SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1993460860> ?p ?o ?g. }

Showing items 1 to 71 of 71 with 100 items per page.

W1993460860 endingPage "92" @default.
W1993460860 startingPage "84" @default.
W1993460860 abstract "We report an optical, interferometric technique for measuring the temperature of semiconductor substrates during heating or cooling, which is applicable in vacuum. The technique circumvents many of the problems associated with thermocouple or pyrometer measurements. A low-power infrared (IR) laser (e.g., λ=1.15-μm He–Ne laser) having an energy below the band gap is directed at a wafer that is polished on both sides, where either reflected or transmitted laser light is detected by a photodiode. Interference results between reflections off the front and back surfaces of the wafer. As the temperature of the wafer is either increased or decreased, the temperature dependence of the refractive index, along with a smaller contribution from thermal expansion, causes the optical path within the wafer to change by λ/2n (i.e., a full interference cycle) for every ∼3 K for a typical Si, GaAs, or InP wafer thickness of 500 μm. Consequently, temperature changes of ±0.2 K are easily detected. This technique, has been used between room temperature and 600 °C on GaAs substrates in a low-pressure metal-organic chemical vapor deposition (MOCVD) system, and in an ultrahigh vacuum thermal desorption experiment. This method can be used well below room temperature, as well as at temperatures above 650 °C with the optimum choice in laser wavelength. Application of this method to other processes such as molecular beam epitaxy (MBE), reactive ion etching, and rapid thermal processing should be straightforward. We also describe a refinement of the method for measuring the sign, as well as magnitude of temperature changes for typical, slightly tapered wafers during heating or cooling cycles. In this case the reflected laser beam contains a series of parallel lines that move toward the thinner end of the region probed by the laser beam as the temperature increases. Sensing the direction that these spatial interference fringes move can be used to determine whether the sample is heating or cooling." @default.
W1993460860 created "2016-06-24" @default.
W1993460860 creator A5055419333 @default.
W1993460860 creator A5075087135 @default.
W1993460860 date "1990-01-01" @default.
W1993460860 modified "2023-09-26" @default.
W1993460860 title "Infrared-laser interferometric thermometry: A nonintrusive technique for measuring semiconductor wafer temperatures" @default.
W1993460860 doi "https://doi.org/10.1116/1.576993" @default.
W1993460860 hasPublicationYear "1990" @default.
W1993460860 type Work @default.
W1993460860 sameAs 1993460860 @default.
W1993460860 citedByCount "69" @default.
W1993460860 countsByYear W19934608602012 @default.
W1993460860 countsByYear W19934608602013 @default.
W1993460860 countsByYear W19934608602014 @default.
W1993460860 countsByYear W19934608602015 @default.
W1993460860 countsByYear W19934608602017 @default.
W1993460860 countsByYear W19934608602018 @default.
W1993460860 countsByYear W19934608602020 @default.
W1993460860 countsByYear W19934608602022 @default.
W1993460860 countsByYear W19934608602023 @default.
W1993460860 crossrefType "journal-article" @default.
W1993460860 hasAuthorship W1993460860A5055419333 @default.
W1993460860 hasAuthorship W1993460860A5075087135 @default.
W1993460860 hasConcept C108225325 @default.
W1993460860 hasConcept C120665830 @default.
W1993460860 hasConcept C121332964 @default.
W1993460860 hasConcept C158355884 @default.
W1993460860 hasConcept C159985019 @default.
W1993460860 hasConcept C160671074 @default.
W1993460860 hasConcept C168068576 @default.
W1993460860 hasConcept C192562407 @default.
W1993460860 hasConcept C32993116 @default.
W1993460860 hasConcept C49040817 @default.
W1993460860 hasConcept C520434653 @default.
W1993460860 hasConcept C62520636 @default.
W1993460860 hasConcept C72293138 @default.
W1993460860 hasConceptScore W1993460860C108225325 @default.
W1993460860 hasConceptScore W1993460860C120665830 @default.
W1993460860 hasConceptScore W1993460860C121332964 @default.
W1993460860 hasConceptScore W1993460860C158355884 @default.
W1993460860 hasConceptScore W1993460860C159985019 @default.
W1993460860 hasConceptScore W1993460860C160671074 @default.
W1993460860 hasConceptScore W1993460860C168068576 @default.
W1993460860 hasConceptScore W1993460860C192562407 @default.
W1993460860 hasConceptScore W1993460860C32993116 @default.
W1993460860 hasConceptScore W1993460860C49040817 @default.
W1993460860 hasConceptScore W1993460860C520434653 @default.
W1993460860 hasConceptScore W1993460860C62520636 @default.
W1993460860 hasConceptScore W1993460860C72293138 @default.
W1993460860 hasIssue "1" @default.
W1993460860 hasLocation W19934608601 @default.
W1993460860 hasOpenAccess W1993460860 @default.
W1993460860 hasPrimaryLocation W19934608601 @default.
W1993460860 hasRelatedWork W1507811721 @default.
W1993460860 hasRelatedWork W1893334860 @default.
W1993460860 hasRelatedWork W1964155478 @default.
W1993460860 hasRelatedWork W2071429140 @default.
W1993460860 hasRelatedWork W2129126733 @default.
W1993460860 hasRelatedWork W2172990930 @default.
W1993460860 hasRelatedWork W2316272916 @default.
W1993460860 hasRelatedWork W4312393858 @default.
W1993460860 hasRelatedWork W60263113 @default.
W1993460860 hasRelatedWork W2185969615 @default.
W1993460860 hasVolume "8" @default.
W1993460860 isParatext "false" @default.
W1993460860 isRetracted "false" @default.
W1993460860 magId "1993460860" @default.
W1993460860 workType "article" @default.