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Spectralon

Spectralon is a sintered polytetrafluoroethylene (PTFE) fluoropolymer material renowned for its exceptionally high diffuse reflectance, exceeding 99% from 400 nm to 1500 nm and greater than 95% from 250 nm to 2500 nm across the ultraviolet (UV), visible, and near-infrared (NIR) spectrum. Developed and commercialized by Labsphere, Inc. in 1986, it exhibits near-perfect Lambertian diffusion, meaning it scatters light uniformly in all directions without specular reflection, making it an ideal reference standard for optical measurements. With a hardness comparable to high-density polyethylene and thermal stability up to over 400°C, Spectralon is chemically inert, hydrophobic, and environmentally durable, allowing it to withstand harsh conditions without degrading its reflectance properties. This material's superior performance surpasses traditional coatings like paints, offering a flat spectral response and NIST-traceable for precise applications. Key uses include integrating spheres, spectrophotometers, and densitometers for laboratory , as well as on-orbit standards for Earth-observing satellites in , where it serves as a vicarious with uncertainties as low as 2%. Space-grade variants undergo specialized and to ensure reliability in extraterrestrial environments, supporting missions in and . Its enables custom shapes for optical components, from s to diffusers, while variants like color pastels provide controlled reflectance levels for specialized testing.

Physical and Optical Properties

Composition and Structure

Spectralon is a sintered form of (PTFE), a synthetic fluoropolymer produced through the of monomers. This composition results in a highly stable, white solid material optimized for optical applications, where PTFE particles are compressed and heated to form a cohesive structure without melting the polymer. At the microscopic level, Spectralon exhibits a porous, open-cell formed by the of PTFE particles at elevated temperatures, creating an interconnected void structure within the solid matrix. This results in a diffuse, white appearance, which contributes to its bulk properties. The leads to a of approximately 1.2 g/cm³, significantly lower than that of solid PTFE (around 2.2 g/cm³), reflecting the material's high void volume of about 40%. Chemically, Spectralon inherits PTFE's exceptional inertness, demonstrating resistance to most solvents, acids, bases, and , with the exception of highly reactive substances like or organo-sodium compounds. This stability is further evidenced by the absence of bands in the ultraviolet-visible-near-infrared (UV-VIS-NIR) range, ensuring minimal interaction with light in these wavelengths.

Reflectance Characteristics

Spectralon is renowned for its exceptionally high diffuse , which exceeds 99% across the visible to near-infrared (400–1500 ) and remains above 95% over the broader to near-infrared range (250–2500 ), approaching 100% in the visible region. This performance stems from Lambertian scattering, where light undergoes multiple internal reflections within the material's porous structure composed of sintered (PTFE), effectively redirecting nearly all incident radiation in a uniform, non-directional manner. The material's reflectance variance is less than 5% from 250 to 2500 and under 0.5% in the visible band (360–740 ), ensuring spectral flatness suitable for precision optical applications. The (BRDF) of Spectralon adheres closely to the ideal cosine law characteristic of perfect diffuse reflectors, demonstrating near-Lambertian behavior across its wavelength range. Measurements indicate minimal deviations from this ideal, particularly for incidence angles up to 60°, with the specular component remaining very low—typically contributing less than 1% to the total under various illumination conditions. This low specular reflectance arises from the diffuse nature of the , suppressing mirror-like reflections and promoting isotropic light distribution. Reflectance in Spectralon exhibits mild dependence, maintaining high values within its primary operational band but showing a gradual decline below 250 nm and above 2000 nm due to inherent absorption bands in the . In the and extended near-infrared, these absorptions reduce efficiency slightly, though the material still outperforms alternatives like coatings. Additionally, Spectralon's polarimetric properties feature a low degree of in the scattered light, with the average absolute degree of measured at less than 0.01 across visible wavelengths, rendering it an excellent standard for unpolarized reference measurements. This depolarizing effect further enhances its utility in applications requiring isotropic, polarization-insensitive .

Durability and Limitations

Spectralon demonstrates moderate mechanical , with a rating of 20–30 Shore D, comparable to , allowing it to be machined like a soft using standard tools at high speeds and low feed rates. However, its is relatively low, featuring a of 208 (approximately 1.4 ) and an ultimate of 891 (approximately 6.1 ), which makes it susceptible to deformation under excessive during handling or fabrication. Despite this, the material's porous structure provides inherent flexibility, though it remains prone to surface scratching from abrasives or contaminants, necessitating careful manipulation with gloves to preserve optical performance. In terms of environmental stability, Spectralon is thermally robust, remaining unchanged up to temperatures exceeding 350°C before decomposition begins above 400°C, with a low coefficient of linear of 5.5–6.5 × 10⁻⁵ in/in °F. It is non-hygroscopic, exhibiting water permeability below 0.001%, which ensures consistent performance in humid conditions without swelling or shifts. Under prolonged UV , however, can occur, particularly in accelerated testing; for instance, drops by 5–10% in the UV range after 110 equivalent sun hours, accompanied by slight yellowing and up to 20% loss after 500 sun hours, though these effects are often reversible upon re-exposure to atmospheric oxygen. Long-term natural outdoor yields minimal impact, such as a 0.2% at 400 nm over 1.5 years. Regarding , Spectralon shows high resistance to atomic oxygen (up to 5.3 × 10²⁰ ions/cm²) and protons (10¹² protons/cm² at 40 keV) with no observable optical or physical changes, but vacuum ultraviolet (VUV) irradiation can induce non-isotropic , resulting in up to 16% loss at 250 nm after 20 hours of . Key limitations of Spectralon include slight translucency in thin sections below 7 mm thick, which promotes and reduces effective —for example, dropping to 91% at 1060 nm for 1 mm thickness compared to 98% for 5 mm. The material is not entirely opaque, displaying minor in very thin samples, which can affect applications requiring absolute diffusion. Additionally, its porous nature renders it highly sensitive to contamination by non-polar substances like oils or greases, which embed into the surface and cause localized decreases that are challenging to fully reverse. To maintain integrity, Spectralon requires gentle cleaning protocols; light soiling can be addressed with a jet of clean dry air or , while heavier contamination involves sanding with 220–240 waterproof emery cloth under running , followed by drying. For routine surface , mild solvents such as spectrophotometric-grade are recommended, avoiding abrasives that could introduce scratches and further compromise the diffuse reflectance properties. In cases demanding enhanced UV resistance, post- treatments like vacuum baking at 75°C for 12 hours or flushing with high-purity deionized can mitigate potential sites.

Manufacturing and Variants

Production Process

Spectralon is manufactured starting with high-purity (PTFE) powder, derived from the of gas under controlled conditions to ensure minimal impurities. The powder particles are typically smaller than 50 μm, with specific grades using sizes around 20 μm to promote the desired and after processing. The production process employs a technique to form durable plaques or blocks. The PTFE is first compressed at in a under moderate , achieving a pre-sintering of 1.0–1.2 g/cm³, which yields a fragile but cohesive "" body with approximately 30–50% void volume. This step avoids high temperatures initially to prevent premature . The compressed form is then sintered by heating to 360–370°C for several hours (often exceeding 4 hours, depending on block size) at . At this temperature, just above the of PTFE (327°C) but below full , the particles bond at contact points through solid-state , creating a , porous matrix without altering the overall structure. A controlled, slow cooling follows to minimize thermal stresses that could lead to cracks or dimensional instability. Post-sintering, the material is machined into final shapes—such as flat plates, integrating spheres, or calibration targets—using precision computer numerical control (CNC) lathes and mills in a clean-room environment to prevent . Surface finishing techniques, including fly-cutting or wet sanding with abrasives, ensure uniform and a diffuse that enhances . The resulting porous , with roughly 40% void content, underpins its exceptional diffuse properties. Quality assurance includes measurements calibrated against National Institute of Standards and Technology (NIST) reference standards, such as SRM 2044, to verify performance across the UV-VIS-NIR . Manufacturing controls limit batch variations, achieving uniformity better than 1% (often <0.5% in the visible range) through consistent powder blending and process monitoring.

Grades and Customization

Spectralon is offered in standard grades designed for general laboratory and calibration needs, with the SRM-99 grade providing over % diffuse across the UV-VIS-NIR spectrum (250–2500 nm), establishing it as the highest-performing option for precision applications. The SRM-50 grade, featuring approximately 50% reflectance, serves as a reliable gray reference for calibration and comparative measurements, offering a balanced alternative to the high-reflectance variant. These grades are machinable into thicknesses typically ranging from a minimum of 7 mm for optimal performance up to 50 mm, allowing flexibility in component design. For demanding environments like space missions, space-grade Spectralon undergoes enhanced purification processes, including special cleaning, vacuum baking, and nitrogen-purged packaging to minimize contaminants. This variant has been rigorously tested by facilities such as the Jet Propulsion Laboratory and Goddard Space Flight Center for exposure to UV radiation, proton bombardment, atomic oxygen, and alpha-Lyman radiation, confirming its stability with minimal reflectance degradation under harsh conditions. It maintains >99% diffuse reflectance while exhibiting exceptional Lambertian behavior and thermal stability, making it suitable for satellite instrumentation. Customization options enable tailored formulations, such as doping with additives like to achieve tuned reflectance levels from 2% to 99%, accommodating specific optical requirements beyond standard grades. Spectralon can be shaped into specialized forms, including hemispherical domes or components for integrating spheres, to support advanced photometric systems. Alternative variants like Fluorilon and provide comparable diffuse reflectance properties as (ODM) options for varied production needs. Labsphere's in-house capabilities support prototyping of complex geometries, with optical-grade tolerances of ±0.005 inches (approximately ±0.13 mm) for dimensions up to 4 inches, ensuring precise fabrication for applications. Space-grade offers slightly relaxed tolerances of ±0.010 inches to balance durability and precision in contexts.

Applications

Calibration and Standards

Spectralon serves as a NIST-traceable for calibrating spectrophotometers and other optical instruments, providing calibrated targets that validate measurements with an accuracy of ±4% over the photopic . These standards, typically in the form of diffuse targets, enable precise determination of instrument and response across UV, visible, and near-infrared wavelengths. Labsphere's Spectralon standards, certified against NIST measurements, ensure through rigorous bidirectional factor (BRDF) calibrations, minimizing errors in quantitative . In integrating spheres, Spectralon coatings on the interior walls facilitate uniform light distribution for accurate flux measurements by promoting Lambertian scattering, which averages incident over multiple reflections. This uniformity, enhanced by Spectralon's high (>95% from 350 to 1350 ), supports applications in and photometry where precise total or must be determined. The sphere's efficiency, crucial for , accounts for losses due to and port fractions; a key metric is the sphere multiplier M = \frac{1}{1 - R(1 - f)}, where R is the average wall and f is the total port fraction, derived from the radiant flux balance equation L = \frac{F_i \cdot R}{(1 - R(1 - f)) \cdot A_s} for sphere radiance L, input flux F_i, and internal surface area A_s. Spectralon's low-polarization properties make it ideal for in optical systems, serving as a reference for validating sources through Mueller matrix measurements. Its produces nearly depolarized output, with fractions below 1% in the near-infrared, enabling accurate assessment of instrument response to isotropic radiation. This characteristic, stemming from the material's random multiple in sintered PTFE, ensures reliable of polarimeters and systems without introducing bias from partial . Maintenance of Spectralon standards involves strict protocols to mitigate from UV exposure or contaminants, including in , controlled environments and periodic cleaning with dry air or deionized rinses. Due to potential solarization—a lowering of of 5-10% in the UV after 110 sun hours and slight yellowing in the visible after 500 sun hours—recalibration is recommended annually or from the first use date, with maintained to units via NIST-certified facilities. Proper handling, such as wearing gloves and avoiding vapors, preserves , ensuring long-term reliability as a reference.

Remote Sensing and Spectroscopy

Spectralon serves as a critical material in applications, particularly for the radiometric of instruments. For instance, the (MODIS) on NASA's and Aqua satellites employs an on-board solar diffuser panel constructed from Spectralon to track changes in sensor responsivity over time, ensuring accurate radiance measurements across its reflective solar bands. This is essential for atmospheric correction algorithms in studies of vegetation indices and , where precise knowledge of surface enables the removal of effects from aerosols and molecules, thereby improving the retrieval of biophysical parameters like concentration. Similarly, ground-based Spectralon panels are deployed as vicarious targets for various sensors, providing stable, high-reflectance surfaces to validate on-orbit performance and correct for degradation in visible and near-infrared bands. The material's near-Lambertian properties make it ideal for these roles, offering a predictable (BRDF) that minimizes angular dependencies in data. In spectroscopy, Spectralon functions as a primary diffuse reflectance standard for ultraviolet-visible (UV-VIS) and infrared (FTIR) spectrometers, facilitating absolute reflectance measurements through the comparison method. In UV-VIS setups, its spectrally flat reflectance—exceeding % from 400 to 1500 nm—allows samples to be measured relative to the standard, converting raw detector signals to quantitative reflectance spectra without needing transmittance configurations. For FTIR applications, particularly in the near- extending to mid-infrared regions, Spectralon standards enable hemispherical-directional reflectance () and diffuse reflectance measurements, as demonstrated in NIST validations where its % standard provided consistent baselines for rough or powdered samples despite minor absorptions around 2.1 µm. This approach is widely adopted in for characterizing materials like catalysts or polymers, where the standard's uniformity ensures reproducible Kubelka-Munk transformations for deriving coefficients from reflectance data. Spectralon also plays a key role in by serving as a reference in laboratory simulations of lunar and Martian surfaces for calibrating in the visible-near-infrared (VIS-NIR) . In these setups, its high, stable provides a baseline for measuring the bidirectional of simulants, such as JSC-1A for lunar highlands or Mojave Mars Simulant for basaltic terrains, allowing researchers to quantify the analogs' lower (typically 5-20%) and phase functions that mimic extraterrestrial soils. This is crucial for validating hyperspectral imagers on missions like or upcoming lunar rovers, where accurate VIS-NIR spectra (250-2500 nm) help interpret compositions and volatile signatures without the need for direct sample return. Compared to alternatives like pressed powders or specialized paints, Spectralon offers superior long-term stability and broader wavelength coverage, making it the preferred choice for demanding scientific environments. Pressed powders, while effective in UV-VIS, are hygroscopic and prone to under humidity or mechanical stress, leading to inconsistent over time. Paints, often based on , exhibit strong UV absorptions and poor durability or high-radiation settings, whereas Spectralon's composition remains chemically inert, thermally stable up to 350°C, and maintains >95% from 250 to 2500 nm with minimal after extended exposure. These attributes ensure higher accuracy in serial measurements, reducing systematic errors in and spectroscopic datasets.

Other Industrial Uses

Spectralon serves as a high-performance reflector in LED fixtures and projectors, where its near-Lambertian diffuse properties enable uniform distribution across illumination surfaces. By minimizing loss and enhancing beam stability, Spectralon components contribute to more efficient output in systems and large-area LED displays, allowing for optimized energy use in backlighting applications. In medical devices, Spectralon targets are employed for white balancing in and systems, providing a stable, high-reflectance reference that ensures accurate color reproduction during procedures. Its chemical inertness and make it suitable for disposable standards in diagnostic equipment, reducing contamination risks in sensitive biomedical environments. Spectralon's space-grade variants are integrated into applications as light traps and baffles in optical s, where the material's diffuse properties help suppress interference and maintain in harsh orbital conditions. In automotive s, such as those for and , Spectralon components aid in calibrating for reliable detection under varying lighting. Additionally, its allows for custom fabrication of these components to fit specific geometries. For art conservation, Spectralon provides non-destructive reflectance standards that facilitate precise pigment analysis in museums, enabling hyperspectral imaging to identify and document material compositions without altering artifacts. These standards offer consistent, spectrally flat reflectance across UV-VIS-NIR ranges, supporting the evaluation of color fidelity and degradation in historical artworks.

History and Development

Origins and Invention

Research into precursor materials for high-reflectance standards began in the with explorations of (PTFE) for stable reflective coatings, driven by the limitations of existing options like and , which suffered from degradation and moisture absorption. A key advancement came with the development of pressed PTFE formulations, patented in 1973, which achieved over 90% reflectance in the and were suitable for applications in and integrating spheres. Building on this foundation, the late 1970s and early 1980s saw further investigation into sintered PTFE's optical properties at the National Bureau of Standards (now NIST), where researchers V. R. Weidner and J. J. Hsia demonstrated that properly pressed and sintered PTFE powder, such as DuPont's Teflon, exhibited near-ideal diffuse reflectance with minimal angular dependence. These studies highlighted PTFE's potential as a superior alternative for calibration standards in optical instrumentation, particularly for satellite applications like the Coastal Zone Color Scanner (CZCS) launched in 1978. Spectralon was invented in the mid-1980s at Labsphere Inc. by engineer Arthur W. Springsteen, who refined a high-purity process for PTFE to create a machinable material with diffuse reflectance exceeding 99% from the to near-infrared. Springsteen passed away in June 2024. This patented method optimized particle packing density and void volume to enhance light scattering while ensuring and up to 400°C, addressing the instability of prior standards. Initial prototypes of Spectralon were tested in the mid-1980s within integrating spheres for radiometric applications, where they demonstrated exceptional longevity and uniformity compared to or , which often degraded under environmental exposure. These tests confirmed Spectralon's suitability as a durable diffuse reflector, paving the way for its adoption in precision optics.

Commercialization and Advancements

Spectralon was commercialized by Labsphere Inc. in 1986 as a sintered fluoropolymer diffuse reflectance material, initially targeting applications in spectroscopy laboratories for calibration and reference standards. This launch marked the transition from earlier packed PTFE standards to a more stable, machinable form, enabling precise optical component fabrication. Early adoption was swift, particularly by the National Institute of Standards and Technology (NIST), which integrated Spectralon into its radiometric scales for bidirectional reflectance factor measurements in the visible and near-infrared regions shortly after its introduction. NIST-traceable calibrations using Spectralon ensured high accuracy in optical radiation measurements, solidifying its role in establishing industry standards. In the 1990s, Labsphere advanced Spectralon toward space applications through qualification testing, including optical evaluations on flights that simulated harsh orbital conditions. This led to the development of space-grade variants, optimized for vacuum compatibility and thermal stability, which were deployed in missions such as the Observing-1 (EO-1) satellite in 2000 for on-orbit diffuser . By the 2000s, doped formulations emerged, incorporating black pigments to create gray-scale versions with controlled reflectance levels (e.g., 2% to 99%) for enhanced testing in . These advancements expanded Spectralon's utility in instruments like the (MODIS) on 's and Aqua satellites, where space-grade panels provided stable solar diffuser references. The 2010s saw further refinements in space-grade Spectralon, focusing on radiation hardness and outgassing minimization to withstand prolonged exposure in deep-space environments; these variants have supported over 20 missions as primary on-board calibration tools. Concurrently, competitors entered the , with Avian Technologies introducing Fluorilon in the late as a similar sintered PTFE offering comparable diffuse properties. Labsphere maintained a dominant position, holding a significant share of the diffuse reflectance materials by 2020 due to its established NIST traceability and broad adoption in and photometry. Recent developments as of have emphasized UV performance, with Labsphere's introduction of Extreme Physics and Vacuum (EPV) Spectralon featuring a purified for superior below 300 nm, addressing in high-UV applications like LED measurement and deep-UV . This innovation supports emerging needs in UV sanitization and curing, while the material's continues to enable custom without integration into additive .

References

  1. [1]
    [PDF] Spectralon® Diffuse Reflectance Material - Labsphere
    Labsphere's Spectralon Diffuse Reflectance Material. SRM-99 is a high diffuse reflectance material for applications over the UV-VIS-NIR region of the spectrum.
  2. [2]
    SPIE 9639-49 Creation and Validation of Spectralon BRDF Targets ...
    Oct 12, 2015 · Spectralon is an extremely stable, near-perfect lambertian reflecting diffuser and calibration standard material that has been used by ...
  3. [3]
    Space Grade Spectralon® Diffuse Reflectance Material - Labsphere
    Space-Grade Spectralon is developed using an advanced manufacturing process that involves special cleaning and baking procedures, rigid inspection, special ...Missing: history | Show results with:history<|control11|><|separator|>
  4. [4]
    [PDF] Spectralon® Diffuse Reflectance Material - Labsphere, Inc
    Spectralon diffuse reflectance material is a thermoplastic resin that can be machined into a wide variety of shapes for the construction of optical components. ...
  5. [5]
    [PDF] Ultraviolet stability and contamination analysis of Spectralon diffuse ...
    A detailed chemical analysis was carried out on Spectralon, a highly Lambertian, diffuse reflectance material. Results of this investi- gation unambiguously ...
  6. [6]
    [PDF] Spectralon® Reflectance Material Design and Machining Guidelines
    Spectralon is a porous, flexible, thermoplastic material. As such, it is prone to distortion and stress, particularly in applications requiring thin sections or ...Missing: PTFE structure
  7. [7]
    [PDF] Ultraviolet Reflectance of Microporous PTFE | Porex
    This paper presents the reflective properties of porous PTFE in the 250 nm to. 500 nm range and correlates reflectance with porosity and thickness. Porous PTFE ...
  8. [8]
    [PDF] Reflectance Coatings and Materials | Labsphere
    Spectralon diffuse reflectance material is a thermoplastic resin that can be machined into a wide variety of shapes for the construction of optical components.Missing: composition | Show results with:composition
  9. [9]
    Spectralon® Diffuse Reflectance Standards
    Spectralon Diffuse Standards offer the highest diffuse reflectance values of any known substance, housed in a durable Delrin holder with a protective cover.Missing: history | Show results with:history
  10. [10]
    https://opg.optica.org/ao/abstract.cfm?uri=ao-50-16-2431
  11. [11]
    Bidirectional reflectance distribution function of Spectralon white ...
    Jun 1, 2011 · Our measurements show deviations of the BRDF for the Spectralon white reflectance standard from that of a Lambertian ... specular reflection ...
  12. [12]
    Spectral Dependent Degradation of the Solar Diffuser on Suomi ...
    The diffuse reflectance of Spectralon is generally >99% for 400 nm to 1500 nm wavelength range and >95% for a wider wavelength range from 250 nm to 2.5 µm.
  13. [13]
    Polarized reflectance factors of vegetation covers from laboratory ...
    Dec 29, 2016 · We found that the average absolute value of degree of linear polarization of the Spectralon measured by using our instrument was less than 0.01 ...
  14. [14]
    Comprehensive polarimetric analysis of Spectralon white ...
    Since Spectralon was made up and commercialized by Labsphere Inc. in 1986 [1], it has been used in reflectometry as the closest commercial material to a perfect ...
  15. [15]
    [PDF] directional degradation of spectralon diffuser under ionizing ...
    The goal of the current study is to better understand the non-isotropic changes of Spectralon calibration standards caused by ionizing VUV irradiation. Although.
  16. [16]
    [PDF] Spectralon® Reflectance Material Care and Handling Guidelines
    These plasticizers readily absorb ultraviolet light and are a likely cause of yellowing in degraded cavities using Tygon in the coolant stream. sales ...Missing: loss | Show results with:loss
  17. [17]
    US5462705A - Method of forming diffusely reflecting sintered ...
    Such lack of machinability as well as the 2% lower reflectance at the wavelengths of interest make the 50 micron particle size desirable for PTFE granules.
  18. [18]
    Production of a diffuse very high reflectivity material for light ...
    PTFE powder (HOSTAFLON 1750, grain size: 20 μm , Hoechst, Germany) was used to produce raw reflector blocks. For our application, 470 g of PTFE material was ...
  19. [19]
    [PDF] SPACE GRADE SPECTRALON - Semantic Scholar
    The PTFE powder is pressed to a block. • Pressure released; block holds together, but is fragile. • Sintered to bind the particles together. • No additional ...
  20. [20]
    Spectralon® Diffuse Reflectance Material - Labsphere
    The material has hardness roughly equal to that of high-density polyethylene and is thermally stable to >400°C.Missing: composition | Show results with:composition
  21. [21]
    [PDF] Spectralon® Diffuse Reflectance Standards | Labsphere
    Each standard is supplied with complete diffuse reflectance data from 250 - 2500, every 50 nm. All standards are housed in a durable delrin holder with a ...
  22. [22]
    [PDF] Space-grade Spectralon® Reflectance Material - Labsphere
    Space-grade Spectralon is a diffuse reflectance material for space, with >99% reflectance, Lambertian profile, and is chemically and thermally stable.Missing: sintering temperature
  23. [23]
    [PDF] Optical-grade Spectralon® Reflectance Material - Labsphere, Inc
    The material has a hardness roughly equal to that of high-density polyethylene and is thermally stable to >400 °C.Missing: composition | Show results with:composition<|control11|><|separator|>
  24. [24]
    Comparison of methods for generation of absolute reflectance-factor ...
    The uncertainity of the directional, hemispherical reflectance factor of Spectralon is 0.5%, and the uncertainity of the NIST 45/0 reflectance factor is 0.3%.
  25. [25]
    [PDF] Integrating Sphere Theory and Applications | Labsphere, Inc
    Therefore, high reflectance integrating sphere materials such as. Spectralon can optimize spatial performance at only a slight tradeoff in radiance efficiency.
  26. [26]
    [PDF] Polarized Optical Scattering Signatures from Biological Materials
    Scattering from Spectralon standards [25] was measured ... total scattering with low polarization fractions at longer wavelengths similar to leaves.
  27. [27]
    Polarization scattering from a Spectralon calibration sample
    Aug 9, 2025 · The Spectralon is measured for both incident and scattering angles from -80 degrees to 80 degrees to within 20 degrees of retro-reflection. A ...
  28. [28]
    [PDF] Spectralon® Reflectance Standards Care and Handling Guidelines
    Blow dry with clean air or nitrogen or allow material to air dry. If the material requires high resistance to deep UV radiation, prepare the piece as above, and ...Missing: yellowing loss
  29. [29]
    [PDF] On-orbit Characterization of a Solar Diffuser s Bi-directional ...
    The MODerate Resolution Imaging Spectroradiometer (MODIS) uses an on-board solar diffuser (SD) panel made of. Spectralon for the radiometric calibration of ...
  30. [30]
    [PDF] MODIS Reflective Solar Bands On-orbit Calibration and Performance
    In order to ensure and maintain cali- bration and data quality over its entire mission, the MODIS instrument was designed with a set of on-board calibrators. ( ...
  31. [31]
    Spectralon reflectance calibration panels (25 × 25 cm) in images...
    ... This calibration is critical for compensating for variations in sunlight intensity during data acquisition, ensuring the accuracy of spectral analyses. The ...
  32. [32]
    Modeling of Spectralon diffusers for radiometric calibration in remote ...
    Aug 9, 2025 · We have modeled the measured BRDF calibration data of the Spectralon® diffusers used in the Medium Resolution Imaging Spectrometer (MERIS) ...
  33. [33]
    [PDF] hemispherical and diffuse reflectance measurements using an FTIR ...
    The average packing density of the sulfur is 0.78 g∕cm3. For each sample, 2048 scans were recorded for DHR and diffuse measurements. All sets were averaged to ...<|separator|>
  34. [34]
    [PDF] Diffuse Reflectance IR and UV-vis Spectroscopy - Fritz Haber Institute
    Dec 10, 2004 · White Standard Spectralon®. Spectralon® thermoplastic resin, excellent reflectance in UV-vis region. Page 34. © 2004 F.C. Jentoft, Fritz-Haber ...
  35. [35]
    Effects of Spectralon absorption on reflectance spectra of typical ...
    We demonstrate with laboratory reflectance measurements that the VisNIR spectra of three typical planetary surface analog materials, lunar simulant JSC-1A, ...
  36. [36]
    Effects of Spectralon absorption on reflectance spectra of typical ...
    Aug 26, 2014 · Spectralon is a sintered polytetrafluoroethylene (PTFE) plaque and InfraGold is a rough metal plate with gold coating. The different materials ...
  37. [37]
    Large, durable and low‐cost reflectance standard for field remote ...
    Aug 6, 2025 · ... The material of choice with the highest diffuse reflectance standard, Spectralon®, has an averaged reflectance factor of 99%. [10] A review ...
  38. [38]
    [PDF] Spectralon® Diffuse Color Standards | SphereOptics
    Spectralon Diffuse Color Standards aid in developing consistent color ... • LED sourced systems. • Solid state lighting. • Large area LED display.
  39. [39]
    Spectralon Disposable Calibration Standards for Medical Diagnostics
    Labsphere's innovation in disposable calibration standards has lead to numerous other uses for Spectralon components for the medical and biomedical ...
  40. [40]
    [PDF] Synthetic white balancing for intra-operative hyperspectral imaging
    Jul 24, 2023 · 1. However existing established references, such as 95% reflective Spectralon tiles, cannot be sterilized and are very sensitive, making them ...
  41. [41]
    Lidar Technology Overview - Labsphere
    LIDAR, or Light Detection and Ranging, uses pulsed laser and time of flight to measure distances, and is used in driverless vehicles.
  42. [42]
    Spectralon® Diffuse Color Standards - Consistent Color Reproduction
    Spectralon Diffuse Color Standards aid in developing consistent color reproduction for manufacturers of products such as textiles, papers, and more!
  43. [43]
    Hyperspectral Calibration of Art - Labsphere, Inc
    ... art. ... These are typically durable and chemically inert PTFE (Polytetrafluoroethylene) targets, the most widely used of which is Spectralon® manufactured by ...
  44. [44]
    https://patents.google.com/patent/US3764364A/en
  45. [45]
    [PDF] Optical Passive Sensor Calibration for Satellite Remote Sensing and ...
    Jun 24, 2014 · It is also known as. Dupont's Teflon® powder and Allied's Halon G-80™. ... sintered PTFE called. Spectralon™, which became the material of ...
  46. [46]
    US4912720A - Laser cavity material - Google Patents
    Polytetrafluoroethylene (PTFE), or like polymeric material is provided for use as a laser cavity material to efficiently couple flash lamp emissions into ...Missing: Spectralon | Show results with:Spectralon
  47. [47]
    https://opg.optica.org/ao/abstract.cfm?uri=ao-52-24-6051
  48. [48]
    Investigating the optical translucency of Spectralon using BSSRDF ...
    laboratories. Before the commercial production of sintered PTFE by. Labsphere in 1986, standards made of packed PTFE were. extensively studied by researchers ...
  49. [49]
    [PDF] Radiometric Measurement Comparison on the Integrating Sphere ...
    The NIST BRF values assigned to the Spectralon standard were based on absolute bi-direc- tional reflectance measurements for the visible and near infrared (to ...
  50. [50]
    EO-1 (Earth Observing-1) - eoPortal
    Just prior to solar calibration, a space-grade Spectralon® diffuser plate is swung over the secondary mirror by a motor-driven mechanism. The diffuser ...
  51. [51]
    [PDF] MODIS Level 1B Algorithm Theoretical Basis Document (Collection 7)
    Feb 21, 2025 · space-grade Spectralon™, a proprietary thermoplastic formulation of polytetrafluoroethylene. (PTFE). The SD bi-directional reflectance factor ...
  52. [52]
    [PDF] Absolute Low Uncertainty in Small Satellite Constellations - Labsphere
    Jul 29, 2024 · ... art systems for the testing and ... Labsphere has primarily contributed solutions based on our Space Grade Spectralon material in the form of ...
  53. [53]
    [PDF] Integrating Sphere Coatings- A Historical Perspective
    Trade names: Spectralon™ (Labsphere), Fluorilon™(Avian Technologies),. Op-Di-Ma™ (GigaHertz), Zenith™ (SphereOptics). (in order of development…) * for large ...Missing: competitors 1990s
  54. [54]
    Diffuse Reflectance Materials and Coatings Report Probes the XXX ...
    Rating 4.8 (1,980) Jun 11, 2025 · Key players such as Avian Technologies, Labsphere Inc., and PerkinElmer hold significant market share, but a number of smaller, specialized ...
  55. [55]
    Spectralon® EPV Diffuse Reflectance Material & Standards
    In stock Free deliverySpectralon EPV is a purified diffuse reflector for high energy applications, used in laser chambers, particle accelerators, and medical applications requiring ...
  56. [56]
    Spectralon EPV Diffuse Reflectance Material - Photonics Spectra
    In recent years, more and more applications have arisen on the terrestrial scene requiring a great diffuse reflector with a level of purity driven by.