FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2108764383> ?p ?o ?g. }

• W2108764383 endingPage "030305" @default.
• W2108764383 startingPage "030305" @default.
• W2108764383 abstract "Increased living standards in the developed world, as well as in developing countries, have made air conditioning very popular. It is estimated that energy consumption for air conditioning in developing countries will continuously increase from 115 TWh in 2005 to 757 TWh in 2030 [1]. In comparison, energy consumption for cooling residential spaces in the United States will level off and stay constant at around 200 TWh during the same period of time. Glass is widely used in commercial and residential buildings, and automobiles. For these applications, there is a tendency to increase the area covered by windows aiming at increased visual comfort and aesthetics. However, glass does not allow control over infrared (IR) radiation, and thus heat control through the windows is not possible. This way, IR radiation entering buildings and automobiles results in increased temperature. In the case of cars, windows contribute up to about 70% of the total heat, and nearly half of this figure is from windshields [2]. Moreover, energy used for room heating is lost by radiation through the windows. As such, efficient use of energy in air conditioning, i.e. control of IR radiation through windows, becomes desirable since it would result in reduced energy consumption, resulting in energy savings and contributing to reduce global warming. Highly transparent thermally reflective coatings are deposited onto glasses to be used in windows for the purpose of saving energy. These are generally termed spectrally selective coatings, and include solar-control coatings and low-emissivity coatings. Before describing the fundamentals of spectrally selective coatings, it is necessary to keep in mind that all matter emits radiation. To describe radiation from matter the concept of blackbody is introduced. A blackbody is usually defined as a perfect radiator which absorbs all radiation incident upon it [3]. Planck’s Law describes the amplitude of electromagnetic radiation emitted (spectral radiance) from a blackbody. If the wavelength, λ, is given in microns and temperature, T, in Kelvin, Planck’s Law takes the form [3]" @default.
• W2108764383 created "2016-06-24" @default.
• W2108764383 creator A5004240453 @default.
• W2108764383 date "2009-09-01" @default.
• W2108764383 modified "2023-10-02" @default.
• W2108764383 title "Commentary: Spectrally selective coatings on glass: solar-control and low-emissivity coatings" @default.
• W2108764383 cites W1491824834 @default.
• W2108764383 cites W1555378084 @default.
• W2108764383 cites W1968162745 @default.
• W2108764383 cites W1971349164 @default.
• W2108764383 cites W1975604347 @default.
• W2108764383 cites W2004979201 @default.
• W2108764383 cites W2090952572 @default.
• W2108764383 cites W2093555089 @default.
• W2108764383 doi "https://doi.org/10.1117/1.3240868" @default.
• W2108764383 hasPublicationYear "2009" @default.
• W2108764383 type Work @default.
• W2108764383 sameAs 2108764383 @default.
• W2108764383 citedByCount "13" @default.
• W2108764383 countsByYear W21087643832012 @default.
• W2108764383 countsByYear W21087643832013 @default.
• W2108764383 countsByYear W21087643832014 @default.
• W2108764383 countsByYear W21087643832016 @default.
• W2108764383 countsByYear W21087643832017 @default.
• W2108764383 countsByYear W21087643832020 @default.
• W2108764383 countsByYear W21087643832023 @default.
• W2108764383 crossrefType "journal-article" @default.
• W2108764383 hasAuthorship W2108764383A5004240453 @default.
• W2108764383 hasBestOaLocation W21087643831 @default.
• W2108764383 hasConcept C120665830 @default.
• W2108764383 hasConcept C121332964 @default.
• W2108764383 hasConcept C123537908 @default.
• W2108764383 hasConcept C154582812 @default.
• W2108764383 hasConcept C163651212 @default.
• W2108764383 hasConcept C171250308 @default.
• W2108764383 hasConcept C192562407 @default.
• W2108764383 hasConcept C2781448156 @default.
• W2108764383 hasConcept C49040817 @default.
• W2108764383 hasConcept C71597924 @default.
• W2108764383 hasConceptScore W2108764383C120665830 @default.
• W2108764383 hasConceptScore W2108764383C121332964 @default.
• W2108764383 hasConceptScore W2108764383C123537908 @default.
• W2108764383 hasConceptScore W2108764383C154582812 @default.
• W2108764383 hasConceptScore W2108764383C163651212 @default.
• W2108764383 hasConceptScore W2108764383C171250308 @default.
• W2108764383 hasConceptScore W2108764383C192562407 @default.
• W2108764383 hasConceptScore W2108764383C2781448156 @default.
• W2108764383 hasConceptScore W2108764383C49040817 @default.
• W2108764383 hasConceptScore W2108764383C71597924 @default.
• W2108764383 hasIssue "1" @default.
• W2108764383 hasLocation W21087643831 @default.
• W2108764383 hasLocation W21087643832 @default.
• W2108764383 hasOpenAccess W2108764383 @default.
• W2108764383 hasPrimaryLocation W21087643831 @default.
• W2108764383 hasRelatedWork W2031562442 @default.
• W2108764383 hasRelatedWork W2067895498 @default.
• W2108764383 hasRelatedWork W2353060934 @default.
• W2108764383 hasRelatedWork W2378677088 @default.
• W2108764383 hasRelatedWork W2380963728 @default.
• W2108764383 hasRelatedWork W2381561243 @default.
• W2108764383 hasRelatedWork W2388062057 @default.
• W2108764383 hasRelatedWork W2609843811 @default.
• W2108764383 hasRelatedWork W2808934043 @default.
• W2108764383 hasRelatedWork W2905339016 @default.
• W2108764383 hasVolume "3" @default.
• W2108764383 isParatext "false" @default.
• W2108764383 isRetracted "false" @default.
• W2108764383 magId "2108764383" @default.
• W2108764383 workType "article" @default.