定义:具有很宽带宽的光源。
白光光源是具有很宽的光学带宽(通常在100nm或者更宽)的光源。然而,它在实际应用中有两种非常不同的意义:
- 有些情况下,白光光源发射可见白光。这种光源可用于照明或者色度学。它包含白炽灯,发射的光具有非常平缓和很宽的光谱。(荧光灯或者其它气体放电灯的光谱看起来也是白色但是具有更加精细的结构。)通常情况下,这种白光光源具有很低的空间相干性,因此很难紧聚焦光。
- 其它情况下,宽带光源并不需要辐射可见光谱区域的光。这种光源可以是超辐射光源,例如超辐射二极管,具有很高的空间相干性,很难使输出光聚焦或者传输到光纤中。然而,由于其很大的光学带宽,因此其时间相干性很低。这种白光光源的应用主要是白光干涉仪,表征光学元件和光谱学。
- 超连续光产生可以得到更宽光谱的光。它基于光纤中的强非线性相互作用。最常用的光纤为光子晶体光纤。入射光为超短脉冲,纳米脉冲或者连续光的形式。
有些应用中,光学带宽用半高全宽值来表征,其中光谱中的尾部不太相干。也有的情况下,只需要在较大的范围内具有中等强度的功率谱密度,即使功率谱密度在该区域内变化很大也不影响。
Definition: light sources with very broad optical bandwidth
More general term: light sources
A white light source is usually understood to be a light source generating white light, i.e., light with a white perception for the human eye.
Some typical types of white light sources are explained in the following:
- Incandescent lamps (e.g., a tungsten-halogen lamps) naturally emit light with a smooth and very broad optical spectrum. They are cheap to fabricate and easy to handle, but have a quite limited luminous efficacy. The lifetime is also often less than satisfactory.
- Some types of gas discharge lamps, in particular high-pressure arc lamps and flash lamps, for example xenon lamps, can produce bright white light. Metal halide lamps offer particularly high performance in terms of radiance and luminous efficacy. Device lifetimes vary strongly, depending on the type of lamps and its operation conditions.
- Spectra of fluorescent lamps or some other gas discharge lamps can also look white but are sometimes much more structured. Such white light sources often have a low color rendering index.
- Light-emitting diodes (LEDs) in a strict sense cannot generate white light, but there are LED-based white light emitters (often called white LEDs), which mostly contain a blue (GaN-based) LED and a phosphor which absorbs part of the blue light and emits fluorescence at longer wavelengths, so that the overall color impression is white. It is also possible to combine the radiation e.g. of LEDs emitting red, green and blue light.
- Lasers are not suitable for directly generating white light. However, there are laser-based RGB sources, and by mixing their red, green and blue outputs, one can obtain intense white light.
Various CIE standard illuminants serve as standard references for different types of white light spectra.
Essential Properties of White Light Sources
The following properties of white light sources are often particularly important for applications:
- For applications like lighting, the color temperature of a white light source, indicating its color tone, is an important parameter.
- The color rendering index (CRI) is a measure for how well colors can be judged when objects are illuminated with that light.
- Concerning energy efficiency, the luminous efficacy is an important parameter. Note that the effectively achieved energy efficiency can also substantially depend on how directional the light emission is. For example, the energy-saving qualities of LED-based solutions often come to a substantial degree from their directed emission, making it easier to send the light where it is needed.
- The temporal coherence of any white light source is necessarily low as a consequence of its broad optical bandwidth.
- Many white light sources also have a low spatial coherence, making it difficult to tightly focus the light, and a correspondingly low radiance. For example, that applies to long-arc lamps, having a large light-emitting volume. A low radiance is usually no problem for applications like lighting, but is not acceptable for applications like projection displays. Higher radiance can be achieved with short-arc lamps, which are operated with high power densities (high intensity discharge lamps).
- Most white light sources operate continuously, some others are made for pulsed emission – in particular, flash lamps.
Our properties of interest may be the operation lifetime, the ability of rapid switching, the constancy of the radiant flux (low intensity noise, weak aging, weak temperature dependence), the constancy of the spectral shape and color tone, and the absence of possibly disturbing ultraviolet light.
Application of White Light Sources
Many white light sources are required for various lighting applications (indoor and outdoor), where one often needs to generate a substantial luminous flux over extended times. The energy efficiency, largely determined by the luminous efficacy, is then particularly important.
There are various other applications in the context of illumination, often in a more or less localized manner – for example, reading lights, projection displays, machine vision and microscope illumination.
Pulsed white light sources can be used for photography, for stroboscopes and in some scientific applications.
Further, there are special applications of white light sources in scientific and technical areas such as spectroscopy, colorimetry, forensic investigations and solar cell testing.
Other Broadband Light Sources
In some cases, the term white light sources is used for sources which do not really produce a white color impression, but just produce light with a broad optical bandwidth. Some of them do not even emit in the visible spectral range, while others cover a range from somewhere in the infrared to the ultraviolet. Certain applications such as white light interferometry do not really need a white color impression, but just the large bandwidth. Other examples for applications are the characterization of optical components and spectroscopy.
While most white light sources have a poor spatial coherence, there are broadband sources with a high spatial coherence, sometimes even with the whole optical power delivered in a single spatial mode e.g. of an optical fiber. This allows focusing of the radiation to very small spots. Such sources can be different types of superluminescent sources, e.g. superluminescent diodes or ASE sources based on rare-earth-doped fibers.
For particularly high bandwidths, sometimes even more than octave-spanning, one may employ supercontinuum sources, based on strongly nonlinear interactions e.g. in an optical fiber. Most widely used for those are photonic crystal fibers. The input light can be supplied in the form ultrashort pulses, nanosecond pulses, or continuously.
For some applications, the optical bandwidth specified as a full-width half-maximum value is important, whereas weak tails in the spectrum are not relevant. In other cases, it is only important to have at least some moderate level of power spectral density over a broad range, even if the spectral flux varies a lot within that range.
