The length of each wave is 299,792,458 meters/the frequency of the wave .
The line spectrum is usually used to sort out the atomic fingerprint as the gas emit light at very specific frequencies when exposed to the electromagnetic waves. The electromagnetic waves are usually displayed in form of the spectral lines.
Their wavelength (or frequency), the energy carried by each photon, and the names we give them. Their speeds are all the same.
Why electromagnetic waves of course. These are waves that require no material medium for their propagation, but instead propagate by the cyclic exchange of energy between their electrical and magnetic fields (which for a given wave are always polarized perpendicular to each other, as shown in the image above).The spectrum of electromagnetic waves is continuous with no gaps and spans a potential range of wavelengths from as small as roughly the diameter of protons and neutrons to almost as large as the known universe. Different bands within this spectrum interact with matter in different ways, have been given different names by humans, and some of these bands are used by humans for a variety of different purposes (e.g. communication, RADAR, cooking, heating, vision, medical).
by electric and magnetic to move each other
The only part of the electromagnetic spectrum that we can see is the small yet significant part of visible light. Visible light is not harmful for humans, but some of the other types of waves are.
Electromagnetic waves are classified according to their wavelength and frequency and this classification is called electromagnetic spectrum.
It depends what you are talking about... Electromagnetic field Electromagnetic force Electromagnetic radiation Electromagnetic spectrum Electromagnetic therapy Electromagnetic waves ...they each have different meanings.
Frequency. Electromagnetic waves are just magnetic waves that are turning into electric waves. The faster they turn in to each other, the more energy and high up on the spectrum they are.
Sound waves and electromagnetic waves are different. Sound is composed of density waves in the air or some other form of matter. Sound is a mechanical compression-rarefaction wave. The different types of electromagnetic waves are gamma rays, X-rays, ultraviolet rays, visible light, infrared radiation, microwaves, and radio waves.
It goes from longer waves, to shorter waves. Another words Low Frequency to High frequency. I'm not quite sure how to explain how they EACH as and individual wave work.
The line spectrum is usually used to sort out the atomic fingerprint as the gas emit light at very specific frequencies when exposed to the electromagnetic waves. The electromagnetic waves are usually displayed in form of the spectral lines.
Their wavelength (or frequency), the energy carried by each photon, and the names we give them. Their speeds are all the same.
In a vacuum, electromagnetic waves from all parts of the electromagnetic spectrum can indeed propagate. Unlike mechanical waves, such as sound waves, which require a medium (like air, water, or solids) to travel through, electromagnetic waves do not require a medium and can travel through the vacuum of space. The electromagnetic spectrum encompasses a wide range of frequencies, including radio waves, microwaves, infrared radiation, visible light, ultraviolet radiation, X-rays, and gamma rays. Each type of electromagnetic wave has its own characteristic frequency, wavelength, and energy. In a vacuum, electromagnetic waves travel at the speed of light, which is approximately 299,792,458 meters per second (or about 186,282 miles per second) in a vacuum. This speed is constant for all electromagnetic waves in a vacuum, regardless of their frequency or wavelength. Electromagnetic waves can travel through space, transmitting energy and information over vast distances. They play a crucial role in various natural phenomena, such as the transmission of sunlight from the Sun to the Earth, the propagation of radio signals through the atmosphere, and the emission of X-rays and gamma rays from distant astronomical objects. In summary, electromagnetic waves from all parts of the spectrum can travel through a vacuum, allowing them to propagate freely through space without the need for a medium. This property of electromagnetic waves enables them to play essential roles in communication, astronomy, medicine, and many other fields of science and technology.
Their wavelength (or frequency), the energy carried by each photon, and the names we give them. Their speeds are all the same.
Their wavelength (or frequency), the energy carried by each photon, and the names we give them. Their speeds are all the same.
Why electromagnetic waves of course. These are waves that require no material medium for their propagation, but instead propagate by the cyclic exchange of energy between their electrical and magnetic fields (which for a given wave are always polarized perpendicular to each other, as shown in the image above).The spectrum of electromagnetic waves is continuous with no gaps and spans a potential range of wavelengths from as small as roughly the diameter of protons and neutrons to almost as large as the known universe. Different bands within this spectrum interact with matter in different ways, have been given different names by humans, and some of these bands are used by humans for a variety of different purposes (e.g. communication, RADAR, cooking, heating, vision, medical).
Each of them has one.