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Yes. That is why we see light from distant stars, and use radio telescopes to see even older (more distant) structures. It might be easier to imagine light has having particle properties and wave properties both. Light arrives in discrete packets of energy (particles), yet can be "guided" and "directed" like waves.

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Because c the speed of electromagnetic radiation is a constant the wavelength of the radiation is....?

... inversely proportional to its frequency. This means that as the frequency of radiation increases, its wavelength decreases, and vice versa. This relationship is expressed by the equation λ = c / f, where λ is the wavelength, c is the speed of light, and f is the frequency of the radiation.


How can one find energy with wavelength?

One can find energy with wavelength by using the equation E hc/, where E represents energy, h is Planck's constant, c is the speed of light, and is the wavelength of the light. This equation shows the relationship between energy and wavelength in electromagnetic radiation.


How can one determine the wavelength in chemistry?

In chemistry, the wavelength can be determined using the equation: wavelength speed of light / frequency. The speed of light is a constant value (3.00 x 108 m/s) and the frequency can be measured using a spectrometer or other analytical instruments. By plugging in these values into the equation, one can calculate the wavelength of a given electromagnetic wave.


What is the relationship between wavelength of light and the energy of its protons?

The energy in one photon of any electromagnetic radiation is directly proportionalto its frequency, so that would be inversely proportional to its wavelength.Note: There is no energy in the protons of light, since light has no protons.


6.6262 x 1034 Js is?

The value 6.6262 x 10^34 Js represents the Planck constant, denoted as h, in joules seconds. It is a fundamental constant in quantum mechanics and is used to describe the relationship between energy and frequency of electromagnetic radiation.

Related Questions

Which of these is constant for ALL types of electromagnetic radiation in a vacuum?

Answer = Velocity Velocity is the speed of light and, the speed of light, is a constant among Electromagnetic Radiation in the vacuum of space.


How are the wavelength and energy of electromagnetic radiation related?

The energy of one photon is given by its frequency X planck's constant Its frequency is given by the speed of light divided by the wavelength.


What is a constant across the entire elevtromagnetic spectrum?

The Planck constant is a physical constant: the quantum of action in quantum mechanics, with an angular momentum. The Planck constant is the proportionality constant between the energy of a unit of electromagnetic radiation. You may also be looking for the answer of "the speed of light."


How are speeds of electromagnetic radiation frequency and wave length related?

The speed of electromagnetic radiation (light) in a vacuum is a constant, independent of frequency or wavelength. However in a medium (e.g. glass, water, air, diamond) it is no longer a constant, allowing the colors to be separated into a spectrum.


Because c the speed of electromagnetic radiation is a constant the wavelength of the radiation is....?

... inversely proportional to its frequency. This means that as the frequency of radiation increases, its wavelength decreases, and vice versa. This relationship is expressed by the equation λ = c / f, where λ is the wavelength, c is the speed of light, and f is the frequency of the radiation.


If the frequency of an electromagnetic wave decreases what will the wavelength do?

It will become longer, and it will carry less energy, its also likely, that if the change or loss in frequency is enough, the radiation will become a different type of electromagnetic radiation in the spectrum like gamma to x-rays or visible light to infrared and so on.


How are energy and wavelength of electromagnet radiation related?

Energy and wavelength of electromagnetic radiation are inversely related. This means that as the wavelength decreases, the energy of the radiation increases, and vice versa. This relationship is described by the equation E = hc/λ, where E is the energy, h is Planck's constant, c is the speed of light, and λ is the wavelength.


Do radio waves travel through vacuum fasetr than visible light waves?

No, radio waves and visible light waves both travel at the speed of light in a vacuum, which is approximately 299,792 kilometers per second. The speed of light is constant, regardless of the wavelength of the electromagnetic radiation.


What is energy that can travel through empty space?

Electromagnetic radiation can travel through "empty" space. Depending on the wavelength of the electromagnetic radiation, we call it "radio" or "microwaves" or "heat" or "light" or "UV" or "X-rays" or even "cosmic rays" - it's all different frequencies of EM radiation. The shorter the wavelength, the higher the frequency; in fact, the frequency times the wavelength is the constant "c", the speed of light.


Is speed a constant for all types of electromagnetic radiation in space?

Yes, in a vacuum, all types of electromagnetic radiation (including light) travel at the speed of light, which is approximately 299,792 kilometers per second. This speed is a fundamental constant in physics and does not change based on the wavelength or frequency of the radiation.


When describing electromagnetic radiation there is a(n) relationship between wavelength and frequency and the greater the frequency the energy the electromagnetic radiation has.?

Electromagnetic radiation consists of waves with different wavelengths and frequencies. The frequency and energy of electromagnetic radiation are directly proportional—higher frequency waves have higher energy. This relationship is described by the formula E=hf, where E is energy, h is Planck's constant, and f is frequency.


Radiation wavelength becomes longer what happens?

When radiation wavelength becomes longer, the energy of the radiation decreases. This generally corresponds to moving from higher energy regions of the electromagnetic spectrum (e.g. ultraviolet, X-rays) to lower energy regions (e.g. infrared, radio waves). This change in energy can affect how the radiation interacts with matter and the environment.