ASTM E387-2004(2014) 5088 Standard Test Method for Estimating Stray Radiant Power Ratio of Dispersive Spectrophotometers by the Opaque Filter Method《用不透明滤光器方法评估色散分光光度计杂散辐射功率的标准试验方法.pdf

1、Designation: E387 04 (Reapproved 2014)Standard Test Method forEstimating Stray Radiant Power Ratio of DispersiveSpectrophotometers by the Opaque Filter Method1This standard is issued under the fixed designation E387; the number immediately following the designation indicates the year oforiginal adop

2、tion or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon () indicates an editorial change since the last revision or reapproval.1. Scope1.1 Stray radiant power (SRP) can be a significant source oferror in spectro

3、photometric measurements, and the danger thatsuch error exists is enhanced because its presence often is notsuspected (1-4).2This test method affords an estimate of therelative radiant power, that is, the Stray Radiant Power Ratio(SRPR), at wavelengths remote from those of the nominalbandpass transm

4、itted through the monochromator of an absorp-tion spectrophotometer. Test-filter materials are described thatdiscriminate between the desired wavelengths and those thatcontribute most to SRP for conventional commercial spectro-photometers used in the ultraviolet, the visible, the nearinfrared, and t

5、he mid-infrared ranges. These procedures applyto instruments of conventional design, with usual sources,detectors, including array detectors, and optical arrangements.The vacuum ultraviolet and the far infrared present specialproblems that are not discussed herein.NOTE 1Research (3) has shown that p

6、articular care must be exercisedin testing grating spectrophotometers that use moderately narrow band-pass SRP-blocking filters. Accurate calibration of the wavelength scale iscritical when testing such instruments. Refer to Practice E275.1.2 These procedures are neither all-inclusive nor infallible

7、.Because of the nature of readily available filter materials, witha few exceptions, the procedures are insensitive to SRP of veryshort wavelengths in the ultraviolet, or of lower frequencies inthe infrared. Sharp cutoff longpass filters are available fortesting for shorter wavelength SRP in the visi

8、ble and the nearinfrared, and sharp cutoff shortpass filters are available fortesting at longer visible wavelengths. The procedures are notnecessarily valid for “spike” SRP nor for “nearby SRP.” (SeeAnnexes for general discussion and definitions of these terms.)However, they are adequate in most cas

9、es and for typicalapplications. They do cover instruments using prisms orgratings in either single or double monochromators, and withsingle and double beam instruments.NOTE 2Instruments with array detectors are inherently prone tohaving higher levels of SRP. See Annexes for the use of filters to red

10、uceSRP.1.3 The proportion of SRP(that is, SRPR) encountered witha well-designed monochromator, used in a favorable spectralregion, typically is 0.1 % transmittance or better, and with adouble monochromator it can be less than 110-6, even with abroadband continuum source. Under these conditions, it m

11、aybe difficult to do more than determine that it falls below acertain level. Because SRP test filters always absorb some ofthe SRP, and may absorb an appreciable amount if the specifiedmeasurement wavelength is not very close to the cutoffwavelength of the SRP filter, this test method underestimates

12、the true SRPR. However, actual measurement sometimesrequires special techniques and instrument operating condi-tions that are not typical of those occurring during use. Whenabsorption measurements with continuum sources are beingmade, it can be that, owing to the effect of slit width on SRPin a doub

13、le monochromator, these test procedures may offset insome degree the effect of absorption by the SRP filter; that is,because larger slit widths than normal might be used to admitenough energy to the monochromator to permit evaluation ofthe SRP, the stray proportion indicated could be greater thanwou

14、ld normally be encountered in use (but the net effect is stillmore likely to be an underestimation of the true SRPR).Whether the indicated SRPR equals or differs from thenormal-use value depends on how much the SRP is increasedwith the wider slits and on how much of the SRP is absorbedby the SRP fil

15、ter. What must be accepted is that the numericalvalue obtained for the SRPR is a characteristic of the particulartest conditions as well as of the performance of the instrumentin normal use. It is an indication of whether high absorbancemeasurements of a sample are more or less likely to be biasedby

16、 SRP in the neighborhood of the analytical wavelengthwhere the sample test determination is made.1.4 The principal reason for a test procedure that is notexactly representative of normal operation is that the effects ofSRP are “magnified” in sample measurements at high absor-bance. It might be neces

17、sary to increase sensitivity in someway during the test in order to evaluate the SRP adequately.This can be accomplished by increasing slit width and soobtaining sufficient energy to allow meaningful measurement1This test method is under the jurisdiction of ASTM Committee E13 onMolecular Spectroscop

18、y and Separation Science and is the direct responsibility ofSubcommittee E13.01 on Ultra-Violet, Visible, and Luminescence Spectroscopy.Current edition approved Aug. 1, 2014. Published August 2014. Originallyapproved in 1969. Last previous edition approved in 2009 as E387 04(2009). DOI:10.1520/E0387

19、-04R14.2The boldface numbers in parentheses refer to the list of references at the end ofthis standard.Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States1of the SRP after the monochromatic energy has been removedby the SRP filter. Howeve

20、r, some instruments automaticallyincrease sensitivity by increasing dynode voltages of thephotomultiplier detector. This is particularly true of high-enddouble monochromator instruments in their ultraviolet andvisible ranges. A further reason for increasing energy orsensitivity can be that many inst

21、ruments have only absorbancescales, which obviously do not extend to zero transmittance.Even a SRP-proportion as large as 1 % may fall outside themeasurement range.NOTE 3Instruments that have built-in optical attenuators to balancesample absorption may make relatively inaccurate measurements below10

22、 % transmittance, because of poor attenuator linearity. The spectropho-tometer manufacturer should be consulted on how to calibrate transmit-tance of the attenuator at such lower level of transmittance.1.5 High accuracy in SRP measurement is not alwaysrequired; a measurement reliable within 10 or 20

23、 % may besufficient. However, regulatory requirements, or the needs of aparticular analysis, may require much higher accuracy. Pains-taking measurements are always desirable.1.6 The values stated in SI units are to be regarded asstandard. No other units of measurement are included in thisstandard.1.

24、7 This standard does not purport to address all of thesafety concerns, if any, associated with its use. It is theresponsibility of the user of this standard to establish appro-priate safety and health practices and determine the applica-bility of regulatory limitations prior to use.2. Referenced Doc

25、uments2.1 ASTM Standards:3E131 Terminology Relating to Molecular SpectroscopyE275 Practice for Describing and Measuring Performance ofUltraviolet and Visible Spectrophotometers3. Terminology3.1 Definitions:3.1.1 For definitions of terms used in this test method, referto Terminology E131.3.2 Definiti

26、ons of Terms Specific to This Standard:3.2.1 absorption edgeof a sharp cutoff filter: the wave-length interval over which the transmittance changes rapidlyfrom high to very low (that is, less than 0.01 %).3.2.1.1 DiscussionThe bandpass transmittance filters usedin some spectrophotometers to reduce S

27、RP within their band-pass are considered to have both a short wavelength and a longwavelength absorption edge. The rate of change of transmit-tance in the absorption edge may not be as fast as for sharpcutoff filters.3.2.2 blocked-beam spectruma spectrum recorded with anopaque (that is, transmittanc

28、e less than 0.001 %) object in thesample beam; the level of opacity must exist over the range ofwavelengths where the photodetector is sensitive.3.2.3 corrected spectrumthe transmittance (absorbance)spectrum of a SRP filter after the measured spectrum has beenadjusted for the offset of the open-beam

29、 spectrum and (trans-mittance mode) of the blocked-beam spectrum.3.2.4 cutoff wavelength (wavenumber)the wavelength(wavenumber) at which the transmittance of a sharp cutofffilter is 0.01 %.3.2.5 filter, longpassan optical filter having high transmit-tance at wavelengths longer than its absorption ed

30、ge.3.2.6 filter, moderately narrow bandpass SRP-blockingafilter used to reduce remote SRP by transmitting efficientlyover a limited band of wavelengths within a nominal wave-length range of a spectrophotometer.3.2.7 filter, narrow blocking-bandan optical filter havinghigh transmittance at shorter an

31、d at longer wavelengths than anarrow band within which the transmittance is very low (thatis, less than 0.001 %).3.2.8 filter, narrow transmission bandan optical filterhaving very low transmittance at shorter and longer wave-lengths than those of a narrow band within which sometransmittances exceed

32、10 %.3.2.9 filter, neutral (also, neutral density: ND)a filter thatattenuates the radiant power reaching the detector by the samefactor at all wavelengths within a prescribed wavelengthregion.3.2.10 filter, opaquean optical filter that has transmit-tances less than 0.01 % over a specified band of wa

33、velengths.3.2.11 filter, sharp cutoffan optical filter that has a veryrapid transition in wavelengths (wavenumbers) from a state ofhigh transmittance to a state of very low transmittance (that is,less than 0.001 %) and that continues in that low transmittancestate to at least the end of the spectral

34、 region that is beingtested.3.2.12 filter, shortpassa sharp cutoff filter having a hightransmittance at wavelengths shorter than its absorption edge.3.2.13 filter, SRPa test filter for determining SRPR.3.2.14 limiting transmittance (absorbance)the minimumtransmittance (maximum absorbance) of the SRP

35、 filter that isobserved in the SRPR test; the transmittance (absorbance)indicated when the spectral curve levels off or starts to increase(decrease).3.2.15 near SRPstray radiant power of wavelengths(wavenumbers) within several spectral bandwidths from thespectral position of the spectrophotometer (3

36、).3.2.16 open-beam spectrumthe spectrum recorded withno attenuating medium in the sample beam.3.2.17 passbandof a monochromator, the band of wave-lengths around the spectral position of the monochromator thatare preferentially transmitted; of a sharp cutoff filter: thewavelength region of high trans

37、mittance of the filter.3.2.18 remote SRPstray radiant power of wavelengths(wavenumbers) more than several spectral bandwidths fromthe spectral position of the spectrophotometer (3).3For referenced ASTM standards, visit the ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.or

38、g. For Annual Book of ASTMStandards volume information, refer to the standards Document Summary page onthe ASTM website.E387 04 (2014)23.2.19 specified wavelength (wavenumber)the wavelength(wavenumber) specified by the manufacturer of a spectropho-tometer (or by the spectroscopist) as that at which

39、the SRPR isstated (or measured).3.2.20 SRPstray radiant power.3.2.21 SRPRstray radiant power ratio.3.2.22 stray lightthe term used in much technical andmanufacturers literature to represent either SRP or SRPR.4. Summary of Test Method4.1 The following test procedures are written for spectro-photomet

40、ers that have provision for recording (that is, forcollecting and storing) spectral data digitally. Processing maybe by built-in programs or in a separate computer. Data may becollected in either the transmittance or the absorbance mode.The data sets to be collected are: (1) open-beam spectrum:100 %

41、 transmittance or zero absorbance; (2) blocked-beamspectrum: 0 %T, transmittance mode only; and (3) SRP filterspectra. Filter spectra are assumed to have been corrected inthe following discussion.NOTE 4For instruments that lack digital recording capability, tradi-tional methods of correcting open-be

42、am and blocked-beam spectra mustbe applied.4.2 Specified Wavelength Method:4.2.1 Manufacturers typically specify stray light, meaningSRPR, at one or more wavelengths. Where sharp cutoff SRPfilters are used, the specified wavelengths should be near, but alittle toward the lower transmittance side, of

43、 the cutoff wave-length of the chosen SRP filter. Other wavelengths can bespecified by the spectroscopist, according to the need ofparticular analyses, using sharp cutoff filters listed in Table 1 orsharp cutoff filters that are now available from various manu-facturers and distributors.4Cutoff wave

44、lengths of some solu-tion filters for the ultraviolet and cutoff wavenumbers of somesolid filters for the mid-infrared are given in Table 1. Wherenarrow blocking-band filters are used, the filters themselvesdefine the specified wavelength.NOTE 5In some cases, manufacturers state SRPR at a wavelength

45、 wellremoved from the cutoff wavelength of the cited SRPfilter. This can resultin an appreciable underestimate of the true SRPR at the specifiedwavelength. Users are cautioned to note carefully the specific informationprovided about the test used to determine the stated SRPR.4.2.2 The SRP filter mat

46、erials are selected for sharp cutoff,freedom from fluorescence, and sufficiently high absorption4Sources of solution filters in sealed cuvettes, interference filters, glass filters,neutral density filters, and materials for mid-infrared filters can be found in AnnualBuyers Guides of several scientif

47、ic organizations, in advertisements in trade journalsthat serve optical and spectroscopic disciplines, in catalogs of suppliers of opticaland spectroscopic materials, and by searching the Internet, using concatenations ofselected terms: filter, optical, stray light, color, absorbing, solution (or li

48、quid)cuvette, spectrophotometer cell, interference, cutoff, sharp cut, longpass, shortpass,bandpass, neutral density; for mid infrared materials: infrared cells, infraredcrystals, infrared accessories, fused silica.TABLE 1 Filters for Tests for Stray Radiant Power RatioCutoff Wavelength,WavenumberAT

49、ransmittance,B80 %Wavelength or WavenumberFilterCSourceDDetectorEA. Sharp Cutoff Types173.5 nm 183 nm 0.01 cm H2OFUV UV183.5 nm 195 nm 1.00 cm H2OFUV UV200 nm 214 nm 1.00 cm 12 g/L KCl aqueousFUV UV223 nm 232 nm 1.00 cm 10 g/L NaBr aqueousFUV UV259 nm 271 nm 1.00 cm 10 g/L NaI aqueous UV UV259 nm 271 nm 1.00 cm 10 g/L KI aqueous UV UV325 nm 339 nm 1.00 cm acetone UV UV385 nm 420 nm 1.00 cm 50 g/L NaNO2aqueous VIS UV1200 cm-12800 cm-12.0-mm fused silicaG(2) IR IR800 cm-11760 cm-16 mm LiF IR IR600 cm-11240 cm-16mmCaF2IR IR400 cm-11030 cm-16 mm NaF IR IR25