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How is the Electromagnetic Radiation Measured? October 16, 2006

Posted by healthyself in Blogroll, Definitions, Electrical Components, Electrical Pulses, Electrical Surges, Electrical Wiring, Electromagetic pollution, electromagnetic, Electromagnetic Communications, Electromagnetic Field, Electromagnetic Interference, Electromagnetic pollution, Electromagnetic Spectrum, Electromagnetic waves, Electrosensitivity, Electrosmog, ELF, EMF's, EMR, Environment, Exposure, Frequencies, GHz, Global Warming, Government's role, HF, High Frequencies, high voltage transmission lines, HOuseholds, Hz, Infrared, LF, Lifestyle, light beam, Low Frequencies, MF, MHz, Microwave exposure, Pulsed Radiation, Pulses, Quantum Waves, radiation, Radio Waves, Radios, Sound, Spectrum, transmission, Ultraviolet, Unified Field, Visible Light, VLF, Waves.
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…The electromagnetic (EM) spectrum is …types of radiation … as a group. Radiation is energy that travels and spreads out as it goes– visible light …. from a lamp….or radio waves .. or from a radio station are two types of electromagnetic radiation. Other examples of EM radiation are microwaves, infrared and ultraviolet light, X-rays and gamma-rays. Hotter, more energetic objects and events create higher energy radiation than cool objects. Only extremely hot objects or particles moving at very high velocities can create high-energy radiation like X-rays and gamma-rays. Here are the different types of radiation in the EM spectrum, in order from lowest energy to highest:

Radio Radio: …this is the same kind of energy that radio stations emit into the air …to capture and turn into your favorite Mozart, Madonna, or Coolio tunes. But radio waves are also emitted by other things … such as stars and gases in space…
Microwave Microwaves: … will cook your popcorn in just a few minutes! In space, microwaves are used by astronomers to learn about the structure of nearby galaxies, including our own Milky Way!
Infrared to UV Infrared: we often think of this as being the same thing as ‘heat’, because it makes our skin feel warm. In space, IR light maps the dust between stars. Visible:…this is the part that our eyes see. Visible radiation is emitted by everything from fireflies to light bulbs to stars … also by fast-moving particles hitting other particles.

Ultraviolet: we know that the Sun is a source of ultraviolet (or UV) radiation, because it is the UV rays that cause our skin to burn! Stars and other “hot” objects in space emit UV radiation.

X-ray X-rays: your doctor uses them to look at your bones and your dentist to look at your teeth. Hot gases in the Universe also emit X-rays .
Gamma-ray Gamma-rays: radioactive materials (some natural and others made by man in things like nuclear power plants) can emit gamma-rays. Big particle accelerators that scientists use to help them understand what matter is made of can sometimes generate gamma-rays. But the biggest gamma-ray generator of all is the Universe! It makes gamma radiation in all kinds of ways.

A Radio Wave is not a Gamma-Ray, a Microwave is not an X-ray … or is it?

Across the EM spectrum
Radio waves, visible light, X-rays, and all the other parts of the electromagnetic spectrum are fundamentally the same thing, electromagnetic radiation.

We may think that radio waves are completely different physical objects or events than gamma-rays. They are produced in very different ways, and we detect them in different ways. But are they really different things? The answer is ‘no’. Radio waves, visible light, X-rays, and all the other parts of the electromagnetic spectrum are fundamentally the same thing. They are all electromagnetic radiation.

Electromagnetic radiation can be described in terms of a stream of photons, which are massless particles each traveling in a wave-like pattern and moving at the speed of light. Each photon contains a certain amount (or bundle) of energy, and all electromagnetic radiation consists of these photons. The only difference between the various types of electromagnetic radiation is the amount of energy found in the photons. Radio waves have photons with low energies, microwaves have a little more energy than radio waves, infrared has still more, then visible, ultraviolet, X-rays, and … the most energetic of all … gamma-rays.

Across the EM spectrum
The electromagnetic spectrum can be expressed in terms of energy, wavelength, or frequency.

“Actually, the electromagnetic spectrum can be expressed in terms of energy, wavelength, or frequency. Each way of thinking about the EM spectrum is related to the others in a precise mathematical way. So why do we have three ways of describing things, each with a different set of physical units? After all, frequency is measured in cycles per second (which is called a Hertz), wavelength is measured in meters, and energy is measured in electron volts.”

“The answer is that scientists don’t like to use big numbers when they don’t have to. It is much easier to say or write “two kilometers or 2 km” than “two thousand meters or 2,000 m”. So generally, scientists use whatever units are easiest for whatever they are working with. In radio astronomy, astronomers tend to use wavelengths or frequencies. This is because most of the radio part of the EM spectrum falls in the range from a about 1 cm to 1 km (30 gigahertz (GHz) to 100 kilohertz (kHz)). The radio is a very broad part of the EM spectrum. Infrared astronomers also use wavelength to describe their part of the EM spectrum. They tend to use microns (or millionths of meters) for wavelengths, so that they can say their part of the EM spectrum falls in the range 1 to 100 microns. Optical astronomers use wavelengths as well. In the older “CGS” version of the metric system, the units used were angstroms. An angstrom is equal to 0.0000000001 meters (10-10 m in scientific notation)! In the newer “SI” version of the metric system, we think of visible light in units of nanometers or 0.000000001 meters (10-9 m). In this system, the violet, blue, green, yellow, orange, and red light we know so well has wavelengths between 400 and 700 nanometers. This range is only a small part of the entire EM spectrum, so you can tell that the light we see is just a little fraction of all the EM radiation around us! By the time you get to the ultraviolet, X-ray, and gamma-ray regions of the EM spectrum, lengths have become too tiny to think about any more. So scientists usually refer to these photons by their energies, which are measured in electron volts. Ultraviolet radiation falls in the range from a few electron volts (eV) to a about 100 eV. X-ray photons have energies in the range 100 eV to 100,000 eV (or 100 keV). Gamma-rays then are all the photons with energies greater than 100 keV.

Why Do We Have to Go to Space to See All of the Electromagnetic Spectrum?

diagram of EM radiation that reaches the Earth's surface

Electromagnetic radiation from space is unable to reach the surface of the Earth except at a very few wavelengths, such as the visible spectrum, radio frequencies, and some ultraviolet wavelengths. Astronomers can get above enough of the Earth’s atmosphere to observe at some infrared wavelengths from mountain tops or by flying their telescopes in an aircraft. Experiments can also be taken up to altitudes as high as 35 km by balloons which can operate for months. Rocket flights can take instruments all the way above the Earth’s atmosphere for just a few minutes before they fall back to Earth, but a great many important first results in astronomy and astrophysics came from just those few minutes of observations. For long-term observations, however, it is best to have your detector on an orbiting satellite … and get above it all!


Policy Making Needs to Be Holistic–What are the Connections? September 8, 2006

Posted by healthyself in Bioeffects, Biological Effects, Blogroll, Cell phone industry, Cell phone safety, Cell Phones, Circadian rhythms, Decision Making, Electrical Surges, Electromagnetic pollution, Electromagnetic waves, Electrosensitivity, Electrosmog, ELF, EMF Research, EMF's, EMR, Environment, Global Warming, Government's role, Health related, High Frequencies, high voltage transmission lines, Legal Issues, Lifestyle, Long Term Health Risks, Low Frequencies, Microwave exposure, mobile telephones, Non Profit Organizations, Politics, Public Policy, Pulsed Radiation, Quantum Physics, radiation, Risk of Disease, Safety, transmission, W/Kg, watts, Waves, WiFi.
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“Regardless of the strategy ultimately adopted to address potential risks associated with global warming, the issue is ushering in a new phase of policymaking. Political leaders and citizens-at-large must increasingly cope with risk and uncertainty as part of policymaking. For example, debate over the risks associated with pesticides, electromagnetic fields (EMFs), and asbestos used for building insulation involve much the same issues of scientific uncertainty and economic trade-offs as does global warming. Such issues necessitate a more sophisticated political debate and an increased sensitivity to the limitations of science and the importance of economics.”

“One lesson from the ongoing debates over risk and uncertainty is that, in general, policies to address risks posed by potential environmental changes should not be developed in isolation. Although it is politically tempting to respond to a particular crisis—whether it be the energy crisis, the toxic crisis, or the EMF crisis—policies oriented towards “solving” a single environmental problem tend to be expensive and ineffective. A good case in point is the federal Superfund program, which, despite targeting billions of dollars on a limited number of toxic sites, has probably purchased less environmental health and safety than a broader-based program to reduce ongoing toxic emissions would have achieved.”