Electromagnetics

Electromagnetic Fields

Electromagnetic fields (EMF) are invisible electric and magnetic forces that envelop objects. EMFs can be found everywhere from natural phenomena such as Earth’s magnetic field to manmade sources like mobile phones and powerlines; their presence can have physical as well as biological impacts on living things.

Electric field strength decreases with distance from its source and is proportional to voltage applied to current flow. Conversely, magnetic fields increase with flow rate while simultaneously decreasing as one moves further away from their source.

Recent years have witnessed an explosion of publications regarding electromagnetic fields’ effect on plants, birds (embryos and eggs), mycelium and other animals. Studies conducted are often conflicting; health risks have been revised repeatedly while some findings of these studies cannot easily translate to practice; therefore more research needs to be conducted in order to fully comprehend electromagnetic fields’ effect on environmental issues.

Electromagnetic Waves

Electromagnetic waves are produced when an electric field interacts with a magnetic field and becomes coupled. The combined wave travels at a speed determined by both wavelength and frequency.

Frequency refers to the frequency of passing wave crests across an area in one second; this number is measured in Hertz (Hz), named for Heinrich Hertz who first discovered radio waves.

As electromagnetic waves narrow in wavelength, their frequencies increase proportional to energy stored as vibrations; as more frequent waves have shorter wavelengths.

Electromagnetic waves differ from sound waves in that they don’t require any medium to travel through, making electromagnetic waves ideal for broadcasting, wireless communication and microwave ovens. Furthermore, electromagnetic radiation also known as light can transport energy through these electromagnetic waves – however not all forms have equal environmental impacts.

Electromagnetic Forces

The electromagnetic force, composed of electric and magnetic forces, holds atoms together while also enabling their interaction over long distances. It produces visible light, infrared radiation, ultraviolet radiation, as well as visible, infrared, and ultraviolet wavelengths of radiation that we see around us every day. Acceleration can be accomplished by moving charged particles (protons, electrons and photons) through magnetic fields faster.

Electromagnetism underpins many of the key technologies in modern life: electrical energy generation, transmission, and distribution; production and detection of light, heat, sound; fiber optic communication networks and wireless systems; sensors; motors/actuators systems etc. To understand all of these applications engineers require a deep knowledge of electromagnetism principles including Maxwell’s equations as well as other associated mathematical concepts.

Engineers need to know how to analyze induced current and EMF, using Faraday’s law and Lenz’s law as guides. These laws outline how changing magnetic fields induce electric current in conducting materials, an essential skill when designing safe and efficient systems.

Electromagnetic Radiation

Every time you turn on the radio or television, send a text message, or microwave popcorn, you are using electromagnetic energy in the form of waves that span from long radio waves to short gamma rays. Scientists use this entire electromagnetic spectrum as part of their studies on Earth, solar system and universe.

Electromagnetic radiation refers to waves-like patterns of oscillating electric and magnetic fields that travel at light speed through space at an exponentially increasing speed, interconnecting each other at right angles to form perpendicular planes that make up electromagnetic spectrum, with various properties and applications.

These waves differ from other waves in that they travel freely through space without needing a medium such as sound to pass through; sound waves require something like air as an intermediary to travel through before being heard. Each electromagnetic wave has a characteristic length or wavelength (l), as well as frequency or number of oscillations per second which makes up its frequency.