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Reflection is the process by which electromagnetic radiation is returned either at the boundary between two media (surface reflection) or at the interior of a medium (volume reflection), whereas transmission is the passage of electromagnetic radiation through a medium. Both processes can be accompanied by diffusion (also called scattering), which is the process of deflecting a unidirectional beam into many directions. In this case, we speak about diffuse reflection and diffuse transmission (Fig. II.14). When no diffusion occurs, reflection or transmission of an unidirectional beam results in an unidirectional beam according to the laws of geometrical optics (Fig. II.15). In this case, we speak about regular reflection (or specular reflection) and regular transmission(or direct transmission). Reflection, transmission and scattering leave the frequency of the radiation unchanged. Exception: The Doppler effect causes a change in frequency when the reflecting material or surface is in motion.
Absorptionis the transformation of radiant power to another type of energy, usually heat, by interaction with matter.
Fig. II.14 - a-c: Direct, mixed and diffuse reflection d-f: direct, mixed and diffuse transmission
Fig. II.15 - When directly reflected or directly transmitted, an unidirectional beam follows the laws of geometrical optics: direct reflection (left): ain = aout, direct transmission (right): n1 · sin(ain) = n2 · sin(aout) with n1 and n2 denoting the respective medium´s index of refraction
II.8.a. Reflectance r, Transmittance t, and Absorptancea
In general, reflection, transmission and absorption depend on the wavelength of the affected radiation. Thus, these three processes can either be quantified for monochromatic radiation (in this case, the adjective "spectral" is added to the respective quantity) or for a certain kind of polychromatic radiation. For the latter, the spectral distribution of the incident radiation has to be specified. In addition, reflectance, transmittance and absorptance might also depend on polarization and geometric distribution of the incident radiation, which therefore also have to be specified.Thereflectance r is defined by the ratio of reflected radiant power to incident radiant power. For a certain area element dA of the reflecting surface, the (differential) incident radiant power is given by the surface's irradiance Ee, multiplied with the size of the surface element, thus
dFe,incident = Ee dA
and the (differential) reflected radiant power is given by the exitance Me, multiplied with the size of the surface element:
dFe,reflected = Me dA
Thus,
or
Me = r Ee
Total reflectance is further subdivided in regular reflectance rr and diffuse reflectancerd, which are given by the ratios of regularly (or specularly) reflected radiant power and diffusely reflected radiant power to incident radiant power. From this definition, it is obvious that
r = rr + rd
The transmittance t of a medium is defined by the ratio of transmitted radiant power to incident radiant power. Total transmittance is further subdivided in regular transmittance tr and diffuse transmittance td, which are given by the ratios of regularly (or directly) transmitted radiant power and diffusely transmitted radiant power to incident radiant power.
Again,
t = tr + td
The absorptance a of a medium is defined by the ratio of absorbed radiant power to incident radiant power.
Being defined as ratios of radiant power values, reflectance, transmittance and absorptance are dimensionless.
Quantities such as reflectance and transmittance are used to describe the optical properties of materials. The quantities can apply to either complex radiation or to monochromatic radiation.
The optical properties of materials are not a constant since they are dependent on many parameters such as:
• thickness of the sample
• surface conditions
• angle of incidence
• temperature
• the spectral composition of the radiation (CIE standard illuminants A, B, C, D65 and other illuminants D)
• polarization effects
The measurement of optical properties of materials using integrating spheres is described in DIN 5036-3 and CIE 130-1998.
Descriptions of the principle measurements are presented in paragraph III.1.f below.
II.8.b. Radiance coefficient qe, Bidirectional reflectance distribution function (BRDF)
The radiance coefficient qe characterizes the directional distribution of diffusely reflected radiation. In detail, the radiance coefficient depends on the direction of the reflected beam and is defined by the ratio of the radiance reflected in this direction to the total incident irradiance. In general, the reflected radiance is not independent from the directional distribution of the incident radiation, which thus has to be specified.
In the USA, the concept of Bidirectional reflectance distribution function BRDF is similar to the radiance coefficient. The only difference is that the BRDF is a function of the directions of the incident and the reflected beam (Fig. ). In detail, the (differential) irradiance dEe impinging from a certain direction causes the reflected radiance dLe in another direction, which is given by
dLe = BRDF · dEe
This BRDF depends on more arguments than the radiance coefficient. However, its advantage is the simultaneous description of the material's reflection properties for all possible directional distributions of incident radiation, whereas the radiance coefficient generally is valid for just one specific directional distribution of incident radiation.
The unit of radiance coefficient and BRDF is 1/steradian. The BRDF is often abbreviated by the Greek letter ñ, which bears the danger of mixing the BRDF up with reflectance (see foregoing paragraph).
Fig. II.16 - Geometry used for the definition of the bidirectional reflectance distribution function (BRDF). The BRDF depends on the directions of incident and reflected radiation, which are given by the angles Ji and Jr, which are measured relative to the reflecting surface's normal, and the azimuth angles ji and jr, which are measured in the plane of the reflecting surface.
What else can I help you with?
What are the four interactions light can have with matter?
The four interactions light can have with matter are absorption, reflection, transmission, and scattering. Absorption occurs when light is taken in by the material, reflection happens when light bounces off the surface, transmission is when light passes through the material, and scattering involves the redirection of light waves in different directions.
How absorption and scattering affect the beam of light?
Absorption occurs when a material takes in light energy, causing the beam to lose intensity as the energy is converted to other forms. Scattering happens when light is deflected in various directions by particles or surfaces in its path, reducing the overall intensity and sometimes causing the beam to spread out. Both absorption and scattering can alter the direction, intensity, and overall characteristics of a light beam.
How do you use absorption and scattering in the same sentence?
Absorption and scattering are two processes that affect the behavior of light as it interacts with materials. Absorption occurs when light is absorbed and converted into other forms of energy, while scattering refers to the deflection of light in different directions. In many cases, materials can exhibit both absorption and scattering simultaneously, leading to complex interactions with light.
What happends during reflecton arbsoption scattering and transmission?
During reflection, light bounces off a surface. Absorption involves the light being taken in by the material. Scattering refers to the redirection of light particles in different directions. Transmission occurs when light passes through a material without being absorbed or scattered.
How does light interact with materials and what are the effects of this interaction?
Light interacts with materials in several ways, including absorption, reflection, transmission, and scattering. When light is absorbed by a material, it can cause the material to heat up or undergo a chemical reaction. Reflection occurs when light bounces off a material's surface, while transmission happens when light passes through a material. Scattering is when light is dispersed in different directions by the material. These interactions can affect the color, transparency, and overall appearance of the material.
What are the four interactions light can have with matter?
The four interactions light can have with matter are absorption, reflection, transmission, and scattering. Absorption occurs when light is taken in by the material, reflection happens when light bounces off the surface, transmission is when light passes through the material, and scattering involves the redirection of light waves in different directions.
Light remains unchanged when it goes from matter?
Many phenomenons can occur: refraction, reflexion, absorption, dispersion, scattering, transmission.
How absorption and scattering affect the beam of light?
Absorption occurs when a material takes in light energy, causing the beam to lose intensity as the energy is converted to other forms. Scattering happens when light is deflected in various directions by particles or surfaces in its path, reducing the overall intensity and sometimes causing the beam to spread out. Both absorption and scattering can alter the direction, intensity, and overall characteristics of a light beam.
How do you use absorption and scattering in the same sentence?
Absorption and scattering are two processes that affect the behavior of light as it interacts with materials. Absorption occurs when light is absorbed and converted into other forms of energy, while scattering refers to the deflection of light in different directions. In many cases, materials can exhibit both absorption and scattering simultaneously, leading to complex interactions with light.
What happends during reflecton arbsoption scattering and transmission?
During reflection, light bounces off a surface. Absorption involves the light being taken in by the material. Scattering refers to the redirection of light particles in different directions. Transmission occurs when light passes through a material without being absorbed or scattered.
What is the chlorine light transmission?
Chlorine has high light transmission properties, meaning it allows light to pass through with minimal absorption or scattering. This makes it useful for applications where maximum transparency is desired, such as in optics or certain types of glass.
How can absorption and scattering affect a beam of light?
How absorption and scattering can affect a beam of light is if the beam of light is farther away from an object, the light would be dimmer. But, if the beam of light was closer to the object, then the light would appear brighter.
How absorption and scattering can affect beam of light?
How absorption and scattering can affect a beam of light is if the beam of light is farther away from an object, the light would be dimmer. But, if the beam of light was closer to the object, then the light would appear brighter.
How does light interact with materials and what are the effects of this interaction?
Light interacts with materials in several ways, including absorption, reflection, transmission, and scattering. When light is absorbed by a material, it can cause the material to heat up or undergo a chemical reaction. Reflection occurs when light bounces off a material's surface, while transmission happens when light passes through a material. Scattering is when light is dispersed in different directions by the material. These interactions can affect the color, transparency, and overall appearance of the material.
What is the difference between absorption loss and scattering loss?
absorption: having a change in energy from source to the receiver by its medium scattering by particles: occurs without a change in energy, but results in a change in direction of propagation
In Which Would You Expect The Best Transmission Of light?
You would expect the best transmission of light in a material that is transparent, such as glass or clear plastic. These materials allow light to pass through without much absorption or scattering, resulting in minimal loss of light intensity.
What is transmission of light and how does it compare with reflection?
Transmission of light is the passage of light through a material, such as air or glass, without significant absorption or scattering. Reflection, on the other hand, occurs when light bounces off a surface, changing its direction. In transmission, light passes through the material, while in reflection, light is redirected back into the same medium.
