Ammonium (Type-IV)
OIV-MA-AS322-01 Ammonium
Type IV method
- Principle
Retention of the ammonium cation on a weak cation exchange resin, elution using an acidic solution, distillation of the eluent and determination of the ammonia in the distillate by titration with a standardized solution of hydrochloric acid.
- Apparatus
2.1. Cation exchange resin column
A 50 mL burette with a glass stopcock fitted with a glass wool plug containing 25 g of weak cation exchange resin (e.g. Amberlite IR‑50, 80‑100 mesh).
Wash alternately with 1 M sodium hydroxide solution and 1 M hydrochloric acid solution. Wash the resin with distilled water until a negative reaction of chloride ion with silver nitrate is obtained. Pass 50 mL of neutral buffer slowly through the glass column, rinse with distilled water until phosphates begin to elute as detected using a saturated solution of lead acetate.
2.2. Distillation apparatus
Use the apparatus described in the chapter on Alcoholic Strength 3.1
The condensate is transferred to the conical flask through a drawn‑out tube touching the bottom of the vessel.
Alternatively, it is possible to use the steam distillation apparatus used in the chapter on Volatile Acidity 4.1 or other apparatus that can be used for the following experiments which check the purity of the reagents.
- Place 40‑45 mL of 30 % sodium hydroxide solution (v/v), 50 mL of water and 50 mL hydrochloric acid, 1 M, in the distillation flask. Distil half the volume and collect the distillate in 30 mL of boric acid solution, 40 g/L to which 5 drops of methyl red have been added. Adjust the color to pink by the addition of 0.1 mL of 0.1 M hydrochloric acid.
- A test (similar to that described in a) is conducted using, 10 mL 0.05 M ammonium sulfate solution, containing 3.55 g/L of anhydrous ammonium sulfate, (NH4)2SO4. In this case, between 10 and 10.1 mL 0.1 M hydrochloric acid must be used to obtain the change of color of the indicator.
- Reagents
3.1. Hydrochloric acid solution, 1 M.
3.2. Sodium hydroxide, 1 M.
3.3. Neutral solution to wash the resin:
-
di-sodium hydrogen phosphate
: 15 g
-
potassium di-hydrogen phosphate
: 3.35 g
- water to 1000 mL
Verify pH is 7
0.2
3.4. Sodium hydroxide solution, 30% (m/m), ρ = 1.33 g/mL
3.5. Hydrochloric acid solution, 0.1 M.
3.6. Phenolphthalein solution, 1% (m/v), in neutral ethanol, 96% (V/V)
3.7. Bromocresol green solution, 1% (m/v):
- bromocresol green 1 g
- dissolve in 0.1 M sodium hydroxide solution, 14 mL
-
water to 100 mL
- Methyl red ethanol/water solution, 0.2% (v/v):
- methyl red 0.2 g
- alcohol, 95% (vol) 60 mL
-
water to 100 mL
- Boric acid solution
- Boric acid 40g
- Water to 1000mL
Boric acid usually contains a small quantity of alkaline impurities and it is possible to correct this by adding 5 drops of indicator to this solution and adjusting to a pink color by means of few drops of 0.1 M hydrochloric acid (1 mL at most).
- Procedure
Transfer 50 mL of the sample to be analyzed into a 250 mL beaker. Add a quantity of sodium hydroxide, 1 M, equal to half of (n‑0.5) mL, where n is the volume sodium hydroxide solution, 0.1 M, used in the total acidity titration on 10 mL of wine. Pass this mixture through the cation exchange column (2.1) at a rate of one drop every two seconds. The eluent pH should lie between 4 and 5. Rinse the column with 50 mL of distilled water at the same flow rate.
Ammonium and other cations are quantitatively retained on the column. Amides, oligopeptides and nearly all amino acids are eluted by the washing procedure.
Elute the cations retained on the resin with 50 mL of 1 M hydrochloric acid, (3.1) and rinse with 50 mL distilled water.[*] The eluate and the water washings are combined in a 1 liter round bottom distillation flask.
Add one drop of phenolphthalein, 1% (m/v), and sufficient quantity of 30% sodium hydroxide solution (m/v)(3.4), to obtain a true alkaline reaction, constantly cooling the flask during this addition.
Distil about half the volume of the liquid from the distillation flask, into 30 mL of 4% boric acid (m/v)(3.9).
The distillate is titrated with 0.1 M hydrochloric acid (3.5), in the presence of bromocresol green or methyl red. Record the volume of hydrochloric acid used (n).
- Expression of results
The content of ammonium (NH4) ions is expressed in milligrams per liter to the nearest
whole number.
5.1. Calculation
The content of ammonium ions, expressed in milligrams per liter is:
- 36 x n
When wines with low ammonium content are analyzed, the determination is conducted using 100 mL of wine. In this case the quantity of ammonium is given by:
- 18 x n
Bibliography
Usual Method:
- Jaulmes P., Analyse des vins, 1951, 220, Montpellier
- Kourakou Mme S., Ann. Fals. Exp. Chim., 1960, 53, 337.
[*]* The column should be washed with 50 mL of neutral buffer solution and rinsed with water before using the column for another determination.
Potassium (AAS) (Type-II)
OIV-MA-AS322-02A Potassium
Type II method
- Principle
Potassium is determined directly in diluted wine by atomic absorption spectrophotometry after the addition of cesium chloride to suppress ionization of potassium.
- Method
2.1. Apparatus
Atomic absorption spectrophotometer, equipped with an air - acetylene burner
Potassium hollow cathode lamp
2.2. Reagents
2.2.1. Solution containing 1 g of potassium per liter.
Use a standard commercial solution containing 1 g of potassium per liter. This solution may be prepared by dissolving 4.813 g of potassium hydrogen tartrate (
) in distilled water making up the volume to 1 liter with water.
2.2.2. Matrix (model) solution:
- citric acid monohydrate :3.5 g
- sucrose 1.5 g
- glycerol 5.0 g
-
anhydrous calcium chloride, (Ca
) 50 mg
-
anhydrous magnesium chloride (Mg) :50 mg
- absolute alcohol 50 mL
-
water to 500 mL
- Cesium chloride solution containing 5% cesium:
Dissolve 6.33 g of cesium chloride, CsCl, in 100 mL of distilled water.
2.3. Procedure
2.3.1. Preparation of sample
Pipette 2.5 mL of wine (previously diluted 1/10) into a 50 mL volumetric flask, add 1 mL of the cesium chloride solution and make up to the mark with distilled water.
2.3.2. Calibration
Introduce 5.0 mL of the matrix solution into each one of five of 100mL volumetric flasks and add 0, 2.0, 4.0, 6.0 and 8.0 mL respectively of the 1 g/L potassium solution (previously diluted 1/10). Add 2 mL of the cesium chloride solution to each flask and make up to 100 mL with distilled water.
The standard solutions contain 0, 2, 4, 6 and 8 mg of potassium per liter respectively and each contains 1 g of cesium per liter. Keep these solutions in polyethylene bottles.
2.3.3. Determination
Set the wavelength to 769.9 nm. Zero the absorbance scale using the zero standard solution (2.3.2). Aspirate the diluted wine (2.3.1) directly into the spectrophotometer, followed in succession by the standard solutions (2.3.2). Record the absorbance for each solution and repeat.
2.4. Expression of results
2.4.1. Method of calculation
Plot a graph showing the variation in absorbance as a function of potassium concentration in the standard solutions.
Record the mean absorbance obtained with diluted wine on this graph and determine its potassium concentration C in milligrams per liter.
The potassium concentration, expressed in milligrams per liter of the wine to the nearest whole number, is F x C, where F is the dilution factor (here 200).
2.4.2. Repeatability (r):
-
r = 35 mg/L.
- Reproducibility (R):
-
R = 66 mg/L.
- Other ways of expressing results
In milliequivalents per liter:
- 0.0256 x F x C.
In mg potassium hydrogen tartrate per liter:
- 4.813 x F x C.
Potassium (flame photometry) (Type-III)
OIV-MA-AS322-02B Potassium
Type III method
- Principle
Potassium is determined directly in diluted wine by flame photometry.
Note: The gravimetric determination of potassium tetraphenylborate precipitated from the solution of the ash of wine is a precise method for the determination of potassium and is described in the annex.
- Method
2.1. Apparatus
2.1.1. Flame photometer supplied with an air‑butane mixture.
2.2. Reagents
2.2.1. Reference solution containing 100 mg potassium per liter
- Absolute alcohol 10 mL
-
Citric acid
700 mg
- Sucrose 300 mg
- Glycerol 1000 mg
- Sodium chloride, NaCl 50.8 mg
-
Anhydrous calcium chloride, Ca 10 mg
- Anhydrous potassium hydrogen tartrate 481.3 mg
- water to 1000 mL
Dissolve the potassium hydrogen tartrate in 500 mL of very hot distilled water, mix this solution with 400 mL of distilled water in which the other chemicals have already been dissolved, and make up to one liter.
2.2.2. Dilution solution
- Absolute alcohol 10 mL
- Citric acid anhydrous 700 mg
- Sucrose 300 mg
- Glycerol 1000 mg
- Sodium chloride, NaCl 50.8 mg
-
Anhydrous calcium chloride, Ca 10 mg
-
Anhydrous magnesium chloride, Mg 10 mg
- Tartaric acid 383 mg
- Water to 1000 mL
Preserve the solutions in polyethylene bottles by adding two drops of allyl isothiocyanate (3-isothiocyanato-1-propene; 
=CHCH2NCS).
2.3. Procedure
2.3.1. Calibration
Place 25, 50, 75 and 100 mL of the reference solution into a set of four 100 mL volumetric flasks and make up to 100 mL with the dilution solution to give solutions containing 25, 50, 75 and 100 mg of potassium per liter respectively.
2.3.2. Determination
Make measurements at 766 nm. and adjust the 100% transmission using distilled water. Successively aspirate the standard solutions directly into the burner of the photometer, followed by wine diluted 1/10 with distilled water and note the readings. If necessary, the wine already diluted 1/10 may be further diluted with the dilution solution (2.2.2).
2.4. Expression of results
2.4.1. Method of calculation
Plot a graph of the variation in percentage transmission as a function of the potassium concentration in the standard solutions. Record the transmission obtained for the sample of diluted wine on this graph and determine the corresponding potassium concentration C.
The potassium concentration in mg potassium per liter to the nearest whole number will be:
- F x C
where F is the dilution factor.
2.4.2. Repeatability (r):
-
r = 17 mg/L.
- Reproducibility (R)
-
R = 66 mg/L.
- Other ways of expressing results:
In milliequivalents per liter: 0.0256 x F x C.
In mg potassium hydrogen tartrate per liter 4.813 x F x C.
Sodium (AAS) (Type-II)
OIV-MA-AS322-03A Sodium
Type II method
- Principle
Sodium is determined directly in the wine by atomic absorption spectrophotometry after the addition of cesium chloride to suppress ionization of sodium.
- Method
2.1. Apparatus
Atomic absorption spectrophotometer equipped with an air‑acetylene burner.
Sodium hollow cathode lamp.
2.2. Reagents
2.2.1. Solution containing 1 g of sodium per liter:
The use of a commercial standard solution containing 1 g of sodium per liter is preferred.
Alternatively, this solution may be prepared by dissolving 2.542 g of anhydrous sodium chloride (NaCl) in distilled water and making up to a volume of 1 liter.
Keep this solution in a polyethylene bottle.
2.2.2. Matrix (model) solution:
Citric acid monohydrate, (
) 3.5 g
Sucrose 1.5 g
Glycerol 5.0 g
Anhydrous calcium chloride (Ca
). 50 mg
Anhydrous magnesium chloride, (Mg) 50 mg
Absolute alcohol 50 mL
De‑ionized water to 500 mL
2.2.3. Cesium chloride solution containing 5% cesium
Dissolve 6.330 g of cesium chloride, CsCl, in 100 mL of distilled water.
2.3. Procedure
2.3.1. Preparation of the sample
Pipette 2.5 mL of wine into a 50 mL volumetric flask, add 1 mL of the cesium chloride solution (2.2.3) and make up to the mark with distilled water.
2.3.2. Calibration
Place 5.0 mL of the matrix solution in each one of five 100 mL volumetric flasks and add 0, 2.5, 5.0, 7.5 and 10 mL respectively of a 1:100 dilution of the 1 g/L sodium solution. Add 2 mL of the cesium chloride solution (2.2.3) to each flask and make up to 100 mL with distilled water.
The standard solutions prepared in this way contain 0.25, 0.50, 0.75 and 1.00 mg of sodium per liter respectively and each contains 1 g of cesium per liter. Keep these solutions in polyethylene bottles.
2.3.3. Determination
Set the absorbance wavelength to 589.0 nm. Zero the absorbance scale using the zero standard solution. Aspirate the diluted wine (2.3.1) directly into the spectrophotometer, followed in succession by the standard solutions (2.3.2). Record each absorbance and repeat each measurement.
2.4. Expression of results
2.4.1. Method of calculation
Plot a graph of measured absorbance versus the sodium concentration in the standard solutions.
Record the absorbance obtained with the diluted wine on this graph and determine its sodium concentration C in milligrams per liter.
The sodium concentration in milligrams per liter of the wine will then be F x C, expressed to the nearest whole number, where F is the dilution factor.
2.4.2. Repeatability (r ):
- r = 1 + 0.024 xi mg/L.
= concentration of sodium in the sample in mg/L.
2.4.3. Reproducibility (R):
- R = 2.5 + 0.05 xi mg/L.
= concentration of sodium in the sample in mg/L.
Sodium (flame photometry) (Type-III)
OIV-MA-AS322-03B Sodium
Type III method
- Principle
Sodium is determined directly in diluted wine (at least 1 mL:10 mL) by flame photometry.
- Method
2.1. Apparatus
2.1.1. Flame photometer supplied with an air‑butane mixture.
2.2. Reagents
2.2.1. Reference solution containing 20 mg sodium per liter
Absolute alcohol 10 mL
Citric acid monohydrate (
) 700 mg
Sucrose 300 mg
Glycerol 1000 mg
Potassium hydrogen tartrate 481.3 mg
Anhydrous calcium chloride, Ca
10 mg
Anhydrous magnesium chloride, Mg 10 mg
Dry sodium chloride, NaCl 50.84 mg
Water to 1000 mL
2.2.2. Dilution solution
Absolute alcohol 10 mL
Citric acid monohydrate () 700 mg
Sucrose 300 mg
Glycerol 1000 mg
Potassium hydrogen tartrate 481.3 mg
Anhydrous calcium chloride, Ca 10 mg
Anhydrous magnesium chloride, Mg 10 mg
Water to 1000 mL
To prepare 2.2.1 and 2.2.2, dissolve the potassium hydrogen tartrate in approximately 500 mL of very hot distilled water, mix with 400 mL of distilled water into which the other chemicals have already been dissolved, and make up to one liter.
Preserve the solutions in polyethylene bottles by adding two drops of allyl isothiocyanate to each.
2.3. Procedure
2.3.1. Calibration
Place 5, 10, 15, 20 and 25 mL of the reference solution in each of five 100 mL volumetric flasks and make up to 100 mL with the dilution solution to give solutions containing 1, 2, 3, 4 and 5 mg of sodium per liter respectively.
2.3.2. Determination
Carry out measurements at 589.0 nm and adjust the 100% transmission using distilled water. Successively aspirate the standard solutions directly into the photometer, followed by the wine diluted 1:10 with distilled water and note the percentage transmission of each. If necessary, the wine already diluted 1:10 may be further diluted with dilution solution.
2.4. Expression of results
2.4.1. Calculation method
Plot a graph of the percentage transmittance versus sodium concentration of the standard solutions. Record the transmission obtained for the diluted wine sample on this graph and note the concentration, C, of sodium in the wine.
The sodium concentration in mg of sodium per liter will be:
- F x C
where F is the dilution factor.
2.4.2. Repeatability (r)
- r = 1.4 mg/L (except for liqueur wine)
-
r = 2.0 mg/L for liqueur wine.
- Reproducibility (R)
- R = 4.7 + 0.08 xi mg/L.
-
= sodium concentration in the sample in mg/L.
Calcium (Type-II)
OIV-MA-AS322-04 Calcium
Type II method
- Principle
Calcium is determined directly on diluted wine by atomic absorption spectrophotometry after the addition of an ionization suppression agent.
- Apparatus
2.1. Atomic absorption spectrophotometer fitted with an air‑acetylene burner.
2.2. Calcium hollow cathode lamp.
-
Reagents
- Calcium standard solution 1 g/L. Use of a standard commercial calcium solution, 1 g/L, is preferred.
Alternatively this solution may be prepared by dissolving 2.5 g of calcium carbonate, CaC
, in sufficient hydrochloric acid (concentrated hydrochloric acid diluted 1:10) to dissolve it completely and making up to one liter with distilled water.
3.2. Dilute calcium standard solution, 50 mg/L
Note : Store the calcium solutions in polyethylene containers.
3.3. Dilute lanthanum standard solution, 50 g/L
Dissolve 13.369 g of lanthanum chloride, La
in distilled water; add 1 mL, of dilute hydrochloric acid (concentrated hydrochloric acid diluted 1/10) and make up to 100 mL with distilled water.
-
Procedure
- Preparation of sample
Place 1 mL of wine and 2 mL of the lanthanum chloride solution (3.3) in a 20 mL volumetric flask and make up to the mark with distilled water. The diluted wine contains 5 g lanthanum per liter.
Note: For sweet wines, 5 g lanthanum per liter is sufficient provided that the dilution reduces the sugar content to less than 2.5 g/L. For wines with higher concentrations of sugar, the lanthanum concentration should be increased to 10 g/L.
4.2. Calibration
Place 0, 5, 10, 15 and 20 mL, of dilute standard calcium solution (3.2) respectively into each of five 100 mL volumetric flasks, followed by 10 mL of the lanthanum chloride solution (3.3) and make up to 100 mL with distilled water. The solutions prepared in this way contain 0, 2.5, 5.0, 7.5 and 10 mg of calcium per liter respectively, and each contains 5 g of lanthanum per liter. These solutions should be stored in polyethylene bottles.
4.3. Determination
Set the absorbance wavelength to 422.7 nm. Zero the absorbance scale using the zero standard (4.2). Aspirate the diluted wine directly into the spectrophotometer, followed in succession by the five standard solutions (4.2) and record the absorbance. Repeat each measurement.
-
Expression of results
- Method of calculation
Plot a graph showing the variation in absorbance as a function of the calcium concentration in the standard solutions.
Record the mean value of the absorbance obtained with the sample of diluted wine on this graph and read its calcium concentration C. The calcium concentration in milligrams per liter of the wine to the nearest whole number is given by: 20 x C.
5.2. Repeatability (r)
- Concentration<60mg/L: r=2.7mg/L.
-
Concentration > 60 mg/L: r = 4 mg/L.
- Reproducibility (R)
-
R mg/L = 0.114 - 0.5.
where = concentration in the sample in mg/L.
Iron (AAS) (Type-IV)
OIV-MA-AS322-05A Iron
Type IV method
- Principle
After suitable dilution of the wine and removal of alcohol, iron is determined directly by atomic absorption spectrophotometry.
-
Method
-
Apparatus
- Rotary evaporator with thermostatically controlled water bath.
- Atomic absorption spectrophotometer equipped with an air‑acetylene burner.
- Iron hollow cathode lamp.
-
Apparatus
2.2. Reagents
2.2.1. Concentrated standard iron solution containing 1 g Fe (III) per liter.
Use a standard commercial solution, 1 g/L. This solution may be prepared by dissolving 8.6341 g of ferric ammonium sulfate, FeNH4 (SO4)2.12H20, in distilled water slightly acidified with hydrochloric acid, 1 M, and making up to one liter.
2.2.2. Dilute standard iron solution containing 100 mg iron per liter.
2.3. Procedure
2.3.1. Preparation of sample
Remove the alcohol from the wine by reducing the volume of the sample to half its original size using a rotary evaporator (50 to 60 C). Make up to the original volume with distilled water.
If necessary, dilute prior to analysis with distilled water.
2.3.2. Calibration
Place 1, 2, 3, 4 and 5 mL of the solution containing 100 mg iron per liter (2.2.2) respectively into each of five 100 mL volumetric flasks and make up to 100 mL with distilled water. The solutions prepared in this way contain 1, 2, 3, 4 and 5 mg of iron per liter respectively. These solutions should be stored in polyethylene bottles.
2.3.3. Determination
Set the absorption wavelength to 248.3 nm. Zero the absorbance scale using distilled water. Aspirate the diluted sample directly into the spectrophotometer, followed in succession by the five standards (2.3.2). Record the absorbance. Repeat each measurement.
2.4. Expression of results
2.4.1. Method of calculation
Plot a graph giving the variation in absorbance as a function of the iron concentration in the standard solutions. Record the mean value of the absorbance obtained with the diluted wine sample on this graph and read its iron concentration C.
The iron concentration in milligrams per liter of the wine to one decimal place is given by:
|
F x C |
where F is the dilution factor.
Iron (colorimetry) (Type-IV)
OIV-MA-AS322-05B Iron
Type IV method
- Principle
After digestion in hydrogen peroxide, 30%, the total iron, present as Fe (III) state, is reduced to the Fe (II) and quantified by the formation of a colored orthophenanthroline complex.
- Method
2.1. Apparatus
2.1.1. Kjeldahl flask, 100 mL.
2.1.2. Spectrophotometer enabling measurements to be made at a wavelength of 508 nm.
2.2. Reagents
2.2.1. Hydrogen peroxide,
, 30% (m/v), solution, iron free.
2.2.2. Hydrochloric acid, 1 M, iron free.
2.2.3. Ammonium hydroxide (ρ20 = 0.92 g/mL).
2.2.4. Pumice stone grains, pretreated with boiling hydrochloric acid diluted 1/2 and washed with distilled water.
2.2.5. Hydroquinone solution,
, 2.5%, acidified with 1 mL concentrated sulfuric acid ρ20 = 1.84 g/mL) per 100 mL of solution. This solution must be kept in an amber bottle in the refrigerator and discarded at the slightest sign of darkening.
2.2.6. Sodium sulfite solution, Na2S03, 20%, prepared from neutral anhydrous sodium sulfite.
2.2.7. ortho-phenanthroline solution, C12H8N2, 0.5%, in alcohol, 96% vol.
2.2.8. Ammonium acetate solution, CH3COONH4, 20% (m/v).
2.2.9. Fe (III) solution containing 1 g of iron per liter. Use of a commercial solution is preferred. Alternatively, a 1000 mg/L Fe (III) solution can be prepared by dissolving 8.6341 g of ferric ammonium sulfate,
, in 100 mL of hydrochloric acid, 1 M, and making up the volume to one liter with the hydrochloric acid, 1 M.
2.2.10. Dilute standard iron solution containing 100 milligrams of iron per liter.
2.3. Procedure
2.3.1. Digestion
2.3.1.1. For wines with sugar content below 50 g/L
Combine 25 mL of the wine, 10 mL of the hydrogen peroxide solution and a few grains of pumice into the 100 mL Kjeldah1 flask. Concentrate the mixture to a volume of 2 to 3 mL by heating. Allow to cool and add sufficient ammonium hydroxide to make the residue alkaline thus precipitating hydroxides while taking care not to wet the walls of the flask.
After cooling, carefully add hydrochloric acid, to the alkaline liquid to dissolve the precipitated hydroxides and transfer the resulting solution to a 100 mL volumetric flask. Rinse the Kjeldahl flask with hydrochloric acid, and combined the solutions in the volumetric flask and make up to 100 mL.
2.3.1.2. For musts and wines with sugar content above 50 g/L
- If the sugar content is between 50 and 200 g/L, the 25 mL wine sample is treated with 20 mL of hydrogen peroxide solution. Continue as in 2.3.1.1.
-
If the sugar content is greater than 200 g/L, the samples of wine or must should be diluted 1/2 or possibly 1/4 before being treated with 20 mL of hydrogen peroxide solution. Continue as in 2.3.1.1.
- Blank experiment
Carry out a blank trial with distilled water using the same volume of hydrogen peroxide solution as the amount used for the mineralization, following the experimental protocol described in 2.3.1.1.
2.3.3. Determination
Introduce 20 mL of the hydrochloric acid wine digest solution and 20 mL, of the hydrochloric acid solution obtained from the 'blank experiment' into two separate 50 mL volumetric flasks. Add 2 mL of hydroquinone solution, 2 mL of sulfite solution and 1 mL of ortho-phenanthroline. Allow to stand for 15 minutes, during which time Fe (III) is reduced to Fe (II). Then add 10 mL of ammonium acetate solution, make each up to 50 mL with distilled water and shake the two volumetric flasks. Use the solution originating from the blank experiment to zero the absorbance scale at 508 nm and measure the absorbance of the wine solution at the same wavelength.
2.3.4. Calibration
Place 0.5, 1, 1.5 and 2 mL of the 100 mg of iron per liter solution into each of four 50 mL volumetric flasks, and add 20 mL of distilled water to each. Carry out the procedure described in 2.3.3 to measure the absorbance of each of these standard solutions, which contain 50, 100, 150 and 200 micrograms of iron respectively.
2.4. Expression of results
2.4.1. Method of calculation
Plot a graph giving the variation in absorbance as a function of the iron concentration in the standard solutions. Record the absorbance of the test solution and read off the iron concentration C in the hydrochloric acid digestion solution, i.e. in 5 mL of the wine being analyzed.
The iron concentration in milligrams per liter of the wine to one decimal place is given by: 200 C
If the wine (or must) has been diluted, the iron concentration in milligrams per liter of the wine to one decimal place is given by: 200 F C
where F is the dilution factor.
Copper (Type-II)
OIV-MA-AS322-06 Copper
Type IV method
- Principle
The method is based on the use of atomic absorption spectrophotometry.
- Apparatus
2.1. Platinum dish.
2.2. Atomic absorption spectrophotometer.
2.3. Copper hollow cathode lamp.
2.4. Gas supplies: air‑acetylene or nitrous oxide/acetylene.
- Reagents
3.1. Metallic copper.
3.2. Nitric acid (ρ20 = 1.38 g/mL), 65%.
3.3. Nitric acid (3.2), diluted 1/2 (v/v) with water.
3.4. Solution containing 1g of copper per L.
Use of a standard commercial copper solution is preferred. Alternatively this solution may be prepared by weighing 1.000 g of metallic copper and transferring it without loss to a 1000 mL volumetric flask. Add just enough dilute nitric acid to dissolve the metal, add 10 mL of concentrated nitric acid and make up to the mark with double distilled water.
3.5. Solution containing copper at 100 mg/L
Transfer 10 mL, of the 1 g/L solution 3.4. into a 100 mL volumetric flask, and make up to the mark with double‑distilled water.
3.6. Double‑distilled water
-
Procedure
- Preparation of sample and determination of copper
Place 20 mL sample in a 100 mL volumetric flask and make up to 100 mL with double‑distilled water. Modify the dilution if necessary to obtain a response within the dynamic range of the detector.
Measure the absorbance at 324.8 nm. Set the zero with double distilled water.
4.2. Constructing a standard curve
Pipette 0.5, 1 and 2 mL of copper solution into each of three 100 mL volumetric flasks and make to the volume with double distilled water; the solutions contain 0.5, 1 and 2 mg of copper per liter respectively. Measure the absorbance of standard solutions and the sample prepared in and repeat each measurement. Plot a graph showing the variation in absorbance as a function of the copper concentration in the standard solutions.
- Expression of results
5.1. Method of calculation
Using the measured absorbance of the samples read off the concentration C in mg/L from the calibration curve.
If F is the dilution factor, the concentration of the copper present is given in milligrams per liter by:
|
|
It is quoted to two decimal places.
Notes:
a) Select a sample dilution appropriate to the sensitivity of the apparatus to be used and the concentration of the copper present in the sample.
b) Proceed as follows when very low copper concentrations are expected in the sample to be analyzed: Place 100 mL of the sample in a platinum dish and evaporate on a water bath at 100 C until it becomes syrupy. Add 2.5 mL of concentrated nitric acid drop wise, covering the bottom of the dish completely. Carefully ash the residue on an electric hotplate or over a low flame; then place the dish in a muffle furnace set at 500 ± 25C and leave for about one hour. After coo1ing, moisten the ash with 1 mL of concentrated nitric acid while crushing it with a glass rod; allow the mixture to evaporate and ash again as before. Place the dish in the muffle furnace again for 15 min; repeat the treatment with nitric acid at least three times. Dissolve the ash by adding 1 mL of concentrated nitric acid and 2 mL of double distilled water to the dish and transfer to a 10 mL flask. Wash the dish three times using 2 mL of double distilled water each time. Finally, make to volume with double distilled water. Proceed to analyze the sample as in 4.1 but use 10 mL of solution. Take into account the change in dilution factor when calculating the results.
Magnesium (Type-II)
OIV-MA-AS322-07 Magnesium
Type II method
- Principle
Magnesium is determined directly on diluted wine by atomic absorption spectrophotometry.
- Apparatus
2.1. Atomic absorption spectrophotometer fitted with an air‑acetylene burner.
2.2. Magnesium hollow cathode lamp.
- Reagents
3.1. Concentrated magnesium standard solution containing 1 g/L
Use of a standard commercial magnesium solution (1 g/L) is preferred.
Alternatively, this solution may be prepared by dissolving 8.3646 g of magnesium chloride, Mg
.
, in distilled water and making up to 1 liter.
3.2. Dilute magnesium standard solution, 5 mg/L.
Note: Keep the standard magnesium solutions in polyethylene bottles.
- Procedure
4.1. Preparation of sample
The wine is diluted 1/100 with distilled water.
4.2. Calibration
Place 5, 10, 15 and 20 mL of the dilute standard magnesium solution into each one of a set of four 100 ml. volumetric flasks and make up to 100 mL with distilled water. The standard solutions prepared in this way contain 0.25, 0.50, 0.75 and 1.0 mg of magnesium per liter respectively. These solutions should be kept in polyethylene bottles.
4.3. Determination
Set the absorption wavelength to 285 nm. Zero the absorbance scale using distilled water. Aspirate the diluted wine directly into the spectrophotometer, followed in succession by the standard solutions (4.2).
Record the absorbance of each solution and repeat each measurement.
- Expression of results
5.1. Method of calculation
Plot a graph showing the variation in absorbance as a function of the magnesium concentration in the standard solutions.
Record the mean value of absorbance with the diluted sample of wine on this graph and read off the magnesium concentration C in milligrams per liter. The magnesium concentration in milligrams per liter of the wine to the nearest whole number is given by:
|
|
5.2. Repeatability (r):
-
r = 3 mg/L.
- Reproducibility (R):
- R = 8 mg/L.
Zinc (Type-IV)
OIV-MA-AS322-08 Zinc
Type IV method
- Principle
After removal of alcohol, zinc is determined directly in the wine by atomic absorption spectrophotometry.
- Apparatus
2.1. Rotary evaporator and thermostatically controlled water bath.
2.2. Atomic absorption spectrophotometer equipped with an air‑acetylene burner.
2.3. Zinc hollow cathode lamp.
- Reagents
The water used must be double distilled in borosilicate glass apparatus or of an equivalent degree of purity.
3.1. Standard solution containing zinc, 1 g/L
Use of a commercial standard zinc solution is preferred. Alternatively this solution may be prepared by dissolving 4.3975 g of zinc sulfate, Zn
, in water and making up the volume to one liter.
3.2. Dilute standard solution containing 100 mg of zinc per liter.
- Procedure
4.1. Preparation of sample
Remove the alcohol from 100 mL of wine by reducing the volume of the sample to half its original value using a rotary evaporator (50 to 60 C). Make up to the original volume of 100 ml, with double distilled water.
4.2. Calibration
Place 0.5, 1, 1.5 and 2 ml, of the solution containing 100 mg zinc per liter into each one of four 100 mL volumetric flasks and make up to the mark with double distilled water. The solutions prepared in this way contain 0.5, 1, 1.5 and 2 mg of zinc per liter respectively.
4.3. Determination
Set the absorbance wavelength to 213.9 nm. Zero the absorbance scale using double distilled water. Aspirate the wine directly into the burner of the spectrophotometer, followed in succession by the four standard solutions. Record the absorbance and repeat each measurement.
- Expression of results
5.1. Method of calculation
Plot a graph giving the variation in absorbance as a function of zinc concentration in the standard solutions. Record the mean value of the absorbance obtained with the diluted wine sample on this graph and determine its zinc concentration to one decimal place.
Silver (Type-IV)
OIV-MA-AS322-09 Silver
Type IV method
- Principle
The method is based on the use of atomic absorption spectrophotometry after ashing the sample.
- Apparatus
2.1. Platinum dish.
2.2. Water bath, thermostatically controlled to 100 C
2.3. Furnace set at 500 to 525 C.
2.4. Atomic absorption spectrophotometer.
2.5. Silver hollow cathode lamp.
2.6. Gas supplies: air, acetylene.
- Reagents
3.1. Silver nitrate, AgN03.
3.2. Nitric acid, (ρ20 = 1.38 g/mL), 65%.
3.3. Nitric acid, diluted 1/10 (v/v) with distilled water.
3.4. Solution containing 1 g of silver per L.
Use of a standard commercial silver solution is preferred. Alternatively this solution may be prepared by dissolving 1.575 g of silver nitrate in dilute nitric acid and making up to a volume of 1,000 mL with dilute nitric acid (3.3).Solution containing 10 mg of silver per L.
3.5. Take 10 mL of the 1 mg/L solution and make up to 1 L with dilute nitric acid.
- Procedure
4.1. Preparation of sample
Place 20 mL of the sample in a platinum dish and evaporate to dryness over a boiling water bath. Ash in the furnace at a temperature of 500 to 525 C. Moisten the white ash with 1 mL of concentrated nitric acid (3.2). Evaporate over a boiling water bath, repeat the addition of 1 mL nitric acid (3.2) and evaporate a second time. Add 5 mL of dilute nitric acid (3.3) and heat gently until dissolved.
4.2. Calibration
Pipette 2, 4, 6, 8, 10 and 20 mL of solution (3.5) respectively into each of size 100 mL volumetric flasks and make up to the mark with dilute nitric acid (3.3): the solutions contain 0.20, 0.40, 0.60, 0.80, 1.0 and 2.0 mg of silver per liter respectively.
4.3 Set the absorbance wavelength to 328.1 nm. Adjust zero using double distilled water. Measure the absorbance directly of successive standard solutions (4.2) and carry out in duplicate.
- Expression of results
Plot a graph showing the variation in absorbance as a function of the silver concentration in the standard solutions.
Using the measured absorbance of the sample read the concentration C in mg/L from the calibration curve.
The concentration of silver in the wine is given in milligrams per liter by
|
|
It is quoted to two decimal places.
Note: Select the concentration of the solutions for the preparation of the calibration curve. The volume of sample taken and the final volume of the liquid should be appropriate for the sensitivity of the apparatus to be used.
Cadmium (Type-IV)
OIV-MA-AS322-10 Cadmium
Type IV method
- Principle
Cadmium is determined directly in the wine by graphite furnace atomic absorption spectrophotometry.
- Apparatus
All the glassware must be washed in concentrated nitric acid prior to use, heated to 70 to 80 C and rinsed in double distilled water.
2.1. Atomic absorption spectrophotometer equipped with a graphite furnace, background correction and a recorder.
2.2. Cadmium hollow cathode lamp
2.3. 5 μl micropipettes with special tips for atomic absorption measurement.
- Reagents
The water used must be double distilled prepared using borosilicate glass apparatus, or water of a similar purity. All reagents must be of recognized analytical reagent grade and, in particular, free of cadmium.
3.1. Phosphoric acid (ρ20 = 1.71 g/mL), 85%.
3.2. Phosphoric acid solution obtained by diluting 8 mL of phosphoric acid with water to 100 mL.
3.3. 0.02 M Ethylenediaminetetraacetic acid disodium (EDTA) solution.
3.4. pH 9 buffer solution: dissolve 5.4 g of ammonium chloride in a few milliliters of water in a 100 mL volumetric flask, add 35 mL of 25% (v/v) ammonium hydroxide solution. Ammonium hydroxide solution, ρ20= 0.92 g/mL, diluted to 25% (v/v) and made up to 100 mL with water.
3.5. Eriochrome black T, 1% (m/m) solution in sodium chloride.
3.6. Cadmium sulfate, 3CdSO4.8H20.
The concentration of the cadmium sulfate must be verified using the following method:
Weigh exactly 102.6 mg of the cadmium sulfate sample into a beaker with some water and shake until dissolved; add 5 mL of the pH 9 buffer solution and approximately 20 mg of Eriochrome black T. Titrate with the EDTA solution (3.3) until the indicator begins to turn blue.
The volume of EDTA added must be equal to 20 mL. If the volume is slightly different, correct the weighed test portion of cadmium sulfate used in the preparation of the reference solution accordingly.
3.7. Cadmium reference solution at 1 g per liter.
Use of a standard commercial solution is preferred. Alternatively this solution may be prepared by dissolving 2.2820 g of cadmium sulfate in water and making up to one liter. Keep the solution in a borosilicate glass bottle with a ground glass stopper.
- Procedure
4.1. Preparation of the sample
The wine is diluted 1/2 (v/v) with the phosphoric acid solution (3.2).
4.2. Preparation of calibration standards
Using the cadmium reference solution, prepare successive dilutions 2.5, 5, 10 and 15 μg of cadmium per liter respectively.
4.3. Determination
4.3.1. Furnace Programming (for guidance only):
Dry at 100C for 30 seconds
Mineralize at 900 C for 20 seconds
Atomize at 2250 C for 2 to 3 seconds
Nitrogen flow (flushing gas): 6 liters/minute
Note: At the end of the procedure, increase the temperature to 2700 C to clean the furnace.
4.3.2. Atomic absorption measurements
Select an absorption wavelength of 228.8 nm. Set the zero on the absorbance scale with double distilled water. Using a micropipette, introduce into the furnace three 5 μl portions of each of the solutions in the calibration range and the sample solution to be analyzed. Record the absorbance measured. Calculate the mean absorbance value from the results for the three portions.
-
Expression of results
- Method of calculation
Draw the absorbance variation curve as a function of the concentration of cadmium in the solutions in the calibration range. The curve is linear. Enter the mean absorbance value of the sample solution on the calibration curve and obtain the cadmium concentration C. The cadmium concentration expressed in micrograms per liter of wine is equal to 2C.
Bibliography
- MEDINA B., Application de la spectrométrie d absorption atomique sans flamme au dosage de quelques métaux dans les vins, Thèse Doct. en œnologie, Bordeaux II, 1978.
- MEDINA B. and SUDRAUD P., FV O.I.V 1979, nº 695.
Lead (criteria for methods)
OIV-MA-AS322-12 Analysis of mineral elements in wines using ICP-AES inductively coupled plasma/atomic emission spectrometry)
Type III method
- Warning
Safety precautions - When handling acids, operators should protect their hands and eyes. Acids must be handled under a suitable hood.
- Scope
This method specifies an inductively coupled plasma atomic emission spectroscopy (ICP-AES) method to determine the concentration of the following elements in wines:
-Major mineral elements:
- Potassium (up to 1500 mg/L)
- Calcium (up to 250 mg/L)
- Magnesium (up to 150 mg/L)
- Sodium (up to 100 mg/L)
Minor mineral elements:
- Iron (1 to 10 mg/L)
- Copper (0.1 to 5 mg/L)
- Zinc (0.5 to 5 mg/L)
- Manganese (0.5 to 5 mg/L)
- Strontium (0.1 to 3 mg/L)
- Aluminium (0.75 to 7.5 mg/L)
- Barium (0.1 to 5 mg/L)
- Principle
3.1. Simultaneous analysis of major and minor elements
A 1:5 dilution is used to prepare the samples in this method in order to be able to analyse both the major and minor elements.
The calibration range contains ethanol (2.5%) to take into account the matrix effects related to its presence during nebulisation and at the plasma temperature, along with nitric acid (HNO3 - 1%) which is used to stabilise the solutions.
The lines 
(scandium at 5 mg/L) and 
(caesium as 1% in Cs
) proposed in this method can be used as an internal standard in order to minimise the impact of other non-spectral interferences.
Other internal standards, chosen wisely, may also be used in order to optimise the method, such as 
.
Caesium, in the form of Cs. also serves as an ionic buffer when used as an internal standard. The presence of this buffer therefore sets the ionisation balances of the other components. Caesium chloride, CsCl, can also be used as an ionic buffer.
The internal standards and ionic buffer are prepared in the same flask and then introduced into the sample through the addition of a third channel in the peristaltic pump before entering the nebuliser as a homogenous mixture.
3.2. Analysis of the major elements only
The analysis of the major elements only can also be performed by carrying out a 1:50 dilution of the sample. Nitric acid (H - 1%) is added into the standards and the samples in order to stabilise the solutions.
Given the dilution performed, the matrix effects are considered negligible. The use of internal standards will not be necessary. Likewise, there will be no need to add ethanol to the calibration range.
- Reagents and solutions
Unless otherwise specified, all the reagents used must be of a recognised analytical quality.
4.1. Ultra-pure, demineralised water with a resistivity (greater than 18 MΩ), in accordance with the ISO 3696 standard.
4.2. Certified mono-element solution(s) (to 1000 or 10,000 mg/L) for the mineral elements analysed and the internal standard (scandium for example).
4.3. Internal control: certified reference material (wine) or sample from an intercomparison programme between laboratories, comprising the elements analysed.
4.4. Nitric acid of a concentration greater than 60% (for trace analysis) (CAS No. 7697-37-2).
4.5. Ethanol of a concentration greater than 95% (for trace analysis) (CAS No. 64-17-5).
4.6. A solution of 1% nitric acid
Prepare a 1% nitric acid solution by adding 10 mL of nitric acid (4.4) into a 1000 mL flask.
- Apparatus and equipment
5.1. Optical emission spectrometer with excitation by induced argon plasma and dispersive system (for wavelength analysis, see table in section 7) with axial, radial or dual configuration and preferably sequential PM, CCD, CID or SCCD type detector.
Note 1: Multi-element analysis using a simultaneous type spectrometer is strongly advised if an internal standard is used in the method.
Note 2: Other systems for introducing the sample may be used in order to increase the sensitivity and robustness of the method (continuous flow injection system, microwave desolvation system (MWDS, etc.).
5.2. Calibrated micropipettes making it possible to take volumes from 200 µL to 5 mL and/or class A 1.5 and 10 mL graduated pipettes.
5.3. Class A volumetric flasks
Note 3: The equipment in contact with the sample must remain in the nitric acid solution (4.4) at a concentration of 10% for 12 hours and then be rinsed several times with the demineralised water (4.1).
In order to assess the robustness of the method on the instrument used, it is recommended that the Mg 279.800/Mg 285.213 intensity ratio is calculated; Mg 285.213 being an atomic line and Mg 279.800 being an ionic line.
- Sample preparation
6.1. Preparing the calibration range
The number of calibration solutions depends on the reliability required. At least five calibration solutions are needed. The reliability and accuracy of the results can be verified by analysing a reference material.
The range will be chosen according to the dilution performed. It should cover the scope of the various elements. It is important that the nitric acid concentration is the same in the standards and samples.
6.1.1. Preparing a standard solution for simultaneous analysis of major and minor elements (1:5 dilution):
Using a micropipette (5.2), introduce the desired volume of standard, 2.5 mL of ethanol (4.5) and 1 mL of nitric acid (4.4) into a 100 mL flask (5.3). Make up to 100 mL with demineralised water (4.1) and mix.
6.1.2. Preparing a standard solution for analysing major elements only (1:50 dilution):
Using a micropipette (5.2), introduce the desired volume of standard into a 100 mL flask (5.3), make up to 100 mL with nitric acid solution (4.6) and mix.
6.2. Preparing the test samples
6.2.1. Preparing test samples for simultaneous analysis of major and minor elements (1:5 dilution):
Using a graduated pipette or micropipette (5.2), introduce 10 mL of sample and 1 mL of nitric acid (4.4) into a 50 mL flask (5.3). Make up to 50 mL with demineralised water (4.1) and mix.
Sparkling wine samples must be subjected to degassing using an ultrasound bath for example, for at least 10 minutes.
Particularly for samples rich in sugar, mineralisation by microwave digestion in nitric acid is used to destroy organic compounds. Finally, a higher dilution may need to be considered due to a concentration which is too high for certain elements. In this case, the ethanol content may be adjusted accordingly in the solutions and standards.
Note 4: Depending on the robustness of the instrument used and given the use of the ionic buffer and internal standards, it is possible to work with a 1:2 dilution factor in order to improve the sensitivity of the method for trace elements. As a result, the calibration ranges, ethanol content and possibly the experimental parameters (power) must be modified.
6.2.2. Preparing test samples for analysing major elements only (1:50 dilution)
Using a graduated pipette or micropipette (5.2), introduce 1 mL of wine sample and 0.5 mL of nitric acid (4.4) into a 50 mL flask (5.3). Make up to 100 mL with demineralised water (4.1) and mix.
- Procedure
7.1. Experimental parameters
The optimal instrument parameters that have enabled us to achieve the specificity for this method in terms of repeatability and reproducibility are described below. They are presented here as an example and may be modified depending on the instrument used.
Power: 1.3 kW
Plasma gas flow: 15 L/min
Auxiliary gas flow: 1.5 L/min
Nebuliser pressure: 200 kPa
Stabilisation period: 20 s
Measurement time per replicate: 5 s
Pump speed: 15 rpm
Rinsing time: 30 s
Internal standard inlet internal diameter: 0.51 mm
Sample inlet internal diameter: 0.8 mm
Turn the unit on (pump operational and plasma switched on) and clean the system for at least 20 minutes with 1% nitric acid (4.6).
Analyse a blank following the series of standards in increasing order of concentration. A reference sample (4.3) can be used as internal quality control to verify that the calibration is satisfactory. Next, analyse the blank again to ensure the absence of memory effect. Next, conduct the analysis of the samples by inserting a quality control every 10 samples and at the end of the analysis series.
A control chart can be drawn up from the results obtained in relation to the control sample in order to define the acceptance criteria and actions to be performed in the event of drift.
The analyses will be performed for each element with a minimum of 3 replicates.
Lines that can be used for the various elements (other lines may be used depending on the equipment).
|
Elements |
Main line
( |
Associated internal standard |
Secondary line
( |
Associated internal standard |
|
K |
769.897 (I) (1.6 eV) |
Cs 697.327 |
766.491 (I) (1.6 eV) |
Cs 697.327 |
|
Ca |
317.933 (II) (10 eV) |
Sc 335.372 |
315.887 (II) (10.1 eV) |
Sc 335.372 |
|
Mg |
285.213 (I) (4.3 eV) |
Cs 697.327 |
279.800 (II) (10.6 eV) |
Sc 335.372 |
|
Na |
589.592 (I) (2.1 eV) |
Cs 697.327 |
||
|
Fe |
259.940 (II) (12.7 eV) |
Sc 335.372 |
239.563 (II) (11.4 eV) |
Sc 335.372 |
|
Cu |
327.395 (I) (3.8 eV) |
Cs 697.327 |
324.754 (I) (3.8 eV) |
Cs 697.327 |
|
Zn |
213.857 (I) (5.8 eV) |
Cs 697.327 |
206.200 (II) (12.2 eV) |
Sc 335.372 |
|
Mn |
257.61 (II) (12.3 eV) |
Sc 335.372 |
260.568 (II) (11 eV) |
Sc 335.372 |
|
Sr |
421.552 (II) (8.6 eV) |
Sc 335.372 |
407.771 (II) (8.7 eV) |
Sc 335.372 |
|
Al |
396.152 (I) (3.1 eV) |
Cs 697.327 |
167.019 (I) (7.4 eV) |
Cs 697.327 |
|
Rb |
780.026 (I) (1.6 eV) |
Cs 697.327 |
||
|
Li |
670.783 (I) (1.9 eV) |
Cs 697.327 |
||
|
Ba |
455.403 (II) (7.9 eV) |
Sc 335.372 |
||
|
Sc |
335.372 (II) (10.3 eV) |
|||
|
Cs |
697.327 (I) (1.8 eV) |
)
- Calculation
Calculate the concentration of the elements in the sample using the following equation:
|
|
Where:
C: concentration of the element in the wine sample (mg/L)
Cm: concentration of the element in the diluted solution (mg/L)
Vt: volume of the dilution flask (mL) (here V=50 mL)
Vm: volume of the sample taken for dilution (mL) (here V=1 or 10 mL)
- Precision
|
Elements |
Repeatability |
Reproducibility |
LD (mg/L) |
LQ (mg/L) |
Recovery rate |
|
K |
2.3 |
5.5 |
major |
major |
Between 80% and 120% |
|
Ca |
3.5 |
11.3 |
major |
major |
|
|
Mg |
2.4 |
8.9 |
major |
major |
|
|
Na |
2.6 |
9.1 |
major |
major |
|
|
Fe |
2.2 |
6.9 |
0.08 |
0.25 |
|
|
Cu |
13.4 |
15.8 |
0.03 |
0.10 |
|
|
Zn |
3.6 |
6.5 |
0.03 |
0.10 |
|
|
Mn |
4.7 |
7.0 |
0.03 |
0.10 |
|
|
Al |
5.6 |
17.0 |
0.03 |
0.10 |
|
|
Sr |
2.1 |
9.9 |
0.03 |
0.10 |
|
|
Ba |
8.2 |
20.8 |
0.03 |
0.10 |
APPENDIX:
Validation study – Results of the collaborative trials
A validation study was performed in November 2011 (pre-study) and in February 2012 (validation study) in accordance with ISO 5725 and resolution OENO 6/2000.
Pre-study:
3 samples (dry white wine, red wine and sweet white wine), spiked with Al, Fe,
Cu, Sr, Ba, Mn and Zn.
|
Samples |
|||
|
Element (mg/L) |
Red wine |
Dry white wine |
Sweet wine |
|
K |
1258 |
725 |
841 |
|
Ca |
50 |
75 |
81 |
|
Na |
20 |
28 |
24 |
|
Mg |
78 |
70 |
66 |
|
Al |
1.29 |
1.33 |
1.97 |
|
Fe |
8.12 |
6.91 |
9.29 |
|
Cu |
0.86 |
0.86 |
0.94 |
|
Sr |
1.07 |
1.08 |
1.07 |
|
Ba |
0.77 |
0.72 |
0.63 |
|
Mn |
1.6 |
2.01 |
1.77 |
|
Zn |
1.51 |
2.53 |
1.69 |
Analysis of mineral elements in wines using ICP-AES (inductively coupled plasma / atomic emission spectrometry) (Type-II)
OIV-MA-AS322-13 Analysis of mineral elements in wines using ICP-AES (inductively coupled plasma/atomic emission spectrometry)
Type III method
- Warning
Safety precautions - When handling acids, operators should protect their hands and eyes. Acids must be handled under a suitable hood.
- Scope
This method specifies an inductively coupled plasma atomic emission spectroscopy (ICP-AES) method to determine the concentration of the following elements in wines:
Major mineral elements:
- Potassium (up to 1500 mg/L)
- Calcium (up to 250 mg/L)
- Magnesium (up to 150 mg/L)
- Sodium (up to 100 mg/L)
Minor mineral elements:
- Iron (1 to 10 mg/L)
- Copper (0.1 to 5 mg/L)
- Zinc (0.5 to 5 mg/L)
- Manganese (0.5 to 5 mg/L)
- Strontium (0.1 to 3 mg/L)
- Aluminium (0.75 to 7.5 mg/L)
- Barium (0.1 to 5 mg/L)
- Principle
3.1. Simultaneous analysis of major and minor elements
A 1:5 dilution is used to prepare the samples in this method in order to be able to analyse both the major and minor elements.
The calibration range contains ethanol (2.5%) to take into account the matrix effects related to its presence during nebulisation and at the plasma temperature, along with nitric acid (HN
- 1%) which is used to stabilise the solutions.
The lines (scandium at 5 mg/L) and (caesium as 1% in CsN) proposed in this method can be used as an internal standard in order to minimise the impact of other non-spectral interferences.
Other internal standards, chosen wisely, may also be used in order to optimise the method, such as .
Caesium, in the form of CsN. also serves as an ionic buffer when used as an internal standard. The presence of this buffer therefore sets the ionisation balances of the other components. Caesium chloride, CsCl, can also be used as an ionic buffer.
The internal standards and ionic buffer are prepared in the same flask and then introduced into the sample through the addition of a third channel in the peristaltic pump before entering the nebuliser as a homogenous mixture.
3.2. Analysis of the major elements only
The analysis of the major elements only can also be performed by carrying out a 1:50 dilution of the sample. Nitric acid (HNO3 - 1%) is added into the standards and the samples in order to stabilise the solutions.
Given the dilution performed, the matrix effects are considered negligible. The use of internal standards will not be necessary. Likewise, there will be no need to add ethanol to the calibration range.
- Reagents and solutions
Unless otherwise specified, all the reagents used must be of a recognised analytical quality.
4.1. Ultra-pure, demineralised water with a resistivity (greater than 18 MΩ), in accordance with the ISO 3696 standard.
4.2. Certified mono-element solution(s) (to 1000 or 10,000 mg/L) for the mineral elements analysed and the internal standard (scandium for example).
4.3. Internal control: certified reference material (wine) or sample from an intercomparison programme between laboratories, comprising the elements analysed.
4.4. Nitric acid of a concentration greater than 60% (for trace analysis) (CAS No. 7697-37-2).
4.5. Ethanol of a concentration greater than 95% (for trace analysis) (CAS No. 64-17-5).
4.6. A solution of 1% nitric acid
Prepare a 1% nitric acid solution by adding 10 mL of nitric acid (4.4) into a 1000 mL flask.
- Apparatus and equipment
5.1. Optical emission spectrometer with excitation by induced argon plasma and dispersive system (for wavelength analysis, see table in section 7) with axial, radial or dual configuration and preferably sequential PM, CCD, CID or SCCD type detector.
Note 1: Multi-element analysis using a simultaneous type spectrometer is strongly advised if an internal standard is used in the method.
Note 2: Other systems for introducing the sample may be used in order to increase the sensitivity and robustness of the method (continuous flow injection system, microwave desolvation system (MWDS, etc.).
5.2. Calibrated micropipettes making it possible to take volumes from 200 µL to 5 mL and/or class A 1.5 and 10 mL graduated pipettes.
5.3. Class A volumetric flasks
Note 3: The equipment in contact with the sample must remain in the nitric acid solution (4.4) at a concentration of 10% for 12 hours and then be rinsed several times with the demineralised water (4.1).
In order to assess the robustness of the method on the instrument used, it is recommended that the Mg 279.800/Mg 285.213 intensity ratio is calculated; Mg 285.213 being an atomic line and Mg 279.800 being an ionic line.
- Sample preparation
6.1. Preparing the calibration range
The number of calibration solutions depends on the reliability required. At least five calibration solutions are needed. The reliability and accuracy of the results can be verified by analysing a reference material.
The range will be chosen according to the dilution performed. It should cover the scope of the various elements. It is important that the nitric acid concentration is the same in the standards and samples.
6.1.1. Preparing a standard solution for simultaneous analysis of major and minor elements (1:5 dilution):
Using a micropipette (5.2), introduce the desired volume of standard, 2.5 mL of ethanol (4.5) and 1 mL of nitric acid (4.4) into a 100 mL flask (5.3). Make up to 100 mL with demineralised water (4.1) and mix.
6.1.2. Preparing a standard solution for analysing major elements only (1:50 dilution):
Using a micropipette (5.2), introduce the desired volume of standard into a 100 mL flask (5.3), make up to 100 mL with nitric acid solution (4.6) and mix.
6.2. Preparing the test samples
6.2.1. Preparing test samples for simultaneous analysis of major and minor elements (1:5 dilution):
Using a graduated pipette or micropipette (5.2), introduce 10 mL of sample and 1 mL of nitric acid (4.4) into a 50 mL flask (5.3). Make up to 50 mL with demineralised water (4.1) and mix.
Sparkling wine samples must be subjected to degassing using an ultrasound bath for example, for at least 10 minutes.
Particularly for samples rich in sugar, mineralisation by microwave digestion in nitric acid is used to destroy organic compounds. Finally, a higher dilution may need to be considered due to a concentration which is too high for certain elements. In this case, the ethanol content may be adjusted accordingly in the solutions and standards.
Note 4: Depending on the robustness of the instrument used and given the use of the ionic buffer and internal standards, it is possible to work with a 1:2 dilution factor in order to improve the sensitivity of the method for trace elements. As a result, the calibration ranges, ethanol content and possibly the experimental parameters (power) must be modified.
6.2.2. Preparing test samples for analysing major elements only (1:50 dilution)
Using a graduated pipette or micropipette (5.2), introduce 1 mL of wine sample and 0.5 mL of nitric acid (4.4) into a 50 mL flask (5.3). Make up to 100 mL with demineralised water (4.1) and mix.
- Procedure
Experimental parameters
The optimal instrument parameters that have enabled us to achieve the specificity for this method in terms of repeatability and reproducibility are described below. They are presented here as an example and may be modified depending on the instrument used.
Power: 1.3 kW
Plasma gas flow: 15 L/min
Auxiliary gas flow: 1.5 L/min
Nebuliser pressure: 200 kPa
Stabilisation period: 20 s
Measurement time per replicate: 5 s
Pump speed: 15 rpm
Rinsing time: 30 s
Internal standard inlet internal diameter: 0.51 mm
Sample inlet internal diameter: 0.8 mm
Turn the unit on (pump operational and plasma switched on) and clean the system for at least 20 minutes with 1% nitric acid (4.6).
Analyse a blank following the series of standards in increasing order of concentration. A reference sample (4.3) can be used as internal quality control to verify that the calibration is satisfactory. Next, analyse the blank again to ensure the absence of memory effect. Next, conduct the analysis of the samples by inserting a quality control every 10 samples and at the end of the analysis series.
A control chart can be drawn up from the results obtained in relation to the control sample in order to define the acceptance criteria and actions to be performed in the event of drift.
The analyses will be performed for each element with a minimum of 3 replicates.
Lines that can be used for the various elements (other lines may be used depending on the equipment).
|
Elements |
Main line
( |
Associated internal standard |
Secondary line
( |
Associated internal standard |
|
K |
769.897 (I) (1.6 eV) |
Cs 697.327 |
766.491 (I) (1.6 eV) |
Cs 697.327 |
|
Ca |
317.933 (II) (10 eV) |
Sc 335.372 |
315.887 (II) (10.1 eV) |
Sc 335.372 |
|
Mg |
285.213 (I) (4.3 eV) |
Cs 697.327 |
279.800 (II) (10.6 eV) |
Sc 335.372 |
|
Na |
589.592 (I) (2.1 eV) |
Cs 697.327 |
|
|
|
Fe |
259.940 (II) (12.7 eV) |
Sc 335.372 |
239.563 (II) (11.4 eV) |
Sc 335.372 |
|
Cu |
327.395 (I) (3.8 eV) |
Cs 697.327 |
324.754 (I) (3.8 eV) |
Cs 697.327 |
|
Zn |
213.857 (I) (5.8 eV) |
Cs 697.327 |
206.200 (II) (12.2 eV) |
Sc 335.372 |
|
Mn |
257.61 (II) (12.3 eV) |
Sc 335.372 |
260.568 (II) (11 eV) |
Sc 335.372 |
|
Sr |
421.552 (II) (8.6 eV) |
Sc 335.372 |
407.771 (II) (8.7 eV) |
Sc 335.372 |
|
Al |
396.152 (I) (3.1 eV) |
Cs 697.327 |
167.019 (I) (7.4 eV) |
Cs 697.327 |
|
Rb |
780.026 (I) (1.6 eV) |
Cs 697.327 |
|
|
|
Li |
670.783 (I) (1.9 eV) |
Cs 697.327 |
|
|
|
Ba |
455.403 (II) (7.9 eV) |
Sc 335.372 |
|
|
|
Sc |
335.372 (II) (10.3 eV) |
|
||
|
Cs |
697.327 (I) (1.8 eV) |
|
- Calculation
Calculate the concentration of the elements in the sample using the following equation:
|
|
Where:
C: concentration of the element in the wine sample (mg/L)
Cm: concentration of the element in the diluted solution (mg/L)
Vt: volume of the dilution flask (mL) (here V=50 mL)
Vm: volume of the sample taken for dilution (mL) (here V=1 or 10 mL)
- Precision
|
Elements |
Repeatability |
Reproducibility |
LD (mg/L) |
LQ (mg/L) |
Recovery rate |
|
K |
2.3 |
5.5 |
major |
major |
Between 80% and 120% |
|
Ca |
3.5 |
11.3 |
major |
major |
|
|
Mg |
2.4 |
8.9 |
major |
major |
|
|
Na |
2.6 |
9.1 |
major |
major |
|
|
Fe |
2.2 |
6.9 |
0.08 |
0.25 |
|
|
Cu |
13.4 |
15.8 |
0.03 |
0.10 |
|
|
Zn |
3.6 |
6.5 |
0.03 |
0.10 |
|
|
Mn |
4.7 |
7.0 |
0.03 |
0.10 |
|
|
Al |
5.6 |
17.0 |
0.03 |
0.10 |
|
|
Sr |
2.1 |
9.9 |
0.03 |
0.10 |
|
|
Ba |
8.2 |
20.8 |
0.03 |
0.10 |
Appendix :Validation study – Results of the collaborative trials
A validation study was performed in November 2011 (pre-study) and in February 2012 (validation study) in accordance with ISO 5725 and resolution OENO 6/2000.
Pre-study:
3 samples (dry white wine, red wine and sweet white wine), spiked with Al, Fe,
Cu, Sr, Ba, Mn and Zn.
|
Samples |
|||
|
Element (mg/L) |
Red wine |
Dry white wine |
Sweet wine |
|
K |
1258 |
725 |
841 |
|
Ca |
50 |
75 |
81 |
|
Na |
20 |
28 |
24 |
|
Mg |
78 |
70 |
66 |
|
Al |
1.29 |
1.33 |
1.97 |
|
Fe |
8.12 |
6.91 |
9.29 |
|
Cu |
0.86 |
0.86 |
0.94 |
|
Sr |
1.07 |
1.08 |
1.07 |
|
Ba |
0.77 |
0.72 |
0.63 |
|
Mn |
1.6 |
2.01 |
1.77 |
|
Zn |
1.51 |
2.53 |
1.69 |
SAMPLES
|
White wine 1 |
White wine 2 |
|||||
|
Element |
Ref value (mg/L) |
Spike (mg/L) |
Recovery % |
Ref value (mg/L) |
Spike (mg/L) |
Recovery % |
|
K |
754 |
0 |
98 |
1080 |
351 |
96 |
|
Ca |
83 |
11 |
98 |
76 |
0 |
102 |
|
Na |
50 |
28 |
105 |
24 |
0 |
100 |
|
Mg |
65 |
0 |
98 |
72 |
7 |
102 |
|
Al |
0.50 |
0 |
100 |
1.19 |
1 |
104 |
|
Fe |
2.86 |
1 |
94 |
1.71 |
0 |
97 |
|
Cu |
0.04 |
0 |
no add. |
0.71 |
1 |
103 |
|
Sr |
1.27 |
1 |
105 |
0.22 |
0 |
108 |
|
Ba |
0.08 |
0 |
102 |
0.64 |
1 |
96 |
|
Mn |
1.84 |
1 |
98 |
1.12 |
0 |
102 |
|
Zn |
1.40 |
0 |
100 |
2.12 |
1 |
102 |
|
Red wine 1 |
Red wine 2 |
|||||
|
Element |
Ref value (mg/L) |
Spike (mg/L) |
Recovery % |
Ref value (mg/L) |
Spike (mg/L) |
Recovery % |
|
K |
1160 |
70 |
100 |
1371 |
316 |
95 |
|
Ca |
62 |
1 |
103 |
67 |
7 |
101 |
|
Na |
71 |
56 |
100 |
19 |
0 |
100 |
|
Mg |
82 |
7 |
102 |
80 |
0 |
99 |
|
Al |
0.81 |
0 |
105 |
1.82 |
1 |
103 |
|
Fe |
4.90 |
0 |
101 |
4.55 |
0 |
101 |
|
Cu |
0.46 |
0 |
102 |
0.12 |
0 |
65 |
|
Sr |
0.28 |
0 |
102 |
1.32 |
1 |
105 |
|
Ba |
0.12 |
0 |
102 |
0.62 |
1 |
97 |
|
Mn |
1.81 |
1 |
100 |
1.10 |
0 |
101 |
|
Zn |
0.95 |
0 |
107 |
1.68 |
1 |
101 |
|
Sweet wine 1 |
Sweet wine 2 |
|||||
|
Element |
Ref value (mg/L) |
Spike (mg/L) |
Recovery % |
Ref value (mg/L) |
Spike (mg/L) |
Recovery % |
|
K |
1105 |
246 |
96 |
832 |
0 |
102 |
|
Ca |
85 |
4 |
99 |
92 |
10 |
101 |
|
Na |
68 |
42 |
98 |
21 |
0 |
100 |
|
Mg |
63 |
0 |
97 |
66 |
6 |
101 |
|
Al |
1.65 |
1 |
101 |
0.80 |
0 |
96 |
|
Fe |
3.03 |
0 |
97 |
4.63 |
0 |
101 |
|
Cu |
0.73 |
1 |
101 |
0.12 |
0 |
94 |
|
Sr |
1.73 |
1 |
106 |
0.22 |
0 |
96 |
|
Ba |
0.11 |
0 |
94 |
0.34 |
0 |
90 |
|
Mn |
1.01 |
0 |
99 |
1.62 |
1 |
102 |
|
Zn |
1.53 |
1 |
102 |
1.18 |
0 |
100 |
Participant laboratories had the choice to carry out the analysis of elements
- either in two steps: high dilution for major elements and low dilution for minor elements, preferably with internal standards.
- or in one step: the same dilution for all elements with internal standards.
For each sample number and for each determination, the first individual value was used. The two individual portions of blind identical replicas per laboratory are considered as a single material.
Outlier elimination was performed using a sequential application of the Cochran (applied to variances) and Grubbs (applied to mean values) tests (at a 2.5% probability (P) level, 1-tail for Cochran and 2-tail for Grubbs) until no further outliers were flagged or until a drop of 22.2% in the original number of laboratories providing valid data occurred.
With the exception of the element calcium in the "sweet wine 2" sample, which exhibits a Horrat R value of 2.2, all the elements were compliant. For this sample, 93% of the laboratories have a satisfactory Z-score (14 results) and 7% of the laboratories have a questionable Z-score (1 result). Consequently, as the five other samples were compliant for the determination of calcium, including another sweet wine sample with the same calcium concentration, it was decided to validate this element and to include it in the analytical method.
For the determination of major elements, 9 laboratories used a high dilution and 6 laboratories used a single dilution for all (major and minor) elements. There were no differences between the results of both groups.
Tableau 1 - Potassium
|
Statistical parametres |
White Wine 1 |
White Wine 2 |
Red wine 1 |
Red wine 2 |
Sweet wine 1 |
Sweet wine 1 |
|
Total |
15,00 |
15,00 |
15,00 |
15,00 |
15,00 |
15,00 |
|
Accepted |
13,00 |
13,00 |
14,00 |
11,00 |
14,00 |
14,00 |
|
Repetitions |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
|
Vréf (mg/L) |
754,38 |
1079,82 |
1160,33 |
1370,96 |
1105,46 |
831,62 |
|
Limit of repeatability - r |
22,45 |
47,32 |
132,68 |
50,64 |
124,78 |
42,92 |
|
RSD r (%) |
1,10 |
1,50 |
4,00 |
1,30 |
4,00 |
1,80 |
|
RSD r Horwitz |
3,90 |
3,69 |
3,65 |
3,56 |
3,68 |
3,84 |
|
r Horrat |
0,30 |
0,40 |
1,10 |
0,40 |
1,10 |
0,50 |
|
Limite de reproductibility - R |
139,25 |
182,82 |
165,46 |
147,56 |
176,10 |
142,93 |
|
RSD R (%) |
6,50 |
6,00 |
5,00 |
3,80 |
5,60 |
6,10 |
|
RSD R Horwitz |
5,90 |
5,59 |
5,53 |
5,39 |
5,57 |
5,82 |
|
R Horrat |
1,10 |
1,10 |
0,90 |
0,70 |
1,00 |
1,00 |
Tableau 2 - Calcium
|
Statistical parametres |
White Wine 1 |
White Wine 2 |
Red wine 1 |
Red wine 2 |
Sweet wine 1 |
Sweet wine 1 |
|
Total |
15,00 |
15,00 |
15,00 |
15,00 |
15,00 |
15,00 |
|
Accepted |
10,00 |
10,00 |
13,00 |
10,00 |
13,00 |
15,00 |
|
Repetitions |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
|
Vréf (mg/L) |
85,37 |
73,43 |
67,68 |
66,00 |
78,35 |
92,39 |
|
Limit of repeatability - r |
3,30 |
4,12 |
4,60 |
2,86 |
7,96 |
26,66 |
|
RSD r (%) |
2,10 |
2,00 |
2,40 |
1,50 |
3,60 |
10,20 |
|
RSD r Horwitz |
5,85 |
5,53 |
5,60 |
5,62 |
5,48 |
5,34 |
|
r Horrat |
0,30 |
0,40 |
0,40 |
0,30 |
0,70 |
1,90 |
|
Limite de reproductibility - R |
10,68 |
10,45 |
42,58 |
9,51 |
29,85 |
45,60 |
|
RSD R (%) |
4,40 |
5,00 |
22,20 |
5,10 |
13,50 |
17,40 |
|
RSD R Horwitz |
8,19 |
8,38 |
8,48 |
8,52 |
8,30 |
8,10 |
|
R Horrat |
0,50 |
0,60 |
2,60 |
0,60 |
0,60 |
2,20 |
Tableau 3 - Sodium
|
Statistical parametres |
White Wine 1 |
White Wine 2 |
Red wine 1 |
Red wine 2 |
Sweet wine 1 |
Sweet wine 1 |
|
|
Total |
15,00 |
15,00 |
15,00 |
15,00 |
15,00 |
15,00 |
|
|
Accepted |
15,00 |
13,00 |
12,00 |
12,00 |
14,00 |
15,00 |
|
|
Repetitions |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
|
|
Vréf (mg/L) |
50,50 |
24,09 |
71,43 |
18,76 |
67,91 |
21,42 |
|
|
Limit of repeatability - r |
3,00 |
1,32 |
2,53 |
1,73 |
5,20 |
1,85 |
|
|
RSD r (%) |
2,10 |
1,90 |
1,20 |
3,30 |
2,70 |
3,00 |
|
|
RSD r Horwitz |
5,85 |
6,54 |
5,55 |
6,79 |
5,60 |
6,6 |
|
|
r Horrat |
0,30 |
0,30 |
0,20 |
0,50 |
0,50 |
0,50 |
|
|
Limite de reproductibility - R |
9,41 |
6,09 |
15,19 |
6,72 |
13,09 |
6,49 |
|
|
RSD R (%) |
6,60 |
9,90 |
7,50 |
12,70 |
6,80 |
10,70 |
|
|
RSD R Horwitz |
8,87 |
9,91 |
8,42 |
10,29 |
8,48 |
10,09 |
|
|
R Horrat |
0,70 |
0,90 |
0,90 |
1,20 |
0,80 |
1,10 |
|
Tableau 4 - Magnésium
|
Statistical parametres |
White Wine 1 |
White Wine 2 |
Red wine 1 |
Red wine 2 |
Sweet wine 1 |
Sweet wine 1 |
|
Total |
15,00 |
15,00 |
15,00 |
15,00 |
15,00 |
15,00 |
|
Accepted |
15,00 |
15,00 |
14,00 |
14,00 |
13,00 |
14,00 |
|
Repetitions |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
|
Vréf (mg/L) |
65,30 |
72,0 |
82,15 |
80,01 |
62,63 |
65,53 |
|
Limit of repeatability - r |
3,43 |
4,29 |
10,27 |
7,25 |
5,32 |
2,27 |
|
RSD r (%) |
1,90 |
2,10 |
4,40 |
3,20 |
3,00 |
1,20 |
|
RSD r Horwitz |
5,63 |
5,55 |
5,44 |
5,46 |
5,67 |
5,63 |
|
r Horrat |
0,30 |
0,40 |
0,80 |
0,60 |
0,50 |
0,20 |
|
Limite de reproductibility - R |
15,26 |
16,33 |
29,80 |
20,23 |
15,86 |
13,74 |
|
RSD R (%) |
8,30 |
8,00 |
12,80 |
8,90 |
8,90 |
7,40 |
|
RSD R Horwitz |
8,53 |
8,40 |
8,24 |
8,2 |
8,58 |
8,53 |
|
R Horrat |
1,00 |
1,00 |
1,60 |
1,10 |
1,00 |
0,90 |
Tableau 5 - Aluminium
|
Statistical parametres |
White Wine 1 |
White Wine 2 |
Red wine 1 |
Red wine 2 |
Sweet wine 1 |
Sweet wine 1 |
|
Total |
15,00 |
15,00 |
15,00 |
15,00 |
15,00 |
15,00 |
|
Accepted |
10,00 |
9,00 |
8,00 |
8,00 |
9,00 |
8,00 |
|
Repetitions |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
|
Vréf (mg/L) |
0,50 |
1,19 |
0,81 |
1,82 |
1,65 |
0,80 |
|
Limit of repeatability - r |
0,19 |
0,11 |
0,22 |
0,15 |
0,15 |
0,05 |
|
RSD r (%) |
13,10 |
3,30 |
9,40 |
2,80 |
3,20 |
2,10 |
|
RSD r Horwitz |
11,71 |
10,29 |
10,89 |
9,65 |
9,79 |
10,93 |
|
r Horrat |
1,10 |
0,30 |
0,90 |
0,30 |
0,30 |
0,20 |
|
Limite de reproductibility - R |
0,42 |
0,33 |
0,33 |
0,46 |
0,97 |
0,41 |
|
RSD R (%) |
29,80 |
10,00 |
14,20 |
8,90 |
20,80 |
18,10 |
|
RSD R Horwitz |
17,75 |
15,59 |
16,50 |
14,61 |
14,84 |
16,56 |
|
R Horrat |
1,70 |
0,60 |
0,90 |
0,60 |
1,40 |
1,10 |
Tableau 6 - Fer
|
Statistical parametres |
White Wine 1 |
White Wine 2 |
Red wine 1 |
Red wine 2 |
Sweet wine 1 |
Sweet wine 1 |
|
Total |
10,00 |
10,00 |
10,00 |
10,00 |
10,00 |
10,00 |
|
Accepted |
6,00 |
7,00 |
7,00 |
6,00 |
7,00 |
7,00 |
|
Repetitions |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
|
Vréf (mg/L) |
2,86 |
1,71 |
4,90 |
4,55 |
3,03 |
4,63 |
|
Limit of repeatability - r |
0,19 |
0,06 |
0,57 |
0,33 |
0,21 |
0,70 |
|
Limit of repeatability - r |
0,19 |
0,06 |
0,57 |
0,33 |
0,21 |
0,70 |
|
RSD r (%) |
2,30 |
1,30 |
4,10 |
2,60 |
2,40 |
0,50 |
|
RSD r Horwitz |
9,02 |
9,74 |
8,31 |
8,41 |
8,94 |
8,38 |
|
r Horrat |
0,30 |
0,10 |
0,50 |
0,30 |
0,30 |
0,10 |
|
Limite de reproductibility - R |
0,20 |
0,29 |
0,99 |
0,34 |
0,34 |
2,52 |
|
RSD R (%) |
2,50 |
6,10 |
7,10 |
2,60 |
3,90 |
19,20 |
|
RSD R Horwitz |
13,66 |
14,76 |
12,59 |
12,74 |
13,54 |
12,70 |
|
R Horrat |
0,20 |
0,40 |
0,60 |
0,20 |
0,30 |
1,50 |
Tableau 7 - Cuivre
|
Statistical parametres |
White Wine 1 |
White Wine 2 |
Red wine 1 |
Red wine 2 |
Sweet wine 1 |
Sweet wine 1 |
|
|
Total |
9,00 |
10,00 |
10,00 |
10,00 |
10,00 |
10,00 |
|
|
Accepted |
7,00 |
10,00 |
8,00 |
10,00 |
8,00 |
10,00 |
|
|
Repetitions |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
|
|
Vréf (mg/L) |
0,04 |
0,71 |
0,46 |
0,12 |
0,73 |
0,12 |
|
|
Limit of repeatability - r |
0,03 |
0,10 |
0,08 |
0,05 |
0,03 |
0,10 |
|
|
RSD r (%) |
24,30 |
4,80 |
6,00 |
14,40 |
1,70 |
29,00 |
|
|
RSD r Horwitz |
16,95 |
11,12 |
11,87 |
14,62 |
11,07 |
14,55 |
|
|
r Horrat |
1,40 |
0,40 |
0,50 |
1,00 |
0,20 |
2,00 |
|
|
Limite de reproductibility - R |
0,03 |
0,21 |
0,09 |
0,05 |
0,14 |
0,10 |
|
|
RSD R (%) |
24,30 |
10,40 |
6,80 |
16,40 |
6,80 |
30,10 |
|
|
RSD R Horwitz |
25,68 |
16,84 |
17,98 |
22,15 |
16,77 |
22,05 |
|
|
R Horrat |
0,90 |
0,60 |
0,40 |
0,70 |
0,40 |
1,40 |
|
Tableau 8 – Strontium
|
Statistical parametres |
White Wine 1 |
White Wine 2 |
Red wine 1 |
Red wine 2 |
Sweet wine 1 |
Sweet wine 1 |
|
Total |
8,00 |
8,00 |
8,00 |
8,00 |
8,00 |
8,00 |
|
Accepted |
7,00 |
7,00 |
7,00 |
6,00 |
7,00 |
6,00 |
|
Repetitions |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
|
Vréf (mg/L) |
1,27 |
0,22 |
0,28 |
1,32 |
1,73 |
0,22 |
|
Limit of repeatability - r |
0,03 |
0,01 |
0,04 |
0,06 |
0,12 |
0,00 |
|
RSD r (%) |
1,00 |
1,70 |
5,50 |
1,70 |
2,60 |
0,50 |
|
RSD r Horwitz |
10,19 |
13,25 |
12,76 |
10,13 |
9,72 |
13,30 |
|
r Horrat |
0,01 |
0,10 |
0,40 |
0,20 |
0,30 |
0,00 |
|
Limite de reproductibility - R |
0,18 |
0,07 |
0,12 |
0,09 |
0,24 |
0,12 |
|
RSD R (%) |
5,10 |
11,40 |
15,30 |
2,50 |
5,00 |
20,00 |
|
RSD R Horwitz |
15,44 |
20,08 |
19,34 |
15,34 |
14,73 |
22,15 |
|
R Horrat |
0,30 |
0,60 |
0,80 |
0,20 |
0,30 |
1,00 |
Tableau 9 - Barium
|
Statistical parametres |
White Wine 1 |
White Wine 2 |
Red wine 1 |
Red wine 2 |
Sweet wine 1 |
Sweet wine 1 |
|
|
Total |
8,00 |
8,00 |
8,00 |
8,00 |
8,00 |
8,00 |
|
|
Accepted |
7,00 |
8,00 |
8,00 |
7,00 |
8,00 |
8,00 |
|
|
Repetitions |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
|
|
Vréf (mg/L) |
0,08 |
0,64 |
0,12 |
0,62 |
0,11 |
0,34 |
|
|
Limit of repeatability - r |
0,01 |
0,38 |
0,01 |
0,16 |
0,01 |
0,06 |
|
|
RSD r (%) |
5,70 |
21,00 |
3,60 |
9,20 |
3,30 |
6,30 |
|
|
RSD r Horwitz |
15,33 |
11,30 |
14,52 |
11,34 |
14,73 |
12,41 |
|
|
r Horrat |
0,40 |
1,90 |
0,20 |
0,80 |
0,20 |
0,50 |
|
|
Limite de reproductibility - R |
0,04 |
0,38 |
0,05 |
0,54 |
0,05 |
0,24 |
|
|
RSD R (%) |
18,80 |
21,00 |
13,90 |
30,07 |
15,80 |
24,50 |
|
|
RSD R Horwitz |
23,23 |
17,12 |
22,00 |
17,18 |
22,32 |
18,80 |
|
|
R Horrat |
0,80 |
1,20 |
0,60 |
1,80 |
0,70 |
1,30 |
|
Tableau 10 - Manganèse
|
Statistical parametres |
White Wine 1 |
White Wine 2 |
Red wine 1 |
Red wine 2 |
Sweet wine 1 |
Sweet wine 1 |
|
Total |
10,00 |
10,00 |
10,00 |
10,00 |
10,00 |
10,00 |
|
Accepted |
9,00 |
10,00 |
9,00 |
10,00 |
8,00 |
8,00 |
|
Repetitions |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
|
Vréf (mg/L) |
1,84 |
1,12 |
1,81 |
1,10 |
0,11 |
1,62 |
|
Limit of repeatability - r |
0,09 |
0,21 |
0,49 |
0,14 |
0,13 |
0,60 |
|
RSD r (%) |
1,60 |
6,50 |
9,60 |
4,50 |
4,60 |
1,30 |
|
RSD r Horwitz |
9,64 |
10,38 |
9,66 |
10,41 |
10,55 |
9,82 |
|
r Horrat |
0,20 |
0,60 |
1,00 |
0,40 |
0,40 |
0,10 |
|
Limite de reproductibility - R |
0,25 |
0,21 |
0,49 |
0,22 |
0,22 |
0,38 |
|
RSD R (%) |
4,80 |
6,50 |
9,60 |
7,10 |
7,10 |
8,30 |
|
RSD R Horwitz |
14,60 |
15,73 |
14,63 |
15,78 |
15,98 |
14,88 |
|
R Horrat |
0,30 |
0,40 |
0,70 |
0,50 |
0,30 |
0,60 |
Tableau 11 - Zinc
|
Statistical parametres |
White Wine 1 |
White Wine 2 |
Red wine 1 |
Red wine 2 |
Sweet wine 1 |
Sweet wine 1 |
|
|
Total |
10,00 |
10,00 |
10,00 |
10,00 |
10,00 |
10,00 |
|
|
Accepted |
7,00 |
8,00 |
9,00 |
8,00 |
7,00 |
7,00 |
|
|
Repetitions |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
2,00 |
|
|
Vréf (mg/L) |
1,40 |
2,12 |
0,95 |
1,68 |
1,53 |
1,18 |
|
|
Limit of repeatability - r |
0,09 |
0,16 |
0,22 |
0,10 |
0,18 |
0,05 |
|
|
RSD r (%) |
2,40 |
2,60 |
8,40 |
2,20 |
4,20 |
1,60 |
|
|
RSD r Horwitz |
10,03 |
9,43 |
10,65 |
9,77 |
9,91 |
10,30 |
|
|
r Horrat |
0,20 |
0,30 |
0,80 |
0,20 |
0,40 |
0,20 |
|
|
Limite de reproductibility - R |
0,10 |
0,39 |
0,29 |
0,36 |
0,22 |
0,22 |
|
|
RSD R (%) |
2,40 |
6,50 |
10,70 |
7,60 |
5,10 |
6,70 |
|
|
RSD R Horwitz |
15,20 |
14,28 |
16,13 |
14,80 |
15,01 |
15,61 |
|
|
R Horrat |
0,20 |
0,50 |
0,70 |
0,50 |
0,30 |
0,40 |
|
2/ Laboratoires participants :
- State General Laboratory, NMR Lab, Nicosia Chypre
- ANALAB CHILE S.A., Santiago Chile
- CISTA, National Reference Laboratoty Brno Czech Republic
- Laboratório de Análises- REQUIMTE- FCT/UNL, Caparica Portugal
- Laboratório Central de Análises - Universidade de Aveiro Portugal
- Laboratory of National Center of Alcoholic Beverages Testing, Chisinau Republic of Moldova
- National Research Institute of Brewing, Higashihiroshima Japon
- Instituto Nacional de Vitivinicultura, Laboratorio General, Mendoza Argentine
- LFZ Wein und Obstbau, Klosterneuburg Autriche
- Laboratorio Arbitral Agroalimentario, Madrid Spain
- Laboratoire SCL de Bordeaux-Pessac France