# What is the frequency of a wave carrying 8.35x10 18 j of energy?

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## Top best answers to the question «What is the frequency of a wave carrying 8.35x10 18 j of energy»

What is the frequency of a wave carrying 8.35 x 10-18 J of energy? (8.35x10-18)/(6.626 x 10-34)= **1.26x1016 Hz g**. What is the frequency of a 1.78 x 10-15 J wave? (1.78x10-15)/(6.626 x 10-34)= 2.69x1018 Hz h.

FAQ

Those who are looking for an answer to the question «What is the frequency of a wave carrying 8.35x10 18 j of energy?» often ask the following questions:

### 👋 What is the frequency of a wave carrying?

Wave frequency is **the number of waves that pass a fixed point in a given amount of time**. The SI unit for wave frequency is the hertz (Hz), where 1 hertz equals 1 wave passing a fixed point in 1 second.

- Which wave is carrying the most energy brainly?
- Does frequency affect energy of wave?
- How does frequency affect wave energy?

### 👋 Which wave is carrying the most energy?

- The
**electromagnetic waves**with the highest energy are**gamma waves**(usually called gamma rays). The most energetic gamma rays appear to originate from extremely energetic stellar objects called pulsars and blazars.

- What is the relationship between wave energy and wave frequency?
- Which wave is carrying the most energy a wave with large amplitude?
- How are frequency and wave energy related?

### 👋 Does frequency affect wave energy?

- Higher the frequency of the wave,
**more is the energy carried by it. A wave with higher frequency would have more energy**, and thus more energy will be transferred to the electrons. Lol so it's another question where we're not supposed to ask why?

- How does frequency effect energy transverse wave?
- How does frequency relate to wave energy?
- Is a wave frequency related to energy?

We've handpicked 23 related questions for you, similar to «What is the frequency of a wave carrying 8.35x10 18 j of energy?» so you can surely find the answer!

What is the energy of wave amplitude or frequency?- Energy of a classical wave is proportional to the square of the amplitude and is independent of frequency. However it's more helpful to talk about power transmission of a wave (per unit area) because the total energy in a wave is spread out. The power transmitted will in general depend on the frequency as well as the amplitude of the wave.

#### Radio waves

**Radio waves**, on the other hand, have the lowest energies, longest wavelengths, and lowest frequencies of any type of EM radiation. In order from highest to lowest energy, the sections of the EM spectrum are named: gamma rays, X-rays, ultraviolet radiation, visible light, infrared radiation, and radio waves. Which wave has the highest frequency and energy?

**Gamma rays**have the highest energies, the shortest wavelengths, and the highest frequencies. Radio waves, on the other hand, have the lowest energies, longest wavelengths, and lowest frequencies of any type of EM radiation.

To summarise, waves carry energy. The amount of energy they carry is related to their frequency and their amplitude. **The higher the frequency, the more energy**, and the higher the amplitude, the more energy.

#### What is the relationship between wavelength and frequency?

- Wavelength and frequency are two such characteristics. The relationship between wavelength and frequency is that the
**frequency of a wave multiplied by its wavelength gives the speed of the wave**, as we will see below.

#### How do you calculate the frequency of a wave?

- The most common unit of frequency is the hertz (Hz), corresponding to one crest per second. The frequency of a wave can be calculated by
**dividing the speed of the wave by the wavelength**. Thus, in the electromagnetic spectrum, the wavelengths decrease as the frequencies increase, and vice versa.

#### How does frequency affect energy of a wave?

- Wave frequency is related to wave energy. Since all that waves really are is traveling energy, the more energy in a wave, the higher its frequency. The lower the frequency is, the less energy in the wave. Following the above examples, gamma rays have very high energy and radio waves are low-energy.

- When we mention
**energy of**an electromagnetic**wave**we always say it's**energy**in terms**of Amplitude**square , and say it's frequency independent. However , when we mention this in quantum mechanics it's enertgy**is**hf and its frequency dependent. And we say higher frequency means higher energy, now we no longer relates it to it's amplitude???

- Answer Wiki. The
**energy**of**a wave**is not just**a**matter of frequency. For two waves of the same amplitude the higher**frequency**will have higher energy content because the medium is vibrating at faster speeds and its particles have higher kinetic energy.

#### How does the frequency of a wave affect the electric energy?

- Each
**wave**of a fixed height can lift the float once and give a certain amount of electric energy. Waves with a higher**frequency**will do this more times per minute and therefore generate more electric power than waves with a lower frequency.

- Energy of a classical wave is proportional to the square of the amplitude and is independent of frequency. However it’s more helpful to talk about power transmission of a wave (per unit area) because the total energy in a wave is spread out. The power transmitted will in general depend on the frequency as well as the amplitude of the wave.

#### What happens as the frequency of a wave increases?

- As
**frequency**increases**the energy of a wave**also increases. What happens as**the**wavelength**of**electromagnetic radiation increases? Remember that for any wave, wavelength x frequency = speed (**of the wave**). So, as the wavelength increases,**the frequency**decreases.

#### How do you convert frequency into wavelength?

- To convert wavelength to frequency enter the wavelength in microns (μm) and press "Calculate f and E". The corresponding frequency will be in the "frequency" field in GHz. OR enter the frequency in gigahertz (GHz) and press "Calculate λ and E" to convert to wavelength. Wavelength will be in μm.

**The**relationship between the amplitude and**energy of a wave**can be explained as**energy**being directly proportional**to**amplitude squared.**Frequency is**inversely proportional**to the wave**'s amplitude....

- The electron’s vibration causes a transverse wave and the photon’s energy is based on the frequency of this vibration. This energy and its derivation is very similar to
**Coulomb’s law**, with the exception that one is measured as energy and one is measured as a force.

To summarise, waves carry energy. The amount of energy they carry is related to **their frequency and their amplitude**. The higher the frequency, the more energy, and the higher the amplitude, the more energy.

- How
**does**changing**frequency affect**the**energy of**the wave?**Frequency**is the number**of**ways that pass by each second, measured in hertz. So**a wave of a**particular amplitude will transmit more**energy**per second if it has**a**higher frequency , simply because more waves are passing by in a given period of time.

- The quantum of energy in an EM wave is the photon, and the energy of one photon is Planck’s constant times the frequency of the wave, so higher frequency light has larger quanta of energy. Beware, however: this does not mean that a laser beam of low frequency and high intensity carries less total energy than a single gamma ray photon.

- Wave frequency is related to wave energy. Since all that waves really are is traveling energy, the more energy in a wave, the higher its frequency. The lower the frequency is, the less energy in the wave. Following the above examples, gamma rays have very high energy and radio waves are low-energy.

Wave frequency is related to **wave energy**. Since all that waves really are is traveling energy, the more energy in a wave, the higher its frequency. The lower the frequency is, the less energy in the wave… Shorter waves move faster and have more energy, and longer waves travel more slowly and have less energy.

- If you are talking about light wave or a wave of radiation in general, yes energy is directly proportional to the wave frequency but inversely proportiona to the wavelength.Since E= hf=hC/l,where C is light speed,constant,h is Planck constant l is the wave length and f is the frequency.Since hC =constant k ——->E=k/l and E~f.

- The amount of energy in a wave is related to its
**amplitude and its frequency**. Large-amplitude earthquakes produce large ground displacements. Loud sounds have high-pressure amplitudes and come from larger-amplitude source vibrations than soft sounds.

Wave Frequency and Energy

The frequency of a wave is the same as the frequency of the vibrations that caused the wave… This takes more energy, so **a higher-frequency wave** has more energy than a lower-frequency wave with the same amplitude.