photometer$60423$ - ορισμός. Τι είναι το photometer$60423$
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Τι (ποιος) είναι photometer$60423$ - ορισμός

FORMER NASA INFRARED SPACE OBSERVATORY
SIRTF; Space Infrared Telescope Facility; Spitzer Telescope; Spitzer space telescope; Multiband Imaging Photometer for Spitzer; Spitzer Space telescope; Spitzer Warm Mission; 2003-038A; Spitzer (spacecraft); Spitzer telescope; Earth-trailing orbit
  • The [[Andromeda Galaxy]] imaged by MIPS at 24 micrometers.
  • [[Earth]]}}
  • An artist's impression of the TRAPPIST-1 system.
  • The [[Helix Nebula]], blue shows infrared light of 3.6 to 4.5 micrometers, green shows infrared light of 5.8 to 8 micrometers, and red shows infrared light of 24 micrometers.
  • first light]] image of [[IC 1396]].
  • An artificial color image of the [[Double Helix Nebula]], thought to be generated at the galactic center by magnetic torsion 1000 times greater than the Sun's.
  • Infrared observations can see objects hidden in visible light, such as [[HUDF-JD2]], shown. This shows how the Spitzer IRAC camera was able to see beyond the wavelengths of Hubble's instruments.
  • OGLE-2015-BLG-1319}}: Ground-based data (grey), Swift (blue), and Spitzer (red).
  • Cepheus C & B Regions.]] – The Spitzer Space Telescope (30 May 2019).</div>
  • An arrow points to the embryonic star HOPS-68, where scientists believe [[forsterite]] crystals are raining down onto the central dust disk.
  • A [[Henize 206]] viewed by different instruments in March 2004. The separate IRAC and MIPS images are at right.

Photoelectric flame photometer         
  • Flame photometer FP8800 for simultaneous determination of up to 4 alkali and alkali earth element concentrations in aqueous samples. Courtesy of A.KRÜSS Optronic
  • Analysis of samples by Flame photometer
LABORATORY DEVICE THAT CARRIES OUT A QUANTITATIVE FLAME TEST
Photoelectric Flame Photometer; Flame photometer
A photoelectric flame photometer is an instrument used in inorganic chemical analysis to determine the concentration of certain metal ions, among them sodium, potassium, lithium, and calcium. Group 1 and Group 2 metals are quite sensitive to Flame Photometry due to their low excitation energies.
photometer         
  • Ritchie's photometer
  • Rumford's photometer
SCIENTIFIC INSTRUMENT
Luminometer
[f?(?)'t?m?t?]
¦ noun an instrument for measuring the intensity of light.
Derivatives
photometric adjective
photometrically adverb
photometry noun
Photometer         
  • Ritchie's photometer
  • Rumford's photometer
SCIENTIFIC INSTRUMENT
Luminometer
An apparatus for measuring the intensity of light emitted by a given lamp or other source of illuminating power. They may be classified into several types. Calorimetric or Heat Photometers act by measuring relatively the heat produced by the ether waves (so-called radiant heat) emitted by the source. The accuracy of the instrument is increased by passing the rays through an alum solution. A thermopile, or an air thermometer, may be used to receive the rays. Chemical Photometers. In these the light falls upon sensitized photographic paper. The depth of coloration is used as the index of illuminating power. Direct Visual Photometers. These include Rumford's Shadow Photometer, Bunsen's Bar Photometer, and Wheatstone's Bead Photometer, in which the light is estimated by direct visual comparison of its effects. Optical Photometers. These include Polarization Photometers, in which the light is polarized; Dispersion Photometers, in which a diverging lens is placed in the path of the rays of light so as to reduce the illuminating power in more rapid ratio than that of the square of the distance. Selenium Photometers, in which the variations in resistance of selenium as light of varying intensity falls upon it is used as the indicator of the intensity of the light. Jet Photometers, for gas only, in which the height of a flame under given conditions, or the conditions requisite to maintain a flame of given height, is used to indicate the illuminating power. The subject of photometers has acquired more importance than ever in view of the extensive introduction of the electric light. (See Candle, Standard--Carcel--Violé's Standard--and Photometers of various kinds.)

Βικιπαίδεια

Spitzer Space Telescope

The Spitzer Space Telescope, formerly the Space Infrared Telescope Facility (SIRTF), was an infrared space telescope launched in 2003. Operations ended on 30 January 2020. Spitzer was the third space telescope dedicated to infrared astronomy, following IRAS (1983) and ISO (1995–1998). It was the first spacecraft to use an Earth-trailing orbit, later used by the Kepler planet-finder.

The planned mission period was to be 2.5 years with a pre-launch expectation that the mission could extend to five or slightly more years until the onboard liquid helium supply was exhausted. This occurred on 15 May 2009. Without liquid helium to cool the telescope to the very low temperatures needed to operate, most of the instruments were no longer usable. However, the two shortest-wavelength modules of the IRAC camera continued to operate with the same sensitivity as before the helium was exhausted, and continued to be used into early 2020 in the Spitzer Warm Mission.

During the warm mission, the two short wavelength channels of IRAC operated at 28.7 K and were predicted to experience little to no degradation at this temperature compared to the nominal mission. The Spitzer data, from both the primary and warm phases, are archived at the Infrared Science Archive (IRSA).

In keeping with NASA tradition, the telescope was renamed after its successful demonstration of operation, on 18 December 2003. Unlike most telescopes that are named by a board of scientists, typically after famous deceased astronomers, the new name for SIRTF was obtained from a contest open to the general public. The contest led to the telescope being named in honor of astronomer Lyman Spitzer, who had promoted the concept of space telescopes in the 1940s. Spitzer wrote a 1946 report for RAND Corporation describing the advantages of an extraterrestrial observatory and how it could be realized with available or upcoming technology. He has been cited for his pioneering contributions to rocketry and astronomy, as well as "his vision and leadership in articulating the advantages and benefits to be realized from the Space Telescope Program."

The US$776 million Spitzer was launched on 25 August 2003 at 05:35:39 UTC from Cape Canaveral SLC-17B aboard a Delta II 7920H rocket. It was placed into a heliocentric (as opposed to a geocentric) orbit trailing and drifting away from Earth's orbit at approximately 0.1 astronomical units per year (an "Earth-trailing" orbit).

The primary mirror is 85 centimeters (33 in) in diameter, f/12, made of beryllium and was cooled to 5.5 K (−268 °C; −450 °F). The satellite contains three instruments that allowed it to perform astronomical imaging and photometry from 3.6 to 160 micrometers, spectroscopy from 5.2 to 38 micrometers, and spectrophotometry from 55 to 95 micrometers.