LEDs - Green Devices of Lighting Technology
A new approach to fabricating LEDs could be used to increase their efficiency by 20 per cent while yielding higher-quality light than conventional LEDs. However, researches are going on to examine their impacts on human eye.
What are LEDs?
Basically, LEDs are just solid-state devices that emit light when connected to an electrical circuit. They are made of special kinds of materials, called semiconductors.
When current is passed, light is produced as the particles that carry the current (known as electrons and holes) combine together within the semiconductor material.
The colour emitted by an LED depends on the semiconductor material it is built of. A diode made of gallium arsenide (Gas) emits red light while a diode made of gallium phosphide (GaP) emits green light. Using other semiconducting materials diodes emitting yellow, orange colours, etc., have also been developed.
The development of white LEDs became possible only after the invention of blue-light emitting diodes or blue LEDs. The development of blue LED was posing difficulties. However, in 1997, blue LED was finally created, thanks to the efforts of the Japanese scientists Shuji Nakamura, Isamu Akasaki and Hiroshi Amano. They were able to create blue LED by using gallium nitride (GaN) and indium gallium nitride (InGaN). The creation of blue LED by the scientist-trio virtually revolutionised the field of lighting technology. It became possible to generate white light by combining the outputs from red, green and blue LEDs. Generally, Nobel prizes are awarded for somewhat arcane and hard-to-grasp discoveries. However, the Nobel Prize Committee realised the real-world importance of this innovation and awarded the scientist-trio the Nobel Prize in Physics for the year 2014.
The history of development of LEDs
In 1907, the British scientist Henry Joseph Round, while working as an assistant to Guglielmo Marconi in the Marconi Lab, discovered that an electric current passed through silicon carbide produces light.
However, nobody took a serious note of Henry's work. In the mid-1920s, Russian radio researcher Oleg Vladimirovich Lose observed that diodes used in radio receivers emitted light when current was passed through them. In 1927, Losev published a paper about his research in a Russian journal. Later, he also published the details of his work in German and British journals.
Lose used Einstein's new quantum theory to explain how electrons produce the light without releasing heat. He also wrote a letter to Einstein asking for his help in developing the theory of LEDs.
But, incidentally, he received no reply from Einstein. While no practical LED could be created out of Losev's work, his research did pave the path for future development of LEDs.
In 1950, British scientists using gallium arsenide developed an LED that could emit light in the infrared region of the spectrum. This may be said to be the first ever attempt to develop infrared (IR) LED. Eleven years later, in 1961, Robert Biard and Gary Pittman working with Texas Instruments invented and patented an IR LED. This was, in fact, the first LED. However, the light emitted by it being in the infrared region of the spectrum, was beyond the visible range.
Actually, Biard and Pittman accidentally developed the IR LED when they were attempting to invent a laser diode.
In 1962, Nick Holonyak, a consulting engineer with General Electric Co. invented the first visible LED. Holonyak used gallium arsenide phosphide to create this LED. In 1972, electrical engineer George Crayford invented the first yellow LED for Monsanto Co. Cravford also invented a red LED that was ten times brighter than Holonyak's.
It should be noted that Monsanto Co. was the first to mass-produce visible light LEDs. In 1968, Monsanto produced red LEDs used as indicators. But it was not until 1970s that LEDs became popular when Fairchild Optoelectronics began producing low cost LED devices.
Credentials of LEDs
The most important credential of LEDs is that they are highly energy efficient as they consume very little power. The great secret of energy efficiency exhibited by LEDs lies in the fact that they produce light directly without having to pass through an intermediate stage. In other sources of man-made light, only a fraction of electrical energy is converted into light. For instance, in the case of incandescent bulbs, electrical energy is first converted to heat energy to heat the filament, which subsequently emits light.
About 90 per cent of the energy goes in heating the filament and only 10 per cent is converted to light.
In the case of fluorescent tubes or compact fluorescent lamps (CFLs), the electrical energy is first used to ionise a gas, which subsequently produces light by fluorescence of a special material (called phosphor) that is coated on the inside of the tube or CFL. However, LEDs neither have a filament nor a gas; they function solely through movement of electrons through semiconducting materials. So, LEDs are more energy efficient and emit brighter light compared to other artificial light sources. Also, they are long lasting.
They can last for 1,00,000 hours or more. That means if you buy an LED today, you would need to throw it after using it for more than 25 years! Sounds incredible but true. Calculation is simple: there are 365 days in a whole year and normally a bulb is used for 10 hours a day in an average household. Compared to an LED bulb, an incandescent bulb lasts for only 1,000 hours and a CFL for around 8,000 hours.
However, LED bulbs present a high up-front cost compared to incandescent bulbs or CFLs. But, in the long run, they indeed prove cost effective by saving a lot of energy. The worldwide thrust, therefore, is to use LEDs for general lighting purposes. Statistics show that about one-fourth of global electricity consumption is used for lighting purposes.
In view of very low power require-ments, LEDs can effectively be powered by solar panels. This has great potential of benefitting 1.5 billion people across the globe who lack access to electricity grids.
New types of LEDs
Conventional white LEDs used for illumination purposes give out bright light closer to daylight. But, now warm-white LEDs have also been developed.
These LEDs produce a yellow hue, close to that produced by incandescent bulbs.
They produce less glare and work more efficiently in fog. Also, they give an aesthetic look. Warm-white LEDs were initially started in Korea and Malaysia not very long time ago. But, now they are being used in other countries as well. In India, warm-white LEDs are being used to give aesthetic look to roundabouts, parks and fountains in New Delhi.
Potential health risks of LEDs
It has been found that LEDs might affect your eye, particularly the health of retina. This might sound unbelievable, but some studies indicate that the risk cannot be ruled out either. The latest to raise the red flag is the French Agency for Food, Environmental and Occupational Health & Safety (ANSES), the country's government-run health watchdog. In a 400-page report, it has stated that the blue light in LED lighting can damage the retina. "Exposure to an intense and powerful (LED) light is 'photo-toxic and can lead to irreversible loss of retinal cells and diminished sharpness of vision, ," said the report.
Like most other countries, LEDs are used widely in our country, both outdoors and indoors. LEDs with high intensity are also increasingly being used in automobile headlights.
Although LEDs are energy efficient, they produce more blue light compared to the old-fashioned incandescent bulbs.
According to eye specialists, theoretically
LED lights have the potential to damage retinal cells. However, they say that there is a need for large-scale clinical studies to determine the intensity and duration of such exposures that can be damaging.
"Conclusive data is needed before raising an alarm", they say.
Another area of concern is the marked constant flicker and glare in LED lights.
Most LEDs available in India have high flicker rates not suitable for overall eye health. Some studies point out that the factors that make flicker worse include longer duration of exposure, greater area of retina receiving stimulation, greater brightness of the Hash, and its higher contrast with surrounding luminance.
In fact, artificial lighting is an integral part of our everyday life. We spend an average of 10-12 hours under these lights.
It is, therefore, important that LED lights need the photobiological safety standards prescribed internationally. The issues of flicker and glare are actually associated with poorly manufactured LEDs.
The issues of eye health, particularly the health of retina are associated with LEDs.
However, there is no conclusive evidence yet that LEDs do hurt the retina. It may be relevant to mention that last year (2018) the European Commission had stated that there is no evidence that the normal usage of LEDs can adversely affect the health of common people. In its statement, the Commission also pointed out: "However, there is insufficient research on the health effects of LED lighting and many topics should be investigated further, particularly the effects of flicker."