Electron example sentences

"Electron" Example Sentences

1. Electons are negatively charged subatomic particles that orbit the nucleus of an atom.
2. Electrons can be transferred between atoms via chemical bonds.
3. Electons occupy electron shells in various energy levels within an atom.
4. Electrons possess a small amount of mass and a unit negative electric charge.
5. The number of electrons in an atom determines how chemically reactive that atom is.
6. Electrons can move between energy levels when absorbing or releasing photons of light.
7. Electrons moving through a conductor create electric current.
8. Electrons occupying the outermost electron shell determine an element's chemical properties.
9. Electron beams can be used for imaging, lithography, and microscopy.
10. Electrons were discovered by J.J. Thomson in 1897.
11. Electrons contribute little to an atom's mass but significantly impact its chemical properties.
12. The electron microscope uses electron beams instead of light to achieve much higher resolution.
13. Electron flow through electric circuits is crucial for multiple technologies.
14. Electrons are often studied in particle accelerators like the Large Hadron Collider.
15. Electrons occupy discrete energy levels within an atom's electron cloud.
16. The electron gun produces a beam of electrons used in vacuum tubes and imaging devices.
17. Electron diffraction enables scientists to visualize the geometric structure of molecules.
18. Electron transfer reactions are important in biology and chemistry.
19. Semiconductors function by manipulating the movement of electrons within a material.
20. Electron configuration describes how electrons are arranged around the nucleus of an atom.
21. Electrons can collide with other electrons and change energy levels.
22. The flow of electrons through circuits powers many electrical devices.
23. Photoelectron spectroscopy measures the electron kinetic energy released when photons strike atoms.
24. Electrons form the negative charge that balances out the positive charge of protons.
25. The Pauli exclusion principle dictates that no two electrons in an atom can have the same set of quantum numbers.
26. The emission spectrum of a gas reveals information about the energy levels of its electrons.
27. Electrons occupy orbitals that can hold up to two electrons of opposite spin.
28. Thermionic emission releases electrons from metal surfaces when heated.
29. Electrons are attracted to the positively charged nucleus by the electrostatic coulomb force.
30. The number of valence electrons determines how an element reacts chemically.
31. The external application of an electric field can extract electrons from the surface of a material.
32. Electron defects contribute to the electrical conductivity and color of gemstones.
33. Electron transfer occurs in molecular processes like photosynthesis and cellular respiration.
34. Electron scattering experiments provide information about electron behavior within materials.
35. Electons have wave-particle duality, behaving like both particles and waves.
36. Electrons orbit the nucleus in probabilistic regions known as electron clouds.
37. The accelerating electrons within a transmission electron microscope generate very small wavelengths.
38. Electron delocalization explains how electrons are spread across multiple atoms in molecules.
39. Electron spin leads to either an up or down spin state for individual electrons.
40. Electrons surround the nucleus in a series of probability clouds called orbitals.
41. Electrons emit photons when transitioning between higher and lower energy levels.
42. Electrons interact electromagnetically, moving in response to electric and magnetic fields.
43. Superconductors allow electrons to flow with no electrical resistance below a critical temperature.
44. Electrons occupy atomic and molecular orbitals that determine chemical bonding properties.
45. Electron microscopy enables scientists to visualize objects at the nanoscale.
46. Electron arrangements determine an atom's chemical nature and reactivity.
47. Electron transfer events are crucial steps in many chemical reactions.
48. Electron clouds describe regions where electrons may likely be found around an atomic nucleus.
49. Electron shells denote discrete energy levels where electrons may be located within atoms.
50. Electrons moving through a wire generate magnetic fields that surround the conductor.
51. An electron volt is the unit used to measure electron energy.
52. Free electrons allow electrical current to flow through metallic conductors.
53. When electrons jump to lower orbitals, they release photons of various wavelengths.
54. Electron transitions to higher orbital levels require absorption of photon energy.
55. The outermost electron shells determine how atoms bond with each other in molecules.
56. Electrons possess intrinsic properties like spin, charge and mass.
57. Electron density maps reveal information about electron locations within molecules.
58. Electrons occupy specific energy levels within an atom or molecule that follows rules.
59. Electrons are subatomic particles surrounding the nucleus of an atom in electron clouds.
60. Electron pairs in atoms occupy regions of space described by electron orbital wave functions.

Common Phases

1. The electron travels around the nucleus of an atom.
2. Electrons carry negative electrical charges.
3. The greater the number of electrons in an atom, the greater the atomic number.
4. An atom can gain or lose electrons to create an ionic bond with another atom.
5. Electron microscopy uses a beam of electrons instead of light to observe specimens.
6. Electrons are fundamental subatomic particles that have a negative charge.
7. Electron beams are commonly used for welding and particle acceleration.
8. An electron gun produces a stream of electrons.
9. When electrons jump from a higher to a lower orbital, energy is released.
10. The electron cloud model shows the probabilistic distribution of electrons in an atom.
11. Electrons are counted to determine an element's place in the periodic table.
12. Electrons transfer energy when they jump between orbitals.
13. An electron microscope uses electrons instead of light to view objects up to 10,000 times smaller.
14. Electrons have an average mass of 9.1 x 10^-31 kg.
15. Electron shells occupy different energy levels surrounding the nucleus.
16. When electrons change orbital shells it is called an electronic transition.
17. Electron volt is a unit of energy used to measure electron energy levels.
18. Electron configuration outlines the distribution of electrons into orbitals.
19. Electron shielding occurs when inner electrons block the attraction of outer electrons.
20. An electron gun produces a narrow beam of electrons.
21. Electron microscopes use electrons instead of photons, allowing higher resolution images.
22. Electrons are attracted to the positively charged nucleus of an atom.
23. Electron flow occurs in a direction from negative to positive.
24. Electron pair repulsion causes atoms to form bonds with other atoms.
25. Free electrons can flow as an electric current in metals.
26. Electron paramagnetic resonance detects the absorption of microwave energy by unpaired electrons.
27. Electron configuration depends on atomic number to fill electron shells.
28. Electron clouds become more diffuse as electrons move farther from the nucleus.
29. Electron microscopy allows us to see objects below the resolution limit of visible light.
30. Electrons contribute to conductivity in metals by flowing freely through the material.
31. Electron beam welding uses a concentrated electron beam to join materials.
32. An electron microscope bombards a specimen with electrons instead of light rays.
33. Electron orbitals have specific shapes and orientations depending on energy levels.
34. Electron diffraction uses a beam of electrons to determine atomic structure.
35. Electron scanners detect electrons ejected from materials bombarded with electrons.
36. Electrons move more quickly through a conductor than an insulator.
37. Electron configuration determines chemical properties by the number of valence electrons.
38. Each electron contributes a small negative charge to the atom's overall charge.
39. Electrons occupy discrete energy levels around an atom's nucleus.
40. Low energy electrons can be emitted from a material due to photoelectric effect.
41. An electron stream transports toner particles in a laser printer.
42. Electrons occupy different quantum states described by quantum numbers.
43. Electrons fill higher energy orbitals before lower ones according to Pauli's exclusion principle.
44. Electron spin can be either up or down depending on orientation relative to the magnetic moment.
45. Electron shells hold a specific maximum number of electrons before the next shell begins.
46. Electrons jumping to a lower energy state emit photons of specific frequencies.
47. Electron clouds determine the shape and reactivity of chemical molecules.
48. Electrons occupy orbitals within different electron shells.
49. Excited electrons contribute to an atom's emission spectrum through electronic relaxation.
50. Electrons are responsible for chemical bonds through sharing or transfer between atoms.
51. Electron beams are accelerated using electric and magnetic fields.
52. Electron shells correspond with specific atomic emission spectra.
53. Electrons dissipate excess energy through emission of photons.
54. Electron acceptors gain electrons and become negatively charged.
55. Electron donors lose electrons and become positively charged.
56. Electron emission occurs when electrons leave a material's surface.
57. Electrons exist in quantized energy states described by wavefunctions.
58. Valence electrons determine elemental properties through electron configuration.
59. Heat raises electrons to higher energy levels within an atom.
60. The Coulomb force attracts electrons to the nucleus of an atom.