The frequency would be 1 million Hertz.
The frequency of something vibrating 1 million times per second is 1 million hertz (Hz).
The frequency of something vibrating one million times per second is 1 MHz (megahertz).
1Mhz (full wave) or 500kHz (half wave) but you didn't describe any type of oscillation so therefore it has no frequency except a vibration. What does Vibration mean? A sound vibration, does that mean noise energy? A material shake, a high noise energy noise pitch from collision or hum?
The wavelength for a frequency of 1 million Hz is 300 meters. This can be calculated using the formula: wavelength = speed of light / frequency. In this case, the speed of light is approximately 300 million meters per second.
It is Tungsten
MHz (megahertz) means millions of cycles per second. For example, if something has a frequency of 100 MHz, something will repeat at a rate of 100 million cycles per second.
10 million
Frequency refers to the vibration of some object that is creating a wave; in the case of electromagnetic waves, it would normally be an electron. Let us then imagine a vibrating electron. Every time it vibrates, it produces a wave. If it vibrates a million times a second it produces a million waves. The electromagnetic radiation always travels at the same speed, the speed of light, sometimes known as c, which is equal to 300,000 kilometers per second. So if there are a million waves per second, they will fit into the space of 300,000 kilometers, which makes each wave a third of a kilometer in length. Increase the frequency and you increase the number of waves, but the total distance remains the same, so you have to fit more waves into the same distance, hence, each individual wave is smaller, meaning it has a shorter wavelength. So if the electron is now vibrating at a billion times a second, it produces a billion waves, and they still have to fit into 300,000 kilometers, hence, each wave is now a third of a meter in length, rather than a third of a kilometer. If the electron vibrates at a trillion times a second, the waves are then a third of a millimeter in length. And so forth.
One megahertz
An oscillator is something that produces an output that repeats regularly. In the electronics field this will be an electrical waveform, often but not always a sine wave. The most important property of an oscillator is its frequency : the rate at which the output repeats. This is measured in Hertz (Hz for short). One Hertz is one repetition (aka cycle) per second. One MegaHertz (MHz) is one million repetitions per second. One of the problems in designing a high quality oscillator is maintaining the output frequency at the value required. One method is to control it by a quartz crystal; this is cut so that it vibrates mechanically at the design frequency, and is coupled to the electronics by the piezo-electric effect. A 12 MHz crystal oscillator is an electronic circuit, whose output frequency is controlled by a quartz crystal to repeat 12 million times per second. (Note. Oscillators don't have to be electronic. Other examples are a guitar string, a flute or a pendulum. An electronic oscillator is the only one that can be crystal controlled.)
An oscillator is something that produces an output that repeats regularly. In the electronics field this will be an electrical waveform, often but not always a sine wave. The most important property of an oscillator is its frequency : the rate at which the output repeats. This is measured in Hertz (Hz for short). One Hertz is one repetition (aka cycle) per second. One MegaHertz (MHz) is one million repetitions per second. One of the problems in designing a high quality oscillator is maintaining the output frequency at the value required. One method is to control it by a quartz crystal; this is cut so that it vibrates mechanically at the design frequency, and is coupled to the electronics by the piezo-electric effect. A 12 MHz crystal oscillator is an electronic circuit, whose output frequency is controlled by a quartz crystal to repeat 12 million times per second. (Note. Oscillators don't have to be electronic. Other examples are a guitar string, a Flute or a pendulum. An electronic oscillator is the only one that can be crystal controlled.)
Electromagnetic waves in the X-ray frequency range typically have frequencies around 100 million Hz. These waves have high energy and can penetrate materials, making them useful in medical imaging and industrial applications.