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Total external reflection, hollow light tube
Total internal reflection, block of acrylic

Light tubes (also known as solar pipes, tubular skylights or sun tunnels[1]) are structures that transmit or distribute natural or artificial light for the purpose of illumination and are examples of optical waveguides.

In their application to daylighting, they are also often called tubular daylighting devices, sun pipes, sun scopes, or daylight pipes. They can be divided into two broad categories: hollow structures that contain the light with reflective surfaces; and transparent solids that contain the light by total internal reflection. Principles of nonimaging optics govern the flow of light through them.[2]

Types

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The Copper Box, venue for Handball at the 2012 Summer Olympics, makes use of light tubes to reduce energy use.

IR light tubes

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Manufacturing custom designed infrared light pipes, hollow waveguides and homogenizers is non-trivial. This is because these are tubes lined with a highly polished infrared reflective coating of gold, which can be applied thick enough to permit these tubes to be used in highly corrosive atmospheres. Carbon black can be applied to certain parts of light pipes to absorb IR light (see photonics). This is done to limit IR light to only certain areas of the pipe.

While most light pipes are produced with a round cross-section, light pipes are not limited to this geometry. Square and hexagonal cross-sections are used in special applications. Hexagonal pipes tend to produce the most homogenized type of IR Light. The pipes do not need to be straight. Bends in the pipe have little effect on efficiency.

Light tube with reflective material

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A light tube installed in the subterranean train station at Potsdamer Platz, Berlin
Capturing sunlight above ground
Distributing sunlight below ground

The first commercial reflector systems were patented and marketed in the 1850s by Paul Emile Chappuis in London, using various forms of angled mirror designs. Chappuis Ltd's reflectors were in continuous production until the factory was destroyed in 1943.[3] The concept was rediscovered and patented in 1986 by Solatube International of Australia.[4] This system has been marketed for widespread residential and commercial use. Other daylighting products are on the market under various generic names, such as "SunScope", "solar pipe", "light pipe", "light tube", and "tubular skylight".

A tube lined with highly reflective material leads the light rays through a building, starting from an entrance-point located on its roof or one of its outer walls. A light tube is not intended for imaging (in contrast to a periscope, for example); thus image distortions pose no problem and are in many ways encouraged due to the reduction of "directional" light.

The entrance point usually comprises a dome (cupola), which has the function of collecting and reflecting as much sunlight as possible into the tube. Many units also have directional "collectors", "reflectors", or even Fresnel lens devices that assist in collecting additional directional light down the tube.

In 1994, the Windows and Daylighting Group at Lawrence Berkeley National Laboratory (LBNL) developed a series of horizontal light pipe prototypes to increase daylight illuminance at distances of 4.6-9.1 m, to improve the uniformity of daylight distribution and luminance gradient across the room under variable sun and sky conditions throughout the year. The light pipes were designed to passively transport daylighting through relatively small inlet glazing areas by reflecting sunlight to depths greater than conventional sidelight windows or skylights.[5][6]

A set-up in which a laser cut acrylic panel is arranged to redirect sunlight into a horizontally or vertically orientated mirrored pipe, combined with a light spreading system with a triangular arrangement of laser cut panels that spread the light into the room, was developed at the Queensland University of Technology in Brisbane.[7] In 2003, Veronica Garcia Hansen, Ken Yeang, and Ian Edmonds were awarded the Far East Economic Review Innovation Award in bronze for this development.[8][9]

Light transmission efficiency is greatest if the tube is short and straight. In longer, angled, or flexible tubes, part of the light intensity is lost. To minimize losses, a high reflectivity of the tube lining is crucial; manufacturers claim reflectivities of their materials, in the visible range, of up to almost 99.5 percent.[10][11]

At the end point (the point of use), a diffuser spreads the light into the room.

The first full-scale passive horizontal light pipes were built at the Daylight Lab at Texas A&M University, where the annual daylight performance was thoroughly evaluated in a 360 degree rotating 6 m wide by 10 m deep room. The pipe is coated with a 99.3% specular reflective film and the distribution element at the end of the light pipe consists of a 4.6 m long diffusing radial film with an 87% visible transmittance. The light pipe introduces consistently illuminance levels ranging between 300 and 2,500 lux throughout the year at distances between 7.6 m to 10 m.[12]

To further optimize the use of solar light, a heliostat can be installed which tracks the movement of the sun, thereby directing sunlight into the light tube at all times of the day as far as the surroundings' limitations allow, possibly with additional mirrors or other reflective elements that influence the light path. The heliostat can be set to capture moonlight at night.

Optical fiber

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Optical fibers can also be used for daylighting. A solar lighting system based on plastic optical fibers was in development at Oak Ridge National Laboratory in 2004.[13][14] The system was installed at the American Museum of Science and Energy, Tennessee, USA, in 2005,[15] and brought to market the same year by the company Sunlight Direct.[16][17] However, this system was taken off the market in 2009.

In view of the usually small diameter of the fibers, an efficient daylighting set-up requires a parabolic collector to track the sun and concentrate its light. Optical fibers intended for light transport need to propagate as much light as possible within the core; in contrast, optical fibers intended for light distribution are designed to let part of the light leak through their cladding.[18]

Optical fibers are also used in the Bjork system sold by Parans Solar Lighting AB.[19][20] The optic fibers in this system are made of PMMA (PolyMethyl MethAcrylate) and sheathed with Megolon, a halogen-free thermoplastic resin. A system such as this, however, is quite expensive.[21]

The Parans system[22] consists of three parts. A collector, fiber optic cables, and luminaires spreading the light indoors. One or more collectors are placed on or near the building in a place where they will have good access to direct sunlight. The collector consists of lenses mounted in aluminum profiles with a covering glass as protection. These lenses concentrate sunlight down in the fiber optic cables.

The collectors are modular, which means they come with either 4,6,8,12 or 20 cables depending on the need. Every cable can have an individual length. The fiber optic cables transport the natural light 100 meters (30 floors) in and through the property while retaining both a high level of light quality and light intensity. Examples of implementations are Kastrup Airport, University of Arizona and Stockholm University.

A similar system, but using optical fibers of glass, had earlier been under study in Japan.[23]

Corning Inc. makes Fibrance Light-Diffusing Fiber. Fibrance works by shining a laser through a light-diffusing fiber optic cable. The cable gives off a lighted glow.[24]

Optical fibers are used in fiberscopes for imaging applications.

Transparent hollow light guides

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A prism light guide was developed in 1981 by Lorne Whitehead, a physics professor at the University of British Columbia,[25][26] and has been used in solar lighting for both the transport and distribution of light.[27][28] A large solar pipe based on the same principle was set up in the narrow courtyard of a 14-floor building of a Washington, D.C. law firm in 2001,[29][30][31][32][33] and a similar proposal has been made for London.[34] A further system has been installed in Berlin.[35]

The 3M company developed a system based on optical lighting film[36] and developed the 3M light pipe,[37] which is a light guide designed to distribute light uniformly over its length, with a thin film incorporating microscopic prisms,[26] which has been marketed in connection with artificial light sources, e.g. sulfur lamps.

In contrast to an optical fiber which has a solid core, a prism light guide leads the light through air and is therefore referred to as a hollow light guide.

The project ARTHELIO,[38][39] partially funded by the European Commission, was an investigation in years 1998 to 2000 into a system for adaptive mixing of solar and artificial light, and which includes a sulfur lamp, a heliostat, and hollow light guides for light transport and distribution.

Disney has experimented with using 3D printing to print internal light guides for illuminated toys.[40]

Fluorescence based system

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In a system developed by Fluorosolar and the University of Technology, Sydney, two fluorescent polymer layers in a flat panel capture short wave sunlight, particularly ultraviolet light, generating red and green light, respectively, which is guided into the interior of a building. There, the red and green light is mixed with artificial blue light to yield white light, without infrared or ultraviolet. This system, which collects light without requiring mobile parts such as a heliostat or a parabolic collector, is intended to transfer light to any place within a building. [41][42][43] By capturing ultraviolet, the system can be especially effective on bright but overcast days; this is since ultraviolet is diminished less by cloud cover than are the visible components of sunlight.

Properties and applications

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Solar and hybrid lighting systems

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A simple light tube, showing the collection, transmission, and distribution

Solar light pipes, compared to conventional skylights and other windows, offer better heat insulation properties and more flexibility for use in inner rooms, but less visual contact with the external environment.

In the context of seasonal affective disorder, it may be worth considering that an additional installation of light tubes increases the amount of natural daily light exposure. It could thus possibly contribute to residents´ or employees´ well-being while avoiding over-illumination effects.

Compared to artificial lights, light tubes have the advantage of providing natural light and of saving energy. The transmitted light varies over the day; should this not be desired, light tubes can be combined with artificial light in a hybrid set-up.[27][44][45][46]

Some artificial light sources are marketed which have a spectrum similar to that of sunlight, at least in the human visible spectrum range,[47][48][49] as well as low flicker.[49] Their spectrum can be made to vary dynamically such as to mimic changes in natural light over the day. Manufacturers and vendors of such light sources claim that their products can provide the same or similar health effects as natural light.[49][50][51] When considered as alternatives to solar light pipes, such products may have lower installation costs but do consume energy during use; therefore they may well be more wasteful in terms of overall energy resources and costs.

On a more practical note, light tubes do not require electric installations or insulation and are thus especially useful for indoor wet areas such as bathrooms and pools. From a more artistic point of view, recent developments, especially those pertaining to transparent light tubes, open new and interesting possibilities for architectural lighting design.[citation needed]

Security applications

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Due to the relatively small size and high light output of sun pipes, they have an ideal application to security-oriented situations, such as prisons, police cells, and other locations where restricted access is required. Being of narrow diameter, and not largely affected by internal security grilles, this provides daylight to areas without providing electrical connections or escape access, and without allowing objects to be passed into a secure area.

In electronic devices

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Light pipes,[52][53] as they are referred to in the electronics industry, are commonly used for directing light in electronic devices.

Configurations of light pipes can vary widely, from simple, consisting of pre-made rods cut to length, to highly complex custom molded or machined shapes. Light pipes are usually made from acrylic or polycarbonate optical fibers, or solid transparent acrylic or polycarbonate polymers. Sometimes other transparent plastics are used. The source of illumination, is from LEDs on a circuit board or other internal location, to indicator symbols or buttons on the exterior of the device's enclosure.

Different colors of light can be displayed in several ways. Tinting the light pipe material, using a colored light pipe lens, or using a single color LED, are used to produce a permanent single color. Multiple colors can be displayed by using a clear light pipe with an RGB, RGBW, or RGBWW LED. Older designs have used two or more individual color LEDs routed from the indicator on the display panel to the same light pipe.

The configuration of these light pipes can vary greatly. Simpler light pipes designs may be made from a straight, cylindrical rod, or may be bent with multiple gentle curves preserving the smooth uniform shape of the cylinder walls. Alternatively a flexible optical fiber light pipe may be used. Complex designs of molded or machined configurations, commonly take on a highly elaborate shape that uses either gentle curving bends as in an optic fiber or has sharp prismatic folds which reflect off the angled corners. Multiple light pipes are often molded or machined from a single piece of plastic, permitting easy device assembly since the long thin light pipes are all part of a single rigid component that snaps into place.

Light pipe indicators make electronics cheaper to manufacture since the old way would be to mount a tiny lamp into a small socket directly behind the spot to be illuminated. This often requires extensive hand labor for installation and wiring. Light pipes permit all lights to be mounted on a single flat circuit board, but illumination can be directed up, and away from the board wherever it is required.

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  • The video game franchise Portal uses light tubes to bring sunlight to the underground facility of Aperture Science to convert into hard light.
  • In Neon Genesis Evangelion light tubes allow the subterranean geofront to receive sunlight.

See also

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Light tube

View on Grokipedia
from Grokipedia
A light tube, also known as a tubular daylighting device (TDD) or solar tube, is a passive architectural system that captures sunlight through a rooftop dome and transmits it via a highly reflective cylindrical tube to provide natural illumination in building interiors, offering an efficient alternative to traditional skylights or electric lighting. These devices typically feature three main components: a transparent or translucent acrylic dome mounted on the roof to collect sunlight from a wide angle, a smooth-walled tube—often 10 to 22 inches in diameter and lined with specular reflective material achieving up to 99.7% reflectivity—to minimize light loss over distances up to 30 feet, and a prismatic or diffusing lens at the ceiling to scatter light evenly across a room without direct glare or hotspots. The system operates on principles of total internal reflection and multiple specular reflections, directing daylight downward while blocking nearly all ultraviolet rays and with low solar heat gain. Invented in the mid-1980s as a solution for daylighting in spaces inaccessible to conventional windows, the modern light tube was first patented in 1986 by an Australian innovator, enabling easy retrofits without structural alterations to roofs or ceilings. Early applications focused on residential and commercial buildings, but adoption grew in the 1990s with advancements in reflective coatings and dome designs that improved light transmission efficiency to over 90% under optimal conditions. Light tubes provide notable benefits, including substantial energy savings—up to 74.6% reduction in lighting electricity use in daylit buildings—lower cooling loads due to minimal heat transfer, and enhanced occupant well-being through exposure to natural spectrum light, which studies link to 7-18% improvements in productivity and mood in educational and office settings. They are particularly effective in climates with abundant sunlight, delivering illumination equivalent to 800-1,200 lumens per unit, comparable to a 60-watt incandescent bulb, while costing $600–$1,100 (as of 2025) to install depending on length and size. Commonly applied in homes for bathrooms, closets, and hallways; in commercial spaces like retail corridors and warehouses; and in institutions such as schools and hospitals, light tubes support sustainable design by integrating with LED hybrids for 24-hour use and complying with green building standards like LEED for daylighting credits. Their compact footprint—requiring only a 14- to 22-inch roof penetration—makes them versatile for both new construction and renovations, though performance varies with roof pitch, tube length, and latitude, with optimal output in clear weather.

Fundamentals

Definition and basic principles

A light tube, also known as a light pipe or solar tube, is a passive optical device that transmits natural or artificial light from a source to a destination, typically using internal reflection to minimize loss. These devices function without requiring electrical power, relying instead on the optical properties of materials to direct light efficiently over distances. The fundamental principle of operation in many light tubes is total internal reflection (TIR), which confines light rays within the guiding medium by ensuring they reflect completely at the boundaries rather than refracting out. TIR occurs when light in a denser medium (higher refractive index) encounters an interface with a rarer medium (lower refractive index) at an incident angle exceeding the critical angle, resulting in 100% reflection without absorption or transmission losses at the interface. This process is described by Snell's law of refraction: n1sinθ1=n2sinθ2n_1 \sin \theta_1 = n_2 \sin \theta_2 where n1n_1 and n2n_2 (n1>n2n_1 > n_2) are the refractive indices of the incident and second medium, respectively, and θ1\theta_1 and θ2\theta_2 are the angles of incidence and refraction. At the onset of TIR, θ2=90\theta_2 = 90^\circ, defining the critical angle as: θc=arcsin(n2n1)\theta_c = \arcsin\left( \frac{n_2}{n_1} \right) Light rays entering the tube at angles greater than θc\theta_c undergo repeated TIR along the length, propagating the beam with high fidelity. In variants using mirrored surfaces, such as hollow reflective tubes, specular reflection achieves a similar guiding effect through highly polished coatings, often exceeding 98% reflectivity per bounce. Typical components of a light tube include an entry aperture, such as a transparent dome on the exterior to maximize capture of incoming light rays; a transmission path, which may consist of a reflective tube, solid rod, or bundle of optical fibers to channel the light; and an exit diffuser at the destination to scatter the output evenly, preventing glare and ensuring uniform illumination. These elements work together to maintain light intensity while adapting to structural constraints like bends or varying lengths. Unlike microscopic optical waveguides in integrated photonics, which rely on wave interference and modal confinement for coherent electromagnetic signals in sub-wavelength structures, light tubes are macroscopic systems designed for the propagation of non-coherent, visible-spectrum light using geometric ray optics approximations. This scale enables practical applications in bulk light transport without the need for nanoscale fabrication.

Historical development

The concept of guiding natural light into enclosed spaces traces its origins to ancient Egyptian architecture around 2500 BCE, where reflective shafts and surfaces in structures like tombs and temples were employed to channel sunlight, though these were not enclosed tubes but precursors relying on basic reflection principles. In the 19th century, early heliostats—movable mirrors designed to track and redirect sunlight—emerged as a technological precursor, with developments in the 1830s enabling focused illumination for scientific and architectural purposes, laying groundwork for later light transmission systems. The first commercial reflector systems were patented and marketed in the 1850s by Paul Emile Chappuis in London, using various forms of angled mirror designs to transmit daylight into buildings, serving as precursors to modern enclosed light pipes. This innovation evolved through the 20th century, but widespread adoption awaited advancements in materials. In 1986, Australian inventor Steve Sutton patented the first tubular daylighting device (TDD), a highly reflective tube system that captured roof-level sunlight and delivered it indoors without structural modifications, revolutionizing passive lighting. Commercialization accelerated in the 1990s, with Solatube International launching its TDD products in 1991, achieving millions of installations worldwide by emphasizing leak-proof design and superior light diffusion over traditional skylights. By the 2000s, key enhancements included integration of UV-blocking coatings in reflective tubing to mitigate material degradation from solar exposure, extending system longevity in harsh environments. These developments aligned with growing sustainability focus; by 2005, TDDs contributed to LEED certification under daylighting credits in the USGBC's rating system, supporting energy-efficient building standards. Post-2010 advancements introduced hybrid systems combining solar TDDs with LED supplementation, as seen in Solatube's 2012 launch of integrated daylight-LED fixtures, enabling consistent illumination regardless of weather while harnessing total internal reflection for efficient light propagation. In the 2020s, innovations continued with smart tubular daylighting devices incorporating sensors for automated light control and advanced reflective materials achieving over 99% efficiency, supporting net-zero building initiatives as of 2025.

Types

Reflective light tubes

Reflective light tubes, also known as tubular daylighting devices, consist of cylindrical or rectangular conduits typically 10 to 14 inches in diameter, lined with highly reflective interior surfaces to guide sunlight from an exterior entry point to interior spaces. These linings often employ aluminum or silver-based coatings, achieving reflectivity rates of 98% to 99% per reflection, which minimizes light loss during transmission. The tube's exterior is usually insulated with a protective sheath to prevent heat transfer and condensation, while the entry is capped by a transparent acrylic or glass dome on the roof to capture diffuse and direct sunlight. In operation, sunlight enters the dome and travels down the tube through a series of internal reflections off the mirrored walls, emerging diffused through a ceiling lens to illuminate rooms without significant color distortion. The light intensity after transmission, II, can be approximated by the formula I=I0RL/d,I = I_0 \cdot R^{L/d}, where I0I_0 is the initial intensity, RR is the reflectivity per bounce (typically 0.98–0.99), LL is the tube length, and dd is the diameter, with L/dL/d estimating the approximate number of reflections. This specular reflection preserves the light's spectral neutrality, delivering natural illumination equivalent to several 60-watt bulbs on clear days. These systems offer advantages including low installation costs—often one-third that of traditional skylights—and straightforward retrofitting through attics with minimal structural modifications. They support tube lengths up to 10 meters while retaining 50–70% of incoming light, depending on reflectivity and path straightness, making them suitable for single-story homes. However, rigid variants are sensitive to bends, necessitating mostly straight paths to avoid excessive light scattering and reduced efficiency, and over time, any internal dust accumulation from rare leaks can lower reflectivity by absorbing stray particles. Commercial examples include the VELUX Sun Tunnel, introduced in the 1990s, which uses a 99% reflective rigid aluminum tube for unobstructed runs up to 20 feet, providing bright, even daylight in hallways and bathrooms. Similarly, Solatube's rigid models employ Spectralight Infinity coating with 99.7% reflectivity, enabling efficient light delivery over comparable distances.

Optical fiber-based systems

Optical fiber-based systems utilize bundles of thin glass or plastic fibers to transmit light along compact or curved paths, enabling applications where straight-line propagation is impractical. Each fiber features a core-cladding structure, where the core has a higher refractive index (ncoren_{\text{core}}) than the surrounding cladding (ncladdingn_{\text{cladding}}), facilitating total internal reflection (TIR) to confine light within the core. Light enters the fiber at an acceptance angle determined by the numerical aperture (NA), calculated as NA=ncore2ncladding2NA = \sqrt{n_{\text{core}}^2 - n_{\text{cladding}}^2}
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