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Hitachi F7000 Instruction Manual

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    Page 341

    Page 341 A - 28 (6) As shown in Fig. F-2, set the triangular cell filled with Rhodamine B into the cell holder in the sample compartment, the filter holder to the sample compartment and the red filter (single-side frosted) in the filter holder. In so doing, pay attention to the direction of the triangular cell and filter. (Refer to Fig. F-3) Fig. F-2 Setting of Triangular Cell Containing Rhodamine B Fig. F-3 Setting Direction of Triangular Cell (top view) NOTE: It may... 
    A - 28 
(6)  As shown in Fig. F-2, set the triangular cell filled with Rhodamine 
B into the cell holder in the sample compartment, the filter holder 
to the sample compartment and the red filter (single-side frosted) 
in the filter holder.    In so doing, pay attention to the direction of 
the triangular cell and filter.    (Refer to Fig. F-3) 
 
 
 
 
Fig. F-2    Setting of Triangular Cell Containing Rhodamine B 
 
 
 
 
Fig. F-3    Setting Direction of Triangular Cell (top view) 
 
 
NOTE:  It may...

    Page 342

    Page 342 A - 29 (7) Execute the Instrumental Response command from the Utility menu. The Instrumental Response dialog box will open as shown in Fig. F-4. Select “EX [200 to 600 nm].” (Refer to ① in Fig. F-4.) Fig. F-4 (8) Click the Run button. (Refer to ② in Fig. F-4.) A message box “Set the triangular cell with Rhodamine B to cell holder and set the red filter.” will appear. After setting the Rhodamine B and red filter, click the OK button. (Refer to ③ in Fig. F-5.) Fig.... 
    A - 29 
(7)  Execute the Instrumental Response command from the Utility 
menu.    The Instrumental Response dialog box will open as 
shown in Fig. F-4. 
Select “EX [200 to 600 nm].”    (Refer to ①  in Fig. F-4.) 
 
 
 
Fig. F-4 
 
 
(8) Click the Run button.  (Refer to ②  in Fig. F-4.) 
A message box “Set the triangular cell with Rhodamine B to cell 
holder and set the red filter.” will appear.    After setting the 
Rhodamine B and red filter, click the OK button.  (Refer to ③ in 
Fig. F-5.) 
 
 
 
Fig....

    Page 343

    Page 343 A - 30 (9) The EX wavelength is set at 640 nm and the instrument starts EX wavelength scan (from 198.6 to 601.4 nm). At this stage, the following measuring conditions are automatically set. • Scan mode : Excitation • Data mode : Fluorescence • EX slit : 5.0 nm • EM slit : 20.0 nm • Scan speed : 60 nm/min • PMT voltage : 400 V • Response : Auto (10) Upon completion of measurement, the conditions set before measurement are retrieved. Now, the instrument response on the... 
    A - 30 
(9)  The EX wavelength is set at 640 nm and the instrument starts EX 
wavelength scan (from 198.6 to 601.4 nm). 
At this stage, the following measuring conditions are automatically 
set. 
• Scan mode :  Excitation 
• Data mode :  Fluorescence 
•  EX slit  :  5.0 nm 
•  EM slit  :  20.0 nm 
•  Scan speed  :  60 nm/min 
•  PMT voltage :  400 V 
• Response  :  Auto 
 
(10)  Upon completion of measurement, the conditions set before 
measurement are retrieved. 
Now, the instrument response on the...

    Page 344

    Page 344 A - 31 F.2 Measurement of Instrumental Response on Emission Side This is the function to obtain the instrumental response on the emission side such as wavelength characteristics of the emission monochromator or detector (photomultiplier). The instrumental response on the emission side is determined by measuring a combination of instrumental response on both the excitation and emission sides by synchronous wavelength scan, and dividing it by the instrumental response on the excitation side... 
    A - 31 
F.2  Measurement of Instrumental Response on   
Emission Side 
 
This is the function to obtain the instrumental response on the emission 
side such as wavelength characteristics of the emission monochromator 
or detector (photomultiplier). 
The instrumental response on the emission side is determined by 
measuring a combination of instrumental response on both the 
excitation and emission sides by synchronous wavelength scan, and 
dividing it by the instrumental response on the excitation side...

    Page 345

    Page 345 A - 32 NOTES: 1. Measurement of the instrumental response on the excitation side must be completed before executing measurement of the instrumental response on the emission side. 2. It may take time to obtain stable data due to characteristics of the detector immediately after the photomultiplier voltage has been remarkably changed (from 700 V to 250 V for example). When more accurately calibrating the zero point, wait until stable data is obtained and then proceed to step (5). (7)... 
    A - 32 
NOTES:  1.  Measurement of the instrumental response on the 
excitation side must be completed before executing 
measurement of the instrumental response on the 
emission side. 
  2.  It may take time to obtain stable data due to 
characteristics of the detector immediately after the 
photomultiplier voltage has been remarkably changed 
(from 700 V to 250 V for example).    When more 
accurately calibrating the zero point, wait until stable 
data is obtained and then proceed to step (5). 
 
(7)...

    Page 346

    Page 346 A - 33 (9) The EX and EM wavelengths are set at 198.6 nm and the instrument starts synchronous wavelength scan (from 198.6 to 601.4 nm). At this stage, the following measuring conditions are automatically set. • Scan mode : Synchronous • Data mode : Fluorescence • EX slit : 5.0 nm • EM slit : 20.0 nm • Scan speed : 60 nm/min • PMT voltage : 250 V • Response : Auto (10) Upon completion of measurement, the conditions set before measurement are retrieved. Now, the... 
    A - 33 
(9)  The EX and EM wavelengths are set at 198.6 nm and the 
instrument starts synchronous wavelength scan (from 198.6 to 
601.4 nm). 
At this stage, the following measuring conditions are automatically 
set. 
• Scan mode :  Synchronous 
• Data mode :  Fluorescence 
•  EX slit  :  5.0 nm 
•  EM slit  :  20.0 nm 
•  Scan speed  :  60 nm/min 
•  PMT voltage :  250 V 
• Response  :  Auto 
 
(10)  Upon completion of measurement, the conditions set before 
measurement are retrieved. 
Now, the...

    Page 347

    Page 347 A - 34 F.3 Measurement of Instrumental Response in Long Wavelength Range on Emission Side When a corrected spectrum in the long wavelength area of 600 nm or more is required on the emission side, the beam of a lamp whose wavelength characteristics are known is allowed to be irradiated to the emission monochromator, and the instrumental response in the long wavelength range on the emission side is read for correction. As a light source, a sub standard light source (P/N 250-0123) is used. The... 
    A - 34 
F.3  Measurement of Instrumental Response in 
Long Wavelength Range on Emission Side 
 
When a corrected spectrum in the long wavelength area of 600 nm or 
more is required on the emission side, the beam of a lamp whose 
wavelength characteristics are known is allowed to be irradiated to the 
emission monochromator, and the instrumental response in the long 
wavelength range on the emission side is read for correction. 
As a light source, a sub standard light source (P/N 250-0123) is used.   
The...

    Page 348

    Page 348 A - 35 Fig. F-9 (8) Execute the Instrumental Response command from the Utility menu. The Instrumental Response dialog box will open as shown in Fig. F-10. Select “EM [500 to 900 nm].” (Refer to ① in Fig. F-10.) Fig. F-10 1 2 
    A - 35 
 
 
 
Fig. F-9 
 
 
(8)  Execute the Instrumental Response command from the Utility 
menu.    The Instrumental Response dialog box will open as 
shown in Fig. F-10. 
Select “EM [500 to 900 nm].”    (Refer to ①  in Fig. F-10.) 
 
 
 
Fig. F-10 
 
 
1 
2

    Page 349

    Page 349 A - 36 (9) Click the Run button. (Refer to ② in Fig. F-10.) A message box “Set the sub standard light source.” will appear. Click the OK button. (Refer to ③ in Fig. F-11.) Fig. F-11 (10) The instrument starts EM wavelength scan (from 498.6 to 901.4 nm). At this stage, the following measuring conditions are automatically set. • Scan mode : Emission • Data mode : Luminescence • EM slit : 5.0 nm • Scan speed : 60 nm/min • PMT voltage : 400 V • Response : Auto... 
    A - 36 
(9) Click the Run button.  (Refer to ② in Fig. F-10.)  A message 
box “Set the sub standard light source.” will appear.    Click the 
OK button.  (Refer to ③  in Fig. F-11.) 
 
 
 
Fig. F-11 
 
 
(10)  The instrument starts EM wavelength scan (from 498.6 to   
901.4 nm). 
At this stage, the following measuring conditions are automatically 
set. 
• Scan mode :  Emission 
• Data mode :  Luminescence 
•  EM slit  :  5.0 nm 
•  Scan speed  :  60 nm/min 
•  PMT voltage :  400 V 
• Response  :  Auto...

    Page 350

    Page 350 A - 37 F.4 Measurement of Instrumental Response in Long Wavelength Range on Excitation Side When a corrected spectrum in the long wavelength area of 600 nm or more is required on the excitation side, the instrumental response in the long wavelength range on the excitation side is read for the correction with reference to the instrumental response obtained at the long wavelength on the emission side. This measurement is enabled only when the instrumental response at the long wavelength on the... 
    A - 37 
F.4  Measurement of Instrumental Response in 
Long Wavelength Range on Excitation Side 
 
When a corrected spectrum in the long wavelength area of 600 nm or 
more is required on the excitation side, the instrumental response in the 
long wavelength range on the excitation side is read for the correction 
with reference to the instrumental response obtained at the long 
wavelength on the emission side. 
This measurement is enabled only when the instrumental response at 
the long wavelength on the...
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