photoelectrical Sentence Examples

  1. The photoelectrical effect demonstrates the emission of electrons from a metal surface when exposed to light.
  2. Albert Einstein's theory of the photoelectrical effect revolutionized our understanding of light and matter.
  3. Photoelectrical cells, also known as solar cells, convert light energy into electrical energy through the photoelectrical effect.
  4. The photoelectrical response of a material is determined by its bandgap energy, which is the energy difference between its valence and conduction bands.
  5. Photoelectrical devices, such as photodiodes and phototransistors, are widely used in light detection and sensing applications.
  6. The photoelectrical efficiency of a solar cell measures its ability to convert light energy into electrical energy.
  7. Photoelectrical spectroscopy involves analyzing the absorption or emission of light by a material to determine its electronic structure.
  8. Photoelectrical imaging techniques, such as photoluminescence microscopy, provide valuable information about the spatial distribution of electronic states in materials.
  9. The photoelectrical properties of nanomaterials have unique features due to their small size and quantum effects.
  10. Advances in photoelectrical technology have led to the development of various applications, ranging from photovoltaic systems to light-emitting diodes.

photoelectrical Meaning

Wordnet

photoelectrical (a)

of or pertaining to photoelectricity

Synonyms & Antonyms of photoelectrical

No Synonyms and anytonyms found

FAQs About the word photoelectrical

of or pertaining to photoelectricity

No synonyms found.

No antonyms found.

The photoelectrical effect demonstrates the emission of electrons from a metal surface when exposed to light.

Albert Einstein's theory of the photoelectrical effect revolutionized our understanding of light and matter.

Photoelectrical cells, also known as solar cells, convert light energy into electrical energy through the photoelectrical effect.

The photoelectrical response of a material is determined by its bandgap energy, which is the energy difference between its valence and conduction bands.