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HJ 807-2016: Water quality - Determination of molybdenum and titanium by graphite furnace atomic absorption spectrophotometry
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Water quality - Determination of molybdenum and titanium by graphite furnace atomic absorption spectrophotometry
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HJ 807-2016
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Basic data | Standard ID | HJ 807-2016 (HJ807-2016) | | Description (Translated English) | Water quality - Determination of molybdenum and titanium by graphite furnace atomic absorption spectrophotometry | | Sector / Industry | Environmental Protection Industry Standard | | Classification of Chinese Standard | Z16 | | Word Count Estimation | 12,144 | | Date of Issue | 2016-06-24 | | Date of Implementation | 2016-08-01 | | Regulation (derived from) | Ministry of Environmental Protection Announcement No.47, 2016 | | Issuing agency(ies) | Ministry of Ecology and Environment | HJ 807-2016: Water quality - Determination of molybdenum and titanium by graphite furnace atomic absorption spectrophotometry
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(Quality molybdenum graphite furnace atomic absorption spectrophotometry and titanium)
National Environmental Protection Standard of the People 's Republic of China
Determination of molybdenum and titanium in water
Graphite Furnace Atomic Absorption Spectrophotometry
Water quality-Determination of molybdenum and titanium
By graphite furnace atomic absorption spectrophotometry
2016-06-24 released
2016-08-01 implementation
Ministry of Environmental Protection released
I directory
Preface ..ii
1 Scope of application
2 normative reference documents
3 terms and definitions
4 Principle of the method
5 interference and elimination
6 reagents and materials
7 instruments and equipment .3
8 samples .3
9 Analysis steps
10 results are calculated and expressed
11 Precision and Accuracy
12 Quality assurance and quality control
13 Waste treatment
14 Precautions
Appendix A (informative) Standard Addition Act
Appendix B (informative) Method Precision and accuracy 9
Foreword
In order to implement the Environmental Protection Law of the People's Republic of China and the Law of the People's Republic of China on the Prevention and Control of Water Pollution,
Protection of human health, regulate the determination of molybdenum and titanium in water, the development of this standard.
This standard specifies the graphite furnace atomic absorption spectrophotometric method for the determination of molybdenum and titanium in water.
This standard is the first release.
Appendix A and Appendix B of this standard are informative.
This standard is organized by the Ministry of Environmental Protection Science and Technology Standards Division.
The main drafting of this standard. Nanjing Environmental Monitoring Center Station.
The standard verification unit. Jiangsu Province Environmental Monitoring Center, Jiangsu Province, physical and chemical testing center, Nanjing Water Company water quality
Monitoring center, Changzhou City Environmental Monitoring Center, Zhenjiang City Environmental Monitoring Center Station, Taizhou City Environmental Monitoring Center Station.
This standard is approved by the Ministry of Environmental Protection on June 24,.2016.
This standard has been implemented since August 1,.2016.
This standard is explained by the Ministry of Environmental Protection.
Determination of molybdenum and titanium in water - Graphite furnace atomic absorption spectrophotometric method
1 Scope of application
This standard specifies the graphite furnace atomic absorption spectrophotometric method for the determination of molybdenum and titanium in water.
This standard applies to the determination of molybdenum and titanium in surface water, groundwater, domestic sewage and industrial waste water.
The detection limit of molybdenum was 0.6 μg/L, the lower limit of determination was 2.4 μg/L, the detection limit of titanium was 7 μg/L,
For 28 μg/L.
2 normative reference documents
The contents of this standard refer to the following documents or their terms. Any unspecified date of the reference file, the effective version of the appropriate
For this standard.
Technical specification for surface water and wastewater monitoring
Technical specification for groundwater environmental monitoring
3 terms and definitions
The following terms and definitions apply to this standard.
3.1 soluble molybdenum, soluble titanium
Refers to the content of molybdenum or titanium as determined by filtration of a non-acidified sample through a 0.45 μm pore size filter.
3.2 total molybdenum, total titanium
Refers to the content of molybdenum or titanium as determined by the digestion of the unfiltered sample.
4 principle of the method
After the sample is filtered or digested, it is injected into a graphite furnace atomizer, dried, ashed and atomized to become a ground state atom
Vapor, selective absorption of the characteristic lines emitted by the elemental hollow cathode lamp or the electrodeless discharge lamp. In a certain concentration range,
Its absorbance is proportional to the mass concentration of the element.
5 interference and elimination
5.1 Sample SO42
- When the concentration is greater than or equal to 500 mg/L, the negative molybdenum is measured. Adding palladium nitrate - magnesium nitrate
Substrate modifier or reference to Appendix A Standard addition method eliminates interference.
5.2 Ag, Al, As, B, Ba, Be, Bi, Cd, Co in the sample containing 10 mg/L or less in the sample,
Cr, Cs, Cu, Fe, Hg, Mn, Ni, Pb, Sb, Se, Sn, Sr, Tl, Zn and 1000 mg /
Na, Ca and Mg had no significant effect on the measurement.
6 reagents and materials
Unless otherwise stated, analytical reagents conforming to national standards are used for analysis. Experimental water is a newly prepared deionized
Water or water of the same purity.
6.1 nitric acid. ρ (HNO3) = 1.42 g/ml, excellent grade pure.
6.2 hydrochloric acid. ρ (HCl) = 1.19 g/ml, excellent grade pure.
26.3 sulfuric acid. ρ (H2SO4) = 1.84 g/ml, excellent grade pure.
6.4 Hydrogen peroxide. ω (H2O2) = 30%.
6.5 palladium nitrate [Pd (NO3) 2 · 2H2O]. excellent grade pure.
6.6 Magnesium nitrate [Mg (NO3) 2 · 6H2O]. excellent grade pure.
6.7 Ammonium heptamolybdate [(NH4) 6Mo7O 24 · 4H2O]. Excellent grade pure.
6.8 Titanium. Spectral purity, mass fraction ≥99.99%.
6.9 Nitric acid solution. 1 1 (v/v), prepared with (6.1).
6.10 nitric acid solution. 1 99 (v/v), prepared with (6.1).
6.11 hydrochloric acid solution. 1 1 (v/v), prepared with (6.2).
6.12 mixed solution of palladium nitrate-magnesium nitrate.
Weigh 0.5 g (exact to 0.01 g) of palladium nitrate (6.5) and dissolve with 1 ml of nitric acid (6.1). Weigh 0.2 g (exact
To 0.01 g) of magnesium nitrate (6.6), dissolved in the appropriate amount of water. The two solutions were mixed and bound to 100 ml with experimental water.
6.13 molybdenum standard solution
6.13.1 molybdenum standard stock solution. ρ (Mo) = 1000 mg/L.
Accurately weigh 1.840 g (accurate to 0.0001 g) ammonium heptamolybdate (6.7), with the appropriate amount of water dissolved after the experiment
1000 ml volumetric flask, diluted with experimental water volume to the mark, shake. Transferred to the polyethylene bottle, refrigerated at 4 ℃ below
Can be saved for 2 years. A commercially available standard solution may also be used.
6.13.2 molybdenum standard intermediate liquid. ρ (Mo) = 50.0 mg/L.
Remove the 5.00 ml molybdenum standard stock solution (6.13.1) in a 100 ml volumetric flask and dilute with nitric acid solution (6.10)
Capacity to mark, shake. Transferred to the polyethylene bottle, frozen at 4 ℃ can be stored for 1 year.
6.13.3 molybdenum standard use of liquid. ρ (Mo) = 500 μg/L.
Remove 1.00 ml of molybdenum standard intermediate (6.13.2) in a 100 ml volumetric flask and dilute with nitric acid solution (6.10)
Capacity to mark, shake. Transferred to the polyethylene bottle, refrigerated at 4 ℃ can be stored for 6 months.
6.14 Titanium standard solution
6.14.1 titanium standard stock solution. ρ (Ti) = 1000 mg/L.
Accurately weigh 1 g (accurate to 0.0001 g) titanium (6.8), add.200 ml hydrochloric acid solution (6.11), heat to near 100 ° C
Make it dissolved, after cooling the full amount into 1000 ml volumetric flask, diluted with experimental water volume to the mark, shake. Turn into poly
Ethylene bottle, frozen at 4 ℃ can be stored for 2 years. A commercially available standard solution may also be used.
6.14.2 Titanium Standard Intermediate. ρ (Ti) = 50.0 mg/L.
Transfer the 5.00 ml titanium standard stock solution (6.14.1) in a 100 ml volumetric flask and dilute with nitric acid solution (6.10)
Capacity to mark, shake. Transferred to the polyethylene bottle, frozen at 4 ℃ can be stored for 1 year.
6.14.3 titanium standard use of liquid. ρ (Ti) = 2.50 mg/L.
Remove 5.00 ml of titanium standard intermediate (6.14.2) in a 100 ml volumetric flask, diluted with nitric acid solution (6.10)
Capacity to mark, shake. Transferred to the polyethylene bottle, refrigerated at 4 ℃ can be stored for 6 months.
6.15 argon. purity ≥99.999%.
6.16 Water microporous membrane. 0.45 μm pore size.
37 instruments and equipment
7.1 Graphite Furnace Atomic Absorption Spectrophotometer. with Zeeman background corrector.
7.2 graphite tube. pyrolytic coated graphite tube (commercially available).
7.3 hot plate. with temperature control function, temperature range 90 ℃ ~.200 ℃, temperature accuracy ± 5 ℃.
7.4 microwave digestion instrument. a programmable control function, the output power of 600 W ~ 1500 W, the temperature accuracy of ± 2.5 ℃. Equipped with
Microwave digestion tank with automatic pressure relief function.
7.5 Analysis of the balance. the amount of 0.1 mg.
7.6 Common laboratory equipment and equipment.
8 samples
8.1 Sample collection
The sample collection is carried out in accordance with the relevant provisions of HJ/T 91 and HJ/T 164.
8.2 Preservation of samples
8.2.1 Soluble molybdenum or soluble titanium samples
After the sample was collected, the initial filtrate was discarded by filtration with water microporous membrane (6.16), and immediately adding appropriate amount of nitric acid
Liquid (6.9) to pH to 1 to 2, and the assay was completed within 14 days.
8.2.2 Total molybdenum or total titanium samples
Immediately after the sample collection, the appropriate amount of nitric acid solution (6.9) was acidified to a pH of 1 to 2, and the analysis was completed within 14 days
Determination.
8.3 Preparation of sample
Soluble molybdenum or soluble titanium samples directly measured. Total molybdenum or total titanium samples shall be digested.
8.3.1 Preparation of total molybdenum test
8.3.1.1 Heater digestion
Remove 50.0 ml of shaken samples (8.2.2) In a 100 ml beaker, add 5 ml nitric acid (6.1), cover the surface
Dish, in the hot plate at 95 ℃ ± 5 ℃ heating to the solution remaining 2 ml ~ 3 ml, cooling, depending on the digestion situation can continue to join
Nitric acid (6.1), each time 3 ml, repeat the digestion process until no more brown smoke is generated and cooled. Slowly join 3
Ml of hydrogen peroxide (6.4), covered with a surface dish, in the hot plate 95 ± 5 ℃ heated reflux, as the case can continue to join the peroxide
Hydrogen (6.4), 1 ml at a time until only minor bubbles or no more changes in appearance, remove the surface pan, evaporate the solution to
Near dry and cool. Add 1 ml of nitric acid solution (6.9), with the experimental water to wash the beaker inner wall and surface dish at least 3 times, the whole
Volume into the 50 ml volumetric flask, with the experimental water volume to the mark, shake. If the sample has insoluble particles, it can be left or
Filtration with water microporous membrane (6.16), the clarified liquid stored in the polyethylene bottle.
8.3.1.2 Microwave digestion
Remove 25.0 ml of shaken samples (8.2.2) In a microwave digestion tank, add 5 ml nitric acid (6.1) and 1 ml
Hydrogen peroxide (6.4), after 30 minutes of standing for microwave digestion, 10 min from room temperature rose to 170 ℃ ± 5 ℃, keep the temperature 10
Min. After digestion and cooling to room temperature, move to the hot plate at 95 ℃ ± 5 ℃ heating to close to dry, cooling. Join
0.5 ml nitric acid solution (6.9), with the experimental water rinse digestion tank wall and lid at least 3 times, the whole amount into the 25 ml capacity
Bottle, with the experimental water volume to the mark, shake. If the sample has insoluble particles, can be standing or water microporous membrane
(6.16), and the clearant was stored in a polyethylene bottle.
4 Note 1. The total volume of the solution in the microwave digestion tank shall not exceed the limits specified by the instrument.
Note 2. The volume of the sample and the volume of the volume after sample preparation can be adjusted according to the sample concentration.
8.3.2 Preparation of total titanium samples
8.3.2.1 Heater digestion
Remove 50.0 ml of shaken samples (8.2.2) In a 100 ml beaker, add 5 ml nitric acid (6.1), cover the surface
Dish, in the hot plate at 95 ℃ ± 5 ℃ heating to the solution remaining 2 ml ~ 3 ml, cooling, depending on the digestion situation can continue to join
Nitric acid (6.1), each time 3 ml, repeat the digestion process 1 ~ 2 times. If the digestion is clear and transparent or the appearance is no longer made
Change, remove the surface of the dish, the solution evaporated to near dry, cooling; if the digestion turbidity is not clear, add 5 ml sulfuric acid (6.3),
Cover the surface of the dish, in the hot plate 95 ℃ ± 5 ℃ heating reflux, as the case can continue to add nitric acid (6.1), each 3 ml,
Until no more brown smoke is produced. Raise the temperature to.200 ℃ ± 5 ℃, heat reflux to the emergence of SO3 white smoke, and the solution clear
Bright or appearance no longer change, remove the surface dish, the solution evaporated to near dry, cooling.
Add 1 ml of nitric acid solution (6.9), with experimental water to wash the inner wall of the beaker and the surface dish at least 3 times, the whole volume into 50 ml
Capacity bottle, with the experimental water volume to the mark, shake. If the sample has insoluble particles, can be standing or water microporous filter
Membrane (6.16) was filtered and the clearant was stored in a polyethylene bottle.
8.3.2.2 Microwave digestion
Refer to 8.3.1.2 for operation. If the sample is turbid after digestion, add 3 ml of sulfuric acid (6.3), stamped
Heating on the hot plate 95 ℃ ± 5 ℃ reflow, as the case can continue to add nitric acid (6.1), each 2 ml until no longer brown
Smoke generated. Raise the temperature to.200 ℃ ± 5 ℃, heat reflux to the emergence of SO3 white smoke, and the solution is clear or the appearance of no longer hair
Change, open the lid, the solution evaporated to near dry, cooling. Add 0.5 ml nitric acid solution (6.9), with the experimental water leaching elimination
Decoction of the inner wall and lid at least 3 times, the full amount into the 25 ml volumetric flask, with the experimental water volume to the mark, shake. in case
The sample is insoluble in the particles, can be standing or water microporous membrane (6.16) filter, take the clear liquid stored in the polyethylene bottle.
8.4 Preparation of laboratory blank samples
A laboratory blank sample was prepared according to the same procedure for sample preparation (8.3) using the same batch of experimental water instead of the sample.
9 Analysis steps
9.1 Instrument reference conditions
Select the optimum measurement according to the instrument manual. Instrument reference measurement conditions in Table 1.
Table 1 Reference measurement conditions
Determination of elemental molybdenum (Mo) titanium (Ti)
Light source Molybdenum hollow cathode lamp Titanium hollow cathode lamp
Lamp current (mA) 7 20
Determination of wavelength (nm) 313.3 365.4
Passband width (nm) 0.5 0.2
Drying temperature (℃)/drying time (s) 85 ~ 125/55 85 ~ 125/55
Ashing temperature (° C)/ashing time (s) 1200/15 1400/20
Atomization temperature (℃)/atomization time (s) 2800/3.0 2800/5.5
5 Clear temperature (° C)/Clear time (s) 2850/2 2850/2
Argon flow rate (ml/min) 300 300
Whether the atomization stage is stopped
Injection volume (μl) 20 20
Background correction method Zeeman background correction Zeeman background correction
9.2 Calibration curve calibration
9.2.1 molybdenum calibration curve
Remove 0.00 ml, 0.25 ml, 1.00 ml, 2.00 ml, 3.00 ml, 4.00 ml and 5.00 ml molybdenum respectively
Liquid (6.13.3) in a group of 50 ml volumetric flask, with nitric acid solution (6.10) constant volume to the mark, shake. This standard series
The concentrations of molybdenum were 0.0 μg/L, 2.5 μg/L, 10.0 μg/L, 20.0 μg/L, 30.0 μg/L, 40.0 μg/L and 50.0
Μg/L. From low concentration to high concentration in turn to the graphite tube into the 20 μl standard series, according to the instrument reference conditions (9.1) measured
Absorbance. With the absorbance as the ordinate, the molybdenum standard series mass concentration is abscissa, and the calibration curve is established by linear regression method.
9.2.2 Titanium calibration curve
Remove 0.00 ml, 0.50 ml, 1.00 ml, 2.00 ml, 3.00 ml, 4.00 ml and 5.00 ml titanium standard respectively
Liquid (6.14.3) in a group of 50 ml volumetric flask, with nitric acid solution (6.10) constant volume to the mark, shake. This standard series
The concentration of titanium in the medium was 0 μg/L, 25 μg/L, 50 μg/L, 100 μg/L, 150 μg/L,.200 μg/L and 250 μg/L, respectively.
From low concentration to high concentration in turn to the graphite tube into the 20 μl standard series, according to the instrument reference conditions (9.1) measured absorbance
degree. With the absorbance as the ordinate, the titanium standard series mass concentration is abscissa, and the calibration curve is established by linear regression method.
9.3 blank determination
Prepare the prepared blank sample (8.4) according to the same conditions as the drawing calibration curve (9.1) and step (9.2)
Line determination.
9.4 Sample determination
The prepared sample (8.3) was subjected to the same conditions as in the drawing of the calibration curve (9.1) and step (9.2)
set. If the measurement results exceed the calibration curve range, the sample should be diluted with nitric acid solution (6.10) and re-determined.
Note 3. If SO42-interference is present in the sample containing molybdenum, 5 μl of palladium nitrate-magnesium nitrate mixed solution (6.12) is added to 20 μl of sample
And 20 μl standard series were co-injected into the graphite tube.
10 results are calculated and expressed
10.1 Result calculation
The mass concentration of molybdenum or titanium in the sample is calculated according to equation (1)
Vf 11 -06 (1)
Where. ρ - mass concentration of molybdenum or titanium in the sample, μg/L;
Ρ1 - from the calibration curve obtained in the sample molybdenum or titanium mass concentration, μg/L;
F - the dilution factor of the sample;
6V - the volume of the sample taken, ml;
V1 - volume of the sample after preparation, ml.
10.2 results are shown
10.2.1 molybdenum results
When the determination result is less than 10 μg/L, one decimal place is retained; when the result is greater than or equal to 10 μg/L,
Keep three valid digits.
10.2.2 Titanium results
When the determination result is less than 100 μg/L, it is retained to the integer position. When the measurement result is greater than or equal to 100 μg/L,
Leaving three valid digits.
11 precision and accuracy
11.1 precision
Six laboratories with soluble molybdenum concentrations of 1.4 μg/L and 6.4 μg/L of surface water samples and surface water spiked samples
Six repeated measurements were made. the relative standard deviations in the laboratory were 10% to 16% and 3.5% to 6.4%, respectively; inter-laboratory phase
The standard deviations were 15% and 4.5%, respectively, and the reproducibility limits were 0.6 μg/L and 1.0 μg/L, respectively. The reproducibility limits were 0.8
Μg/L and 1.2 μg/L. The surface water spiked samples with soluble titanium concentrations of 10 μg/L and 30 μg/L were subjected to 6 times
Repeat the determination. the relative standard deviation of the laboratory were 7.1% to 12% and 4.0% to 5.0%; the relative standard deviation between the laboratory
Respectively, 10% and 2.5%; repeatability of 3 μg/L and 4 μg/L, respectively; reproducibility limit of 4 μg/L and 5 μg/L, respectively.
Six laboratories conducted six replicates of groundwater samples with a total molybdenum concentration of 5.4 μg/L. the laboratory phase
Standard deviation of 5.3% to 7.6%; laboratory relative standard deviation of 5.7%; repeatability limit of 1.0 μg/L; reproducibility limit
Was 1.3 μg/L. Six replicates of groundwater spikes with total titanium concentrations of 30 μg/L and 52 μg/L were tested for six replicates.
The relative standard deviations in the laboratory were 4.9% ~ 7.0% and 4.1% ~ 4.9%, respectively. The relative standard deviations were 6.0%
And 4.2% respectively. The reproducibility limits were 5 μg/L and 7 μg/L, respectively. The reproducibility limits were 7 μg/L and 9 μg/L, respectively.
Six laboratories carried out samples of waste water samples with total molybdenum concentration of 8.0 μg/L and 27.6 μg/L
6 times the repeated determination. the relative standard deviation of the laboratory were 4.5% to 5.6% and 4.5% to 5.8%; inter-laboratory relative standard
And the reproducibility limits were 1.2 μg/L and 4.0 μg/L, respectively. The reproducibility limits were 1.5 μg/L
And 4.5 μg/L. Six samples of waste water samples with total titanium mass concentration of 30 μg/L and 223 μg/L were collected
Repeat the determination. the relative standard deviation of the laboratory were 5.3% to 7.9% and 2.6% to 2.9%; the relative standard deviation between the laboratory
Respectively. The reproducibility limits were 6 μg/L and 18 μg/L, respectively. The reproducibility limits were 8 μg/L and 20 μg/L, respectively.
11.2 Accuracy
Six laboratories tested concentrations of 161 μg/L ± 18 μg/L, with a concentration of 503 μg/L ± 49 μg/L
Of the titanium standard samples were measured. the relative error were -6.2% to 0% and -3.4% to 2.4%, the relative error of the final value
Respectively -3.1% ± 4.8% and -1.0% ± 4.0%.
Six laboratories on the surface water samples were spiked recovery test. molybdenum plus standard recovery rate of 95.8% to 106%, plus standard back
The final yield was 101% ± 8.2%. Titanium spiked recovery rate of 97.5% to 103%, spiked recovery rate of the final value
101% ± 4.2%.
Six laboratories on the groundwater samples were spiked recovery test. molybdenum plus standard recovery rate of 97.3% to 104%, plus standard back
The final yield was 101% ± 4.2%. Titanium spiked recovery rate of 96.1% to 109%, spiked recovery rate of the final value
7101% ± 8.0%.
...
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