission and fusing two neutrons to produce energy is Nuclear Fusion.
Do You Know?
In Meteorology, an isobar is a curve drawn via points of equal pressure. For instance, it can be considered a line joining states of equal pressure in a graph representing all the thermodynamic processes. The term isobar is commonly used in meteorology where an isobar is a curve joining points of equal atmospheric pressure on a given reference surface, for instance, a sea level.
Conclusion
We can see that the atoms having the same number of protons is isotope, while atoms having the same number of neutrons are isotones. It’s just a variation of the alphabet. This is actually the stretching performed by the German physicist K. Guggenheimer.
FAQs on Isobar - Nuclear Physics
1. What are isobars in the context of nuclear physics?
In nuclear physics, isobars are atoms of different chemical elements that have the same number of nucleons. This means they share the same mass number (A) but have a different atomic number (Z). Since the atomic number (number of protons) is different, isobars represent completely different elements.
2. Can you provide some common examples of isobars?
Certainly. Here are a few common examples of isobaric pairs and triplets, showing different elements with the same mass number:
- Carbon-14 (¹⁴C) and Nitrogen-14 (¹⁴N) both have a mass number of 14, but Carbon has 6 protons while Nitrogen has 7.
- The triplet Argon-40 (⁴⁰Ar), Potassium-40 (⁴⁰K), and Calcium-40 (⁴⁰Ca) are all isobars with a mass number of 40. They have 18, 19, and 20 protons, respectively.
3. What is the key difference between isotopes, isobars, and isotones?
These terms describe relationships between different nuclides based on their subatomic particles. The key differences are:
- Isotopes: Atoms of the same element that have the same number of protons (same Z) but a different number of neutrons, resulting in a different mass number (A). For example, Carbon-12 and Carbon-14.
- Isobars: Atoms of different elements that have the same mass number (same A) but a different number of protons (different Z). For example, Argon-40 and Calcium-40.
- Isotones: Atoms of different elements that have a different number of protons (different Z) but the same number of neutrons. For example, Chlorine-37 (20 neutrons) and Potassium-39 (20 neutrons).
4. Why do isobars have different chemical properties despite having the same mass number?
Chemical properties are almost entirely determined by an atom's electron configuration, which dictates how it bonds with other atoms. The number of electrons in a neutral atom is equal to its number of protons, which is the atomic number (Z). Since isobars, by definition, have different atomic numbers, they are different elements with different electron configurations. Therefore, they exhibit distinct chemical properties. The mass number (A) primarily influences nuclear properties like stability and radioactive decay, not chemical reactivity.
5. How can two different elements be isobars of each other?
This is possible because an element's identity is defined solely by its atomic number (Z), the number of protons in its nucleus. The mass number (A), however, is the sum of protons and neutrons. Two atoms can have the same mass number while being different elements if they have a complementary number of protons and neutrons. For instance, Argon-40 has 18 protons and 22 neutrons (18+22=40), while Calcium-40 has 20 protons and 20 neutrons (20+20=40). Both sum to 40, making them isobars.
6. Are the nuclei of isobars equally stable?
No, the nuclei of isobars are generally not equally stable. Nuclear stability is highly dependent on the neutron-to-proton (N/Z) ratio and the binding energy per nucleon. Since isobars have different numbers of protons and neutrons, their N/Z ratios differ. Often, for a given mass number, only one or two isobaric forms are stable, while the others are radioactive. These unstable isobars undergo beta decay or electron capture to transform into a more stable nucleus with a better N/Z ratio.
