O mnie
- Albania
- Dołączył 9 miesięcy temu
- academic
374
Jednostki tłumaczeniowe
0
Terminy
Główne dziedziny specjalizacji
electrical engineering
electronics
engineering (electrical)
Moje dokumenty
Przykładowe tłumaczenie Electrical Engineering
Engineering (Electrical) Przykładowe tłumaczenie
Tekst źródłowy (English) | Tekst docelowy (English) |
---|---|
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutrons. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Protons have a positive charge, Electrons have a negative charge that cancels the proton's positive charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Neutrons are particles that are similar to a proton but have a neutral charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
There are no differences between positive and negative charges except that particles with the same charge repel each other and particles with opposite charges attract each other. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
If a solitary positive proton and negative electron are placed near each other they will come together to form a hydrogen atom. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
This repulsion and attraction (force between stationary charged particles) is known as the Electrostatic Force and extends theoretically to infinity, but is diluted as the distance between particles increases. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
When an atom has one or more missing electrons it is left with a positive charge, and when an atom has at least one extra electron it has a negative charge. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Having a positive or a negative charge makes an atom an ion. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Atoms only gain and lose protons and neutrons through fusion, fission, and radioactive decay. | Source Target Atoms, the smallest particles of matter that retain the properties of the matter, are made of protons, electrons, and neutron |
Although atoms are made of many particles and objects are made of many atoms, they behave similarly to charged particles in terms of how they repel and attract. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
In an atom the protons and neutrons combine to form a tightly bound nucleus. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The cloud exists as a series of overlapping shells / bands in which the inner valence bands are filled with electrons and are tightly bound to the atom. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
The outer conduction bands contain no electrons except those that have accelerated to the conduction bands by gaining energy. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
With enough energy an electron will escape an atom (compare with the escape velocity of a space rocket). | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
When an electron in the conduction band decelerates and falls to another conduction band or the valence band a photon is emitted. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
This is known as the photoelectric effect. | This nucleus is surrounded by a vast cloud of electrons circling it at a distance but held near the protons by electromagnetic attraction (the electrostatic force discussed earlier). |
Albania
dostępny/a Dzisiaj
November 2024
Sun. | Mon. | Tues. | Wed. | Thurs. | Fri. | Sat. |
---|---|---|---|---|---|---|
27
|
28
|
29
|
30
|
31
|
1
|
2
|
3
|
4
|
5
|
6
|
7
|
8
|
9
|
10
|
11
|
12
|
13
|
14
|
15
|
16
|
17
|
18
|
19
|
20
|
21
|
22
|
23
|
24
|
25
|
26
|
27
|
28
|
29
|
30
|
Ostatnia aktywność
Przetłumaczył(a) 374 jednostek/ki tłumaczeniowych/e
z dziedzin: engineering (electrical), electronics and electrical engineering
Feb 27, 2024