CHNS Advanced User Guide
- 1 Apparatus, Reagents, & Materials
- 1.1 Gases
- 1.2 Laboratory Apparatus
- 1.2.1 Sample Preparation Tools
- 1.3 Chemicals
- 1.4 Advanced Apparatus
- 1.5 Instrument Description
- 2 Sample Flow
- 3 Starting the Instrument
- 3.1 Powering on the System
- 3.2 Creating Data Folders and Copying Method File
- 3.3 Starting the Instrument Operating System
- 3.4 Checking for Leaks
- 3.5 Copying and Loading Method
- 3.6 Checking Maintenance Status
- 3.7 Editing the Method
- 3.8 Editing the Component Table
- 3.9 Editing the Integration Parameters
- 3.10 Editing Other Parameters
- 3.11 Running Samples
- 4 Shutting Down the Instrument
- 5 Maintenance and Troubleshooting
- 6 Environment, Health, & Safety
- 7 Software User Guide
- 7.1 Archive Version
CHNS is fundamental element analyses performed in the shipboard laboratories for IODP cruises. Fluctuations in the concentrations and/or content ratios of C, N, and S define the origin, depositional environment, and diagenetic alteration of source materials. Analysts have a few choices for sample preparation, instrument settings, and measurement methodologies. Specific analytical methodology may be required based on the nature of certain sample materials. When this circumstance arises, laboratory specialists must authorize and document methodology deviations.
Apparatus, Reagents, & Materials
Before the cruise (during transit), confirm the existence and the condition of consumables, preparation tools, and chemicals for CHNS analysis on solid matrix.
Gases
–Helium (He) carrier gas: chromatographic grade
–Oxygen (O2) for sample oxidation: minimum 999.995%
Laboratory Apparatus
Sample Preparation Tools
–Agate mortar and pestle: well washed, dried
–Chamber for freeze drier: well washed, dried
–Desiccator and silica gel: use well-dried silica gel
–Kimwipes
–Weighing paper
–Mill (for hard rock sample)
–Sample holder (2): stainless steel, well washed, dried
–Spatula (laboratory spoon, 2): stainless steel, well washed, dried
–Spatula (micro spatula, 2)
–Spring tweezers (2)
–Tin containers (set of 100): Thermo Electron PN 240 064 00
–Tin discs (30 mm) (set of 100): Thermo Electron PN 252 080 15, optional
Chemicals
Material Name | Description | Purpose |
Aspartic acid (L-Aspartic acid) | C4H7NO4: white fine crystals | Standard reference material |
2.5-Bis(5-tert-butyl-benzoxazol-2- yl)thiophene (BBOT) | C26H26N2O2S: pale green crystals | Standard reference material |
Copper oxide | Pre-packed | Filling material |
Electrolytic copper | Pre-packed | Filling material |
Ethyl alcohol (ethanol) | C2H5OH | Solvent for sample preparation |
Quartz wool | SiO2 | Filling material |
Soil Reference Material | Light brown powder | Reference for nitrogen and carbon |
Sulfanilamide | C6H8N2SO2: white odorless crystals | Calibration standard for CHNS/CNS |
L-Cystine | C6H12N2O4S2: white odorless crystals | Calibration standard |
Vanadium pentoxide | V2O5: yellow to red crystalline powder | Catalyst |
Magnesium perchlorate | Mg(ClO4)2: white granulate | Filling material for water trap |
Other Consumables and Tools
–Pre-packed reactor: Thermo Electron PN 468 020 15; also CE Elantech 061110
–Cleaning devices: Thermo Electron PN 205 006 25 and 276 060 10
–HPAR reactor extractor
–Crucible extractor
Advanced Apparatus
An expedition-specific science strategy or sample materials may require additional apparatus to handle liquid sample analysis.
–Automatic sampling system with injection assembly
–Water container and vials for solvent
–Syringe (0.5 µL): PN 36504045
–Syringe (10 µL): PN 36500525
–Syringe (250 µL): PN 013680 (36504042)
Instrument Description
C, H, N, and S are analyzed on a Thermo Electron Corporation FlashEA 1112 CHNS elemental analyzer (Figure 1, below) with the following specifications:
–Supplier: Thermo Electron Corporation
–Model: FlashEA 1112
–Detector: Thermal conductivity detector (TCD)
–Instrument Control: Eager 300 software for MS Windows
–Power Supply: 230 V AC; 60 Hz (US); 140 VA
–Dimensions: 500 mm H × 590 mm W × 558 mm D
–Weight: 65 kg
–Measurement Range: 100 ppm to 100% for C, N, H, and S
–Nominal Measurement Time: CNS: 8 min, CHNS: 10 min
–Sample Weight: 0.01–100 mg according to nature of the sample
–Temperature range:15°–35°C Maximum rel. humidity:30%–85%
The basic CHNS instrument configuration contains the following components.
Figure 1. CHNS Components.
1. Autosampler (highlighted in red in Figure 2 and shown in detail in Figure 3)
2. Gas tubing for helium and oxygen
3. Synoptic panel
4. Furnace (furnace cover plate shown in Figure 4; opened plate in Figure 5)
5. Reactor
6. Oven
7. Water adsorption column (shown in Figure 6)
7. Gas chromatographic column (also in Figure 6)
8. TCD detector
Figure 2. Top and Front Instrument Panels (Dry Sample Autosampler is located on top of furnace)
Figure 3. Dry Sample Autosampler
Figure 4. Furnace Compartment Access with Protection Plate
WARNING! Do not open the furnace compartment during operation
Figure 5. Interior Furnace Compartment
WARNING: Do not touch either furnace when the furnace temperature is >40°C. (Select View > View Elemental Analyzer Status)
Figure 6. Detector Access: Protection Plate, GC Column (inside), Adsorption Filter
WARNING: The GC column may only be serviced by the shipboard technicians
Sample Flow
Sample flow in the onboard laboratory normally proceeds as described in the following steps.
Collect samples from core (on the sample table).
Pack, seal, and label wet samples
Record sample information in the LIMS
Prepare sample for analysis (drying, powdering).
Freeze-dry the sample
Grind and homogenize sample
Weigh sample.
Wrap powder samples in tin film (cup), weigh, and place in sample holder
Save weight data in the LIMS
Output sample list from LIMS.
Select samples that are ready for analysis
Output analysis sample list from the LIMS
5. Upload sample list to Eager 300 software.
6. Edit sequence table.
Manually add Bypass sample line to the sequence table
Add a blank line to stop the sequence at any time
7. Run test analysis and samples.
Confirm peak identification and integration parameters
Create calibration curve
Start analyzing unknown samples
8. Output data summary (Excel file).
9. Upload data summary and files to LIMS.
Starting the Instrument
Perform any required maintenance before starting the system (see Instrument Maintenance section).
Powering on the System
Proceed according to the following operating sequence. Early start up (6 hr before measurement) is recommended for this instrument.
Open gas line/bottles.
Power on the FlashEA 1112.
Power on the PC and monitor.
Creating Data Folders and Copying Method File
The sequence of data files must be saved in the folder with the method file. Create new folders in the following directory: My Computer\Local Disk\Program files\Thermo Electron\Eager 300 for EA1112\Expedition No.& abbreviationdata 001-200.
If there are more than 200 expected samples, create two or more data folders (e.g., data 201-400).
Starting the Instrument Operating System
Double-click on the Eager 300 for EA 1112 icon.
Select CHNS from the list and click OK to answers prompted step by step (Figure 7).
Figure 7. CHNS Screen
Checking for Leaks
1. Select Edit > Edit Elemental Analyzer parameter.
2. Select the Flow / Timing tab (Figure 8).
3. Select (check) the Carrier, Oxygen, and Reference parameters.
4. Click Send to transfer the parameters.
5. Click OK to close window.
6. Click NO to exit without saving the method.
7. Select View > View Elemental Analyzer Status.
8. Select the Special Functions tab (Figure 9).
9. Click Leak Test to open the Leak Check screen.
10. Click Start to begin the operation.
11. Click Yes for the Eager 300 to automatically test for leaks.
12. After a few seconds, the reference gas flow must be 0.
Note: After ~560 sec, carrier flow will decrease. Carrier flow must be between 0 and 3 mL/min. Higher values indicate the system is not leak free. Leaks in the system are generally due to incorrect closure of the reactor and filter locking nut. Rarely, leaks may be due to the autosampler.
Figure 8. Flow/Timing Tab.
Figure 9. Special Functions Tab and Leak Test Screen.
Copying and Loading Method
To copy and load a previous method, select File > Copy method from... (Figure 10).
Uncheck the Sample table check box.
Click the button to the right of Method File… to select the method.
Select the method file IODP_NCHSsystem from the folder that has the previous expedition number and click Open.
Select Edit > Edit Elemental Analyzer parameters.
Click File and select the folder that has last expedition number.
Open file IODP_NCHS.eam.
Click File > Save as to save instrument settings into the created folder. Note: Your created folder now contains three files with extensions MTH, EAM, and CC.
Select File > Save method.
Use same method file that you copied in an earlier step and select the folder that you created.
Click Save to save the copied method in the new folder.
Select File > Load method > Load New Method.
Select the folder that contains the copied method and click Open to load method.
Click Send Parameters to Analyzer to send the method to the instrument.
Warning: When the furnaces begin to heat, helium flows in the circuit and the Furnace, Oven, and TCD lights illuminate on the synoptic panel.Select View > View Elemental Analyzer Status to confirm status of instrument.
If the analytical configuration changes from CHNS to CNS, select File > Instrument Configuration on the main screen before editing the method (see instructions in the FlashEA Operating Manual, p. 217–221).
Figure 10. Copy Method from Screen.
Checking Maintenance Status
If a reactor is changed, the maintenance program must be reset. The maintenance program shown in Figure 11 gives an indication of reactor life. Reactor deterioration can also be detected on chromatograms.
Figure 11. Maintenance Program Screen
Reactor life is also influenced by the nature of samples, especially water content. So you may have to check for anomalies on the chromatogram on a regular basis, as follows:
Select View > View Maintenance. The Maintenance Program screen shows the reactor status (Figure 11). To reset the maintenance program, select Edit > Reset Maintenance Program.
Select View > Maintenance Status to see the current settings. The program can be changed in two ways.
Click Edit > Default. Original settings for Left 1 and Left 2 were
Lifetime: 200
Number of runs to warning message: 10
4. Click Edit > Manual. Based on onshore tests, change the settings to
Lifetime: 170
Number of runs to warning message: 10
5. Click OK to save changes.
Editing the Method
Select Edit > Edit Element Analyzer parameters. The following parameters will display:
–Temperature tab:
Left Furnace: generally not checked
Right Furnace: checked, 900°C default (keep value)
Oven: checked, 65°C default (keep value)
–Flow / Timing tab:
Carrier: checked, 140 mL/min (This can be changed to achieve peak separation).
Oxygen: checked, 250 mL/min (default)
Reference: checked, 100 mL/min (default)
Cycle (Run Time): 600 sec (default)
Sampling Delay: 12 sec (default)
Oxygen Injection End: 5 sec (default)
–Detector tab:
Filament On: checked
Time Event: not checked
Note: Peak retention times are confirmed based on the chromatogram of the Bypass sample obtained using standard materials, which is then used to validate the calibration curve.
Editing the Component Table
On the CHNS screen, select Edit > Sample table (Figure 12, below). Clear the sample table and create two new rows.
Fill in the sample table as follows:
–Row 1:
Sample name = Blank test
Filename = Blank_test_ddmmyy
Type = blank
–Row 2: Insert one blank line to stop measurement automatically after the blank.
–Row 3:
Sample name = Bypass test
Filename = Bypass_test_ddmmyy
Type = Bypass
Prepare Blank (tin cup with V2O5) and Bypass using a standard material (~0.6–0.7 mg of sulphanilamide or BBOT with V2O5 and tin cup). Place the Blank in the sample tray of the MAS 200 R autosampler for the FlashEA 1112.
Note: Acquire a chromatogram that contains all the components to be identified.
Click OK to close the sample table.
Select File > Save method to save the sample table.
On the CHNS screen, click the green arrow toolbar icon to start running the samples.
Select View > View sample being acquired to confirm run status.
Note: Confirm chromatogram from the Blank to check the condition of the elemental analyzer. If the chromatogram has unexpected peaks and/or an unacceptable (disturbed) baseline, identify the cause of problem before running the Bypass sample. If the Blank is fine, continue measurement of Bypass.
After the Bypass sample is done, select Edit > Component table to identify the analysis peaks (Figure 13, below). Instructions for editing the component table are given in the Eager 300 Software Operating Manual, p. 101–115.
Select File > Load Chromatogram, and select bypass test-ddmmyy (last sample run).
10. Click Open to view the chromatogram.
11. Select Time of any component on the table.
12. Move the cursor near the red-gray arrow on the screen and right-click.
13. Adjust the red line on the screen to intersect the top of the peak.
14. Repeat Steps 11–13 for each peak on the chromatogram, and click OK to save changes.
Warning: If peak retention times have changed a lot, measure an additional Bypass sample to confirm the new peak positions. Possible causes of peak retention time shifts include (1) gas leaks (include outside of the instrument), (2) gas flow changes, (3) atmospheric pressure changes, and (4) others.
Figure 12. Sample Table.
Figure 13. Component Table.
Editing the Integration Parameters
After finishing peak identification in the previous section, select Edit > Edit Method on the CHNS screen. Method editing instructions are shown in the Eager 300 Software Operating Manual, p. 74–76.
Select the Integration parameters 3 tab and select Test Integration (Figure 14).
Select File > Load Chromatogram.
Load the chromatogram for the last test result (Bypass).
Select Detect > Peak Integration.
Four default integration parameters will be indicated. To customize detailed settings, click Time events, then Peak Detect. (Figure 15).
To edit the integration parameter table, select any peak time.
Move the cursor near the red-gray arrow. The cursor will convert to a narrow white- black arrow. Left-click to move the arrow.
Click Type of Event in the table, and then click the green inverted triangle.
Choose a type of event and click OK to close the window.
Click OK to save the modification.
Click OK on the Peak detect screen and then close the Chromatogram screen.
Figure 14. Edit Method Screen.
Figure 15. Peak Detect Screen.
Editing Other Parameters
Select the Calculation parameters 4 tab on the Edit Method screen to select the calibration method. Eager 300 has three calibration methods, details of which are described in the FlashEA 1112 Operating Manual, p. 232–234. Generally, we use Linear fit for sediment samples. K-Factor is sometimes useful for samples that are characterized by low component concentrations.
Running Samples
Proceed to measuring samples, see the CHNS Analyzer User Guide.
Shutting Down the Instrument
At the end of the cruise, if needed, shut down the system following the procedure below:
Select Edit > Edit Element Analyzer parameters.
Select File > System Defined Method Folder in the Eager300 for EA1112 folder.
Select Shutdown.eam, and then click Open to open shutdown setting.
Click Send to send opened setting to the EA 1112.
Monitor temperature change until oven temperature reaches <200°C.
Maintenance and Troubleshooting
Installing the Reactor in the Furnaces
Warning: The reactor must be installed with the furnaces at room temperature or <50°C with gloves. Do NOT use any mechanical tools to screw or unscrew the fixing nut.
Figure 16. Autosampler Removal.
See the FlashEA 1112 Operating Manual, p. 126–129 and 134. Pages 306–308 are also useful when replacing the O-ring of the coupling unions.
Loosen fixing nut and remove autosampler (Figure 16, above).
Delicately remove the used reactor (Figure 17, below, 2) from the right furnace.
Detach O-ring from the used reactor. If O-ring is undamaged, you can use it again.
Gently cleanup coupling union (Figure 17, 1) and O-ring. Wipe metal with alcohol if needed, but do NOT apply alcohol to O-ring. If using alcohol, apply a small amount of Vaseline to the O-ring to fix the cleaned coupling union.
Put a kimwipe or aluminium foil on the coupling union (Figure 17, 3) to protect cleaned coupling union from dust.
Delicately introduce the reactor into the furnace, ensuring that the tube conical end is turned downward toward the base (Figure 17, 4).
Gently press the edge of the reactor until introduction is complete.
Slip on the O-ring with its conical section turned upward.
Manually screw the fixing nut.
Figure 17. Furnace Reactor.
Cleaning the Autosampler
The autosampler does not normally require maintenance except for the sample tray. However, when the instrument is extensively used, it is a good practice to occasionally check the shaft housed in the autosampler.
Cleaning the Sample Tray
Review the FlashEA 1112 Operating Manual, p. 309–313. Once per week or whenever the autosampler is dirty, clean the sample tray as follows:
Detach the sample tray from the autosampler.
Using a Kimwipe and ethanol, wipe the holders and protective cover of tray.
Place the holder with protective cover over the autosampler.
Cleaning the Shaft of the MAS 200 R Autosampler
If you detect a gas leak in the autosampler (see "Test for Leaks"), clean the shaft of the MAS 200 R. The cleaning method is shown in the FlashEA 1112 Operating Manual, p. 314–318.
Note: If you replace a shaft, you must send the old shaft back to vendor, CE Elantech, Inc., to maintain a shaft.
Connecting the Water Trap (Adsorption Filter)
Warning: Wear gloves and face protector when preparing the adsorption filter. Work with quartz wool under the draft chamber because quartz wool is an inhalation hazard.
Introduce into either of the tube ends a sufficient amount of quartz wool to form a layer ~1 cm (1/3 in.) thick.
Plug the tube mouth with your hand and press the quartz wool gently using a cleaned stainless steel spatula.
Screw the nut completely with its seal onto the thread mouth.
Pour the filling material (magnesium perchlorate) into the adsorption filter.
At the top, add a 1 cm (1/3 in.) layer of quartz wool.
Screw the second nut completely with its seal.
Common issues and Troubleshooting
Environment, Health, & Safety
Laboratory Safety and General Operation Training
Offshore laboratory specialists must complete all mandatory training before sailing. In addition to the general laboratory safety training, offshore laboratory specialists must complete general user training at the onshore facility. The CHNS User Guide has more information on safety related to this system.
High-Pressure Gas Safety
High-pressure gas lines, particularly the O2 line, can be hazardous if there is leak. Check for gas leaks at gas fittings at the instrument regularly.
Other Safety Issues
The FlashEA 1112 has a safety cut-off function to prevent hazards. When an alarm condition is detected, this device cuts off the power to the heating elements of the oxidation and reduction furnaces. Instrument malfunctioning, because of component failure or abnormal operating conditions, is identified by the red safety cut-off LED on the synoptic panel. Reference: FlashEA1112 Operating Manual, p. 23–24.
Material Safety
Wear gloves and face protector when working with quartz wool. Also work under the draft chamber because quartz wool is an inhalation hazard. Vanadium pentoxide and magnesium persulfate are also significant hazards; be sure to read the material safety data sheet (MSDS) for each and every reagent and chemical, including the standards, used in this procedure!
Software User Guide
The CHNS screen of the Eager 300 software application is the starting point to enter all functions.
–File: instrument operation functions:
Set language...
Color set
Instrument name and config
System administration
Installation qualification
Load method
Load system defined method
Save method
Copy method from...
Printer setup
Print method
Exit Eager 300
–Run: start, stop, or abort sequences:
Start sequence of samples
Stop running sequence
Start single sample data acquisition
Stop data acquisition
Abort data acquisition
Run macro
–Edit: instrument setup and analytical parameters:
Edit Method
Component table
Sample table
Wizard method development
Edit Elemental Analyzer parameters
–View: analysis and chromatogram functions
View sample being acquired
Last sample calculated results
View Calibration curve
View Chromatograms
Overlay Chromatograms
Operate on Chromatograms
Compare Chromatograms
View Elemental Analyzer Status
View Maintenance
–Recalculation: cancel or recalculate calibration or results
Reset calibration factor
Recalculation
Summarize results
–Tools: reactor maintenance functions
Ashes removal
Reactor replacement