Main content
NASA
Course: NASA > Unit 2
Lesson 4: SpectroscopyX-rays (1895)
Created by NASA.
Want to join the conversation?
How was X rays discovered and how to produce it?(5 votes)
X-rays were discovered in 1895 by Wilhelm Rontgen. He discovered X-Rays when he was experimenting with electron beams in a gas discharge tube. The fluorescent screen in his lab began to glow when the tube was turned on, and he realized that a ray had been produced. He named it an X-Ray for the unknown variable 'X' in math.
X-Rays are produced when electrons hit a metal target.(10 votes)
How does a x-ray tube works ?(1 vote)
An x-ray tube is a cathode ray tube, where electrons are accelerated under high voltage and shot towards a target. In this case, a very high voltage is applied because the end goal is x-ray fluorescence . A core electron is ejected from your target atom, and a higher-level electron relaxes to fill that "hole", and emits a photon in the process (i.e., fluoresces).
So the heat is more a byproduct of the high voltage and energetic electron beam, rather than a requirement for operation.(3 votes)
In large quantities, no. In the hospital, x-rays are in very small quanities and carefully controlled.(1 vote)
How can radiation harm the body?(1 vote)
why the x-rays cant be on the normal paper.(1 vote)
AslamOAlikum....! Mam or Sir Could you please tell me ...? ?
Why Wavelength of X-rays decreases when falling on heavy element .........?.(0 votes)
Video transcript
A star explodes in a blinding supernova, spraying x-rays across the galaxy to tell its tale. X-rays also tells a dentist which tooth to drill, and a surgeon which bones to mend. In 1895 Wilhelm Roentgen discovered that firing streams of x-rays through arms and hands created eerie, but detailed images of the bones inside. X-rays are high energy light rays with wavelengths between 3 and 0.03 nanometers. So small that some x-rays are no bigger than many individual atoms. In laboratories, scientist fire beams of x-rays at unknown substances to learn what elements they contain and to decode their atomic structure. This is how scientists unraveled complex molecules like penicillin and DNA. Scientists can also detect the x-rays emitted from extremely hot and energetic objects in the Universe. NASA's robotic rovers recorded x-rays to identify the spectral signatures of elements, such as zinc and nickel, in Martian rocks. X-rays can also reveal an object's temperature since temperature determines the wavelength of its radiation. The hotter the object, the shorter that wavelength is. X-rays come from objects that seethe at millions of degrees-such as pulsars, black holes, supernovas, or the plasma in our Sun's corona. Our Sun has a surface temperature of around 6,000 degrees celcius and radiates most of its energy in visible wavelengths. But it is easier to study the massive energy flows in the corona's energetic plasma by observing x-rays like this image from the Hinode satellite, a joint Japanese-NASA mission. NASA's SOHO satellite produced these x-ray images of the Sun that allow scientists to see and record these energy flows within the corona. NASA's orbiting Chandra x-ray observatory detects x-rays created by objects spread far across space such as this supernova explosion that occurred 10,000 light years from Earth. The colors in the gas and dust cloud correspond to different energy levels of the x-rays created by the blast. X-rays at different wavelengths provide information about an object's composition, temperature, density, or its magnetic field. Human eyes may not be able to see x-rays but, from seething cosmic bodies to individual atomic elements, x-rays provide a wealth of information to exploring scientists.