X-Ray

Yes, placing an X-ray or gamma ray telescope on a mountain top can reduce atmospheric interference and provide clearer observations due to the thinner atmosphere at higher altitudes. This can improve the sensitivity and accuracy of the telescope in detecting these high-energy emissions from space.

Gamma rays and X-rays are harmful to students because they are forms of ionizing radiation that can penetrate the body, damaging cells and DNA. This can increase the risk of cancer and other health problems, depending on the level of exposure. It is important for students to limit their exposure to these types of radiation to protect their health.

X-ray's nickname is ironic because X-rays are a form of electromagnetic radiation that can penetrate solid objects, yet X-ray in the story has poor eyesight and needs glasses to see. This contrast between the powerful nature of X-rays and the character's visual impairment creates an ironic twist.

X-radiation (composed of X-rays) is a form of electromagnetic radiation. X-rays have a wavelength in the range of 0.01 to 10 nanometers, corresponding to frequencies in the range 30 petahertz to 30 exahertz (3×1016 Hz to 3×1019 Hz) and energies in the range 120 eV to 120 keV. They are shorter in wavelength than UV rays and longer than gamma rays. In many languages, X-radiation is called Röntgen radiation, after Wilhelm Conrad Röntgen, who is usually credited as its discoverer, and who had named it X-radiation to signify an unknown type of radiation.

Rosalind Franklin, a biophysicist, used X-ray diffraction to capture images of DNA's structure. These images provided crucial data that helped Watson and Crick in determining the double helix structure of DNA.

A lamp or an X-ray tube cannot be used to "add neutrons" to other nuclei because lamps and X-ray tubes are not neutron sources.

Neutron activation is generally something we do in an operating nuclear reactor. In the core of the reactor, there is a high neutron flux. Many, many neutrons are being released in the fissions that are going on in the nuclear core. Materials that are to be activated are lowered through ports and brought down into the neutron flux. Activation occurs. Lamps or X-rays do not produce neutrons, and cannot be used in neutron activation activities. No neutrons means no neutron activation.

X-ray, being a photon, has no physical form or need for a shovel. This appears to be a play on words or a joke related to X-ray radiation passing through holes that are smaller than its wavelength, resulting in diffraction patterns.

X-rays are a form of electromagnetic radiation that can penetrate soft tissues like skin but are absorbed by denser materials like bones. The higher energy of X-rays allows them to pass through skin and create images of internal structures in medical imaging. However, prolonged exposure to X-rays can be harmful due to their ionizing nature.

Radium was used in the past for the treatment of some cancers and Marie Curie was a pioneer in this field. But radium don't emit x-rays; radium is a emitter of gamma, alpha and beta rays. The gamma radiation can destroy malign tumors.

In the book "Holes" by Louis Sachar, X-Ray is a teenage boy at Camp Green Lake who is the leader of the group of boys in Group D. He is known for his intelligence and ability to navigate situations strategically, often coming up with plans to find treasures in the desert. However, X-Ray can also be manipulative and self-serving at times, using his leadership position to his advantage.

Ultraviolet photons have wavelengths below 400nm. X-ray photons have wavelengths between 0.01nm - 10nm. Photons with wavelengths smaller than xrays' are called gamma rays.

Yes, x-rays can travel through air, but some of the energy is absorbed by the air molecules as they pass through. This is why x-rays are typically used in a controlled setting with protective equipment to minimize exposure to surrounding tissues.

Rosalind Franklin, a scientist at King's College London, produced the x-ray crystallography pictures of DNA that were crucial for Watson and Crick's discovery of the DNA's double helix structure. Although Franklin's data was instrumental in their work, she did not share the Nobel Prize awarded to Watson, Crick, and Wilkins for the discovery.

The biggest telescopes are reflecting - instead of a main lens, they have a main mirror. Above a certain size, it is no longer feasible, or at least practical, to use lenses.

The biggest telescopes are reflecting - instead of a main lens, they have a main mirror. Above a certain size, it is no longer feasible, or at least practical, to use lenses.

The biggest telescopes are reflecting - instead of a main lens, they have a main mirror. Above a certain size, it is no longer feasible, or at least practical, to use lenses.

The biggest telescopes are reflecting - instead of a main lens, they have a main mirror. Above a certain size, it is no longer feasible, or at least practical, to use lenses.

Yes, X-rays travel at the speed of light in a vacuum, which is higher than the speed of visible light. This is because the speed of light in a medium is inversely proportional to the refractive index of the medium, and X-rays have a shorter wavelength than visible light, allowing them to travel at a higher speed.

Having the Chandra X-ray Observatory in space allows it to capture high-energy X-rays from celestial sources without the Earth's atmosphere absorbing them. X-rays cannot penetrate the Earth's atmosphere, so having Chandra in space ensures that it can observe these energetic phenomena clearly and accurately. Additionally, being above the Earth's atmosphere provides a stable observing platform with minimal interference from factors like weather or light pollution.

Chandra X-ray Observatory detects X-rays, which are a type of electromagnetic wave with higher energy and shorter wavelength than visible light. X-rays are emitted by extremely hot and high-energy objects in the universe, such as black holes, neutron stars, and supernova remnants.

Although not harmful in small doses, x-rays and cosmic rays potentially can damage tissue or sensitive computer equipment; spacecraft and some ground-based electronics are specially hardened against them for this reason.

High energy particles have the potential to damage DNA and in some cases cause mutations, although this is not a cause for panic. The Earth's atmosphere and powerful magnetic field manage to shield us from most space-born radiation and high-energy particles.

In a typical year a person might receive about 360 millirems of x-ray radiation from space and other normal sources of radiation in the matter around us. By comparison, a dental x-ray is about 2 to 3 mrems. Astronauts which travel outside the Earth's magnetosphere were known to be exposed to larger doses of radiation; this was studied as part of the Apollo lunar mission effort, and the levels deemed safe owing to the brevity of the missions. Some astronauts reported seeing brief flashes of light in their vision, which was attributed to cosmic rays although the mechanism is not fully understood.

I don't believe that this form of deay would directly form a X-ray photon. To go from 81RB to 81KR, a proton would need to be converted to a neutron - thus inverse Beta Decay. During this decay event, a neutrono would also be produced.

Because the electron captured is in the inner shell, the atom is unstable. Thus, when the electrons realign in their respective shells, a high energy photon would then be produced. However, this photon is not the direct result of decay but is instead due to the atom returning to is ground state.

See http://en.wikipedia.org/wiki/Electron_capture

X-rays can be harmful if not used properly. Unnecessary exposure to X-rays can increase the risk of cancer due to the radiation. However, when used in medical imaging for necessary diagnostic purposes, the benefits usually outweigh the risks. It is important to follow recommendations and guidelines provided by healthcare professionals to ensure safe use of X-rays.

Gamma rays have higher energy than X-rays. Gamma rays are a type of electromagnetic radiation with the highest energy in the electromagnetic spectrum, while X-rays have lower energy and fall between ultraviolet and gamma rays on the spectrum.

Marie Curie did not invent the X-ray machine; it was actually invented by Wilhelm Conrad Roentgen in 1895. However, Marie Curie did pioneer research on radioactivity and its uses in medicine, which contributed to advancements in X-ray technology.

X-rays are not capable of producing beta rays. Beta rays are a form of ionizing radiation emitted by certain types of radioactive nuclei. X-rays are electromagnetic radiation produced through processes like electron transitions in atoms or by high-energy electron collisions.