Newport Cornerstone 130B User Manual Download

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90088262 MCS130B

CORNERSTONE 130B MONOCHROMATORS

6.2

35B

GRATING EFFICIENCY AND BLAZING

Efficiency  and  its  variation  with  wavelength and spectral order are important characteristics of a
diffraction  grating.  For  a  reflection  grating,  efficiency  is  defined  as  the  energy  flow  (power)  of
monochromatic light diffracted into the order being measured, relative either to the energy  flow of
the  incident light (absolute efficiency) or to the energy  flow of specular reflection from a polished
mirror substrate coated with the same material (relative efficiency). Efficiency is defined similarly for
transmission gratings, except that an uncoated substrate is used in the meas urement of relat ive
efficiency.

High-efficiency  gratings  are  desirable  for  several  reasons.  A grating with high efficiency is more
useful than one with lower efficiency in measuring weak transition lines in optical spectra. A grating
with  high  efficiency  may  allow  the  reflectivity  and  transmissivity  specifications  for  the  other
components in the spectrometer to be relaxed. Moreover, higher diffracted energy may imply lower
instrumental  stray  light  due  to  other  diffracted  orders,  as  the  total  energy  flow  for  a  given
wavelength leaving the grating is conserved (being equal to the energy flow incident on it minus any
scattering and absorption).

Control over  the magnitude and variation of diffracted energy with wavelength is called blazing, and
it  involves  the  manipulation  of  the  micro-geometry  of  the  grating  grooves.  The  energy  flow
distribution  (by  wavelength)  of  a  diffraction  grating  can  be altered by modifying the shape of the
grating grooves. The blaze wavelength is the wavelength where the grating efficiency is enhanced
by shaping the grating grooves. Although holographic gratings are not shaped like ruled grat ings ,
the peak grating efficiency wavelength is also referred to as the blaze wavelength.

The choice of an optimal efficiency curve for a grating depends on the specific app lication.  Oft en
the desired instrumental efficiency is linear; that is, the intensity of light transformed int o signal at
the image plane must be constant across the spectrum. To approach this as closely as  poss ible,
the  spectral  emissivity  of  the  light  source  and  the  spectral  response  of  the  detector  should be
considered,  from  which the desired grating efficiency curve can be derived. Usually this requires
peak grating efficiency in the region of the spectrum where the detectors are least sensitive.

In  many  instances,  the  diffracted  power  depends  on  the  polarization  of  the  incident  light.  For
completely unpolarized incident light, the efficiency curve will be exactly halfway between the P and
S  efficiency  curves.  Anomalies  are  locations  on  an  efficiency  curve  (efficiency  plotted  vs.
wavelength)  at  which  the  efficiency  changes  abruptly.  These  sharp  peaks  and  troughs  in  an
efficiency curve are sometimes referred to as Wood's anomalies .

The efficiency curves shown are relative (not absolute) and were measured using an in-plane near
Littrow  configuration.    Please  use  the  curves  as  a  guide  and  not  as  absolute  data.    Grating
diffraction is dependent on the polarization of the radiation incident on the grating.

Software such as the Mono Utility and  TracQ Basic may be configured to switch between grat ings
at  a  specific  wavelength.    Typically,  the  most  efficient  grating  is  selected,  so  this  switchover
wavelength  would  be  where  the  two  efficiency  curves  meet.    To  determine empirically the ideal
switchover wavelength, the output should be measured by an optical detector.  Run a s c an in t he
crossover region using only Grating 1.  Repeat the scan using only Grating 2.  Where the det ect or
readings are closest is the optimal switchover wavelength.

If  the  selected  gra