Yes, protons on opposite sides of a large nucleus are attracted to each other due to the strong nuclear force.
The electron has a negative charge, so it would attract and be attracted by particles of opposite/unlike charge (positive charge) such as protons.
Protons, which have positive charge, attract electrons, which have negative charge. Also, quarks with positive charge attract quarks with negative charge. (Actually, it is this electric charge which defines the properties of the particle they make up. A proton has more quarks with positive charges than with negative charges, for example.)
The electrical forces inside a nucleus contribute to the nuclear force, also known as the strong nuclear force. This force is responsible for binding protons and neutrons together in the nucleus. It overcomes the electrical repulsion between positively charged protons to hold the nucleus together.
The force that holds protons in the nucleus is called the strong nuclear force. It is one of the four fundamental forces of nature and is responsible for binding protons and neutrons together in atomic nuclei.
The main components of the nucleus are the nucleolus, chromatin (DNA and associated proteins), nuclear envelope, and nuclear pores. The nucleolus is involved in ribosome production, chromatin contains the genetic material, the nuclear envelope is a double membrane that encloses the nucleus, and nuclear pores allow for the exchange of materials with the cytoplasm.
The strong nuclear force acts only on neutrons and protons in the nucleus of an atom. The opposite would be a weak nuclear force.
The electron has a negative charge, so it would attract and be attracted by particles of opposite/unlike charge (positive charge) such as protons.
ELECTRONS AND PROTONS ARE ATTRACTED TO EACH OTHER. THEY ARE OPPOSITE CHARGES. OPPOSITE CHARGES ATTRACT. IT IS LIKE FORCES THAT DO NOT ATTRACT EACH OTHER. I AM NOT SURE IF IT IS IN THE NUCLEUS THAT THEY ATTRACT. BUT I DO KNOW THAT ELECTRONS ARE ON THE OUTSIDE OF THE NUCLEUS. PROTONS ARE ON THE INSIDE. I REALLY HOPE THIS ANSWERS YOUR QUESTION:)
The nuclear charge of a nucleus of P-32 is +32 because the nuclear charge is always the amount of protons in the nucleus.
The strong nuclear force acts only on neutrons and protons in the nucleus of an atom. The opposite would be a weak nuclear force.
Electrons are not part of the nucleus, but they orbit the protons there because protons and electrons have opposite electrical charges.
Protons and neutrons are normally bound within the nucleus by the strong nuclear force. However, they can be ejected from the nucleus in processes like radioactive decay or nuclear fission.
It is because both of them are oppositively charged particles. Since a proton is a positively charged particle and an electron is a negatively charged particle, hence they both develop an electrostatic force of attraction.
Protons, which have positive charge, attract electrons, which have negative charge. Also, quarks with positive charge attract quarks with negative charge. (Actually, it is this electric charge which defines the properties of the particle they make up. A proton has more quarks with positive charges than with negative charges, for example.)
The nucleus of an atom is the part that takes part in nuclear reactions. It consists of protons and neutrons, which are involved in processes such as fission and fusion. The electrons surrounding the nucleus are not typically involved in nuclear reactions.
When they're very, very close together. Protons and neutrons are not attracted to each other electromagnetically, as neutrons have no electronic charge.Protons and electrons are, as one has a positive and one has a negative charge.Instead, Protons and Neutrons are held together in the nuclei of atoms by the Strong Nuclear Force. The strong force (also called the color force) is the strongest of the four basic forces, but it's only important over extremely short ranges.
They are attracted to each other due to the strong nuclear force, which is far stronger than the electro-magnetic force.