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Fertilizers, soil conditioners and beneficial substances — Determination of ammonium citrate, disodium-EDTA soluble phosphorus and potassium by ICP-OES in inorganic fertilizers

Fertilizers, soil conditioners and beneficial substances — Determination of ammonium citrate, disodium-EDTA soluble phosphorus and potassium by ICP-OES in inorganic fertilizers

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Status
Published
ICS
65.080 - Fertilizers
Technical Committee
ISO/TC 134 - Fertilizers, soil conditioners and beneficial substances
Drafting Committee
ISO/TC 134 - Fertilizers, soil conditioners and beneficial substances
Current Stage
5020 - FDIS ballot initiated: 2 months. Proof sent to secretariat
Start Date
03-Feb-2023
Completion Date
03-Feb-2023
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Standards Content (Sample)

ISO/TC 134
Date: 2021-10-20
ISO TSDTS 20917.3:2022(E)
ISO/TC 134/WG 1
Secretariat: INSO

Fertilizers, soil conditioners and beneficial substances -— Determination of ammonium

citrate, disodium-EDTA soluble phosphorus and potassium by ICP-OES in inorganic
fertilizers
First edition
Date: 2022-01-20
---------------------- Page: 1 ----------------------
© ISO 2022

All rights reserved. Unless otherwise specified, or required in the context of its

implementation, no part of this publication may be reproduced or utilized otherwise in

any form or by any means, electronic or mechanical, including photocopying, or posting

on the internet or an intranet, without prior written permission. Permission can be

requested from either ISO at the address below or ISO’s member body in the country of

the requester.
ISO copyright office
CP 401 • Ch. de Blandonnet 8
CH-1214 Vernier, Geneva
Phone: +41 22 749 01 11
Email: copyright@iso.org
Website: www.iso.org
Technical Specification
---------------------- Page: 2 ----------------------
Published in Switzerland
ii © ISO 2022 – All rights reserved
---------------------- Page: 3 ----------------------
Contents

Forward .................................................................................................................... iii

Introduction ............................................................................................................. iv

1 Scope …..............................................................................................................1

2 Normative eferences ….....................................................................................1

3 Terms and definitions …………………………………………...……...................2

4 Principle .............................................................................................................2

5 Reagents ……………….......................................................................................2

6 Apparatus .......................................................................................................... 4

7 Sampling nd Preparation .................................................................................4

8 Procedure .......................................................................................................... 5

8.1 Extraction of P and K …………………………………………………………......5
8.2 Instrument Conditions ………………………………………………………….…5

8.3 Preparation of Standards ...............................................................................6

8.3.1 Standards from reagent salts ............................................................6

8.3.2 Standards from commercial stock solutions ......................................6

8.3.3 Calibration and wavelength splitting ..................................................7

8.3.4 Analysis ............................................................................................ 8

8.4 Reference Material ........................................................................................ 8

8.5 Duplicates ......................................................................................................8

9 Calculation and expression of results ........................................................... 8

9.1 Calculations ...................................................................................................8

9.2 Precision ........................................................................................................9

9.2.1 Repeatability, r ..................................................................................9

9.2.2 Reproducibility, R ..............................................................................9

10 Special ...............................................................................................................11

11 Test Report …………………………………………………………………………...11

Annex A (informative) Ring test results .................................................................12

Annex B (informative) Critical factors ................................................................... 25

Bibliography ………………………………………………………………….……….….27
iii
---------------------- Page: 4 ----------------------
Foreword

ISO (the International Organization for Standardization) is a worldwide federation of national

standards bodies (ISO member bodies). The work of preparing International Standards is

normally carried out through ISO technical committees. Each member body interested in a

subject for which a technical committee has been established has the right to be represented on

that committee. International organizations, governmental and non-governmental, in liaison

with ISO, also take part in the work. ISO collaborates closely with the International

Electrotechnical Commission (IEC) on all matters of electrotechnical standardization.

The procedures used to develop this proposed technical specificationdocument and those

intended for its further maintenance are described in the ISO/IEC Directives, Part 1. In

particular, the different approval criteria needed for the different types of ISO documents

should be noted. This proposed technical specificationdocument was drafted in accordance with

the editorial rules of the ISO/IEC Directives, Part 2 (see www.iso.org/directives).

Attention is drawn to the possibility that some of the elements of this proposed technical

specificationdocument may be the subject of patent rights. ISO shall not be held responsible for

identifying any or all such patent rights. Details of any patent rights identified during the

development of the document will be in the Introduction and/or on the ISO list of patent

declarations received (see www.iso.org/patents).

Any trade name used in this proposed technical specificationdocument is information given for

the convenience of users and does not constitute an endorsement.

For an explanation onof the voluntary nature of standards, the meaning of ISO specific terms

and expressions related to conformity assessment, as well as information about ISO's adherence

to the World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT)),

see www.iso.org/iso/foreword.htmlthe following URL: .

This proposed technical specificationdocument was prepared by Technical Committee ISO/TC

134, Fertilizers, soil conditioners and beneficial substances.

Any feedback or questions on this document should be directed to the user’s national standards

body. A complete listing of these bodies can be found at www.iso.org/members.html.

iv © ISO 2022 – All rights reserved
---------------------- Page: 5 ----------------------
Introduction

Inductively coupled plasma – -optical emission spectrometer (ICP-OES) instrumentation is

becoming increasingly popular in fertilizer testing laboratories (1,4,5). see References [1], [2]

and [3]). Because these instruments are automated and can determine multiple elements

simultaneously, they offer significant productivity gains. Also, the method does not generate

hazardous wastes. The ammonium citrate disodium etheylenediamine tetraacetic acid (EDTA)

organic solvent and samples containing high phosphorus and/or potassium concentrations

pose some analytical challenges for the instrumentation, which must be addressed. Due to the

increasing use of this technology, a Technical Specificationthis document was created at this time

with the goal of generating a Final Draft International Standard.
---------------------- Page: 6 ----------------------
ISO/DTS 20917:2022(E)
Fertilizers, soil conditioners and beneficial substances – Determination of
Ammonium Citrate, Disodium-EDTA Soluble Phosphorus and Potassium
by ICP-OES in Inorganic Fertilizers
1 Scope

This Technical Specification specifies an ICP-OES method for the determination of the ammonium

citrate, disodium-EDTA soluble phosphorus and potassium content in fertilizer extract solutions. This

specification is suitable for all inorganic fertilizer products, whether compound or complex fertilizer

products or blends thereof, and straight concentrated fertilizer products. For organic fertilizers and

for liquid fertilizers containing phosphorous acid (H PO or phosphite), an alternative method

3 3

that specifically measures PO is preferred since the ICP-OES measures all elemental

phosphorus, which can result in a high bias for these types of fertilizer materials (1). see

Reference [1]).

Due to the inability of the ICP-OES to differentiate between phosphorus species, under normal

operating conditions, this methmethod is primarily intended for fertilizer materials in which the

source(s) of phosphorus is known. While the trueness of this technical specification is

gooddocument can be used with minimal bias, the repeatability and reproducibility is not

consistent with other standards routinely used for governative inspection at this time, such as

[4] [5] [6]
EN15959, EN15477EN 15959 , EN 15477 or ISO 22018. .

As a result, this technical specificationdocument is intended for screening purposes, where a

large number of fertilizer phosphorus and potassium results must be obtained as efficiently as

possible. Where governative inspection is critical, such as where fertilizer tolerances or desired

statistical certainty criteria have been exceeded by this technical specification, then standards

such as EN15959, EN15477 or ISO 22018 can be used for confirmation.
---------------------- Page: 7 ----------------------
ISO/DTS 20917:2022(E)
Fertilizers, soil conditioners and beneficial substances
— Determination of ammonium citrate, disodium-
EDTA soluble phosphorus and potassium by ICP-OES
in inorganic fertilizers
1 Scope

This document specifies an inductively coupled plasma-optical emission spectrometer (ICP-

OES) method for the determination of the ammonium citrate, disodium-etheylenediamine

tetraacetic acid (EDTA) soluble phosphorus and potassium content in fertilizer extract

solutions.

This document is applicable to all inorganic fertilizer products, whether compound or complex

fertilizer products or blends thereof, and straight concentrated fertilizer products.

12 Normative references

The following documents are referred to in the text in such a way that some or all of their

content constitutes requirements of this proposed technical specification. document. For dated

references, only the edition cited applies. For undated references, the latest edition of the

referenced document (including any amendments) applies.

EN 15959:2011ISO 8157, Fertilizers – Determination of extracted phosphorus., soil conditioners and

beneficial substances — Vocabulary

EN 15477:2009, Fertilizers – Determination of the water-soluble potassium content.

ISO 14820--1 2016, Fertilizers and liming materials –— Sampling and sample preparation –—

Part 1: Sampling

ISO 14820--2 2016, Fertilizers and liming materials –— Sampling and sample preparation –—

Part 2: Sample preparation

ISO 22018:2021 Fertilizers, soil conditioners and beneficial substances – Determination of

EDTA soluble phosphorus content in inorganic fertilizers.

ISO 13528:2015, Statistical methods for use in proficiency testing by interlaboratory comparison.

43 Terms and definitions

For the purposes of this technical specificationdocument, the terms and definitions given in ISO

8157 apply.

ISO and IEC maintain terminologicalterminology databases for use in standardization at the

following addresses:
© ISO 2022 – All rights reserved 1
---------------------- Page: 8 ----------------------
ISO/DTS 20917:2022(E)
IEC Electropedia: available at — ISO Online browsing platform: available at
https://www.iso.org/obp
— IEC Electropedia: available at https://www.electropedia.org/
54 Principle

Phosphorus and potassium contained in inorganic fertilizers that is soluble in a heated, dilute

ammonium citrate and disodium-EDTA solvent is determined. The neutral ammonium citrate is

the primary solvent for phosphate, while the EDTA is mainly included to chelate calcium,

magnesium and other soluble metallic cations to minimize their interaction with phosphate and

eliminate the water-wash step (6). see Reference [7]). Also, since this solvent is a relatively

weak solution, it extracts primarily the highly soluble potassium compounds and has been used

for fertilizer potassium determination since 1993. It compares very favorablyfavourably with

other soluble potash solvents such as ammonium oxalate. The user of this technical

standarddocument is not obligated to determine both phosphorus and potassium; however, one

of the main advantages of this approach is to measure both simultaneously in a single extract in

a more productive, cost-effective way.

The resulting extract solution is tested by ICP-OES to quantify the levels of phosphorus and

potassium, which can be converted to their equivalent P O and K O concentrations. The

2 5 2

extract solution is nebulized to produce a fine aerosol, which is introduced to a plasma or high

energy source to ionize or excite electrons to higher energy orbitals. As these electrons return

to ground state, they emit characteristic ultraviolet or visible wavelengths that are unique to

each element. The intensity of the wavelength emission is proportionate to the concentration,

which can be quantified by various detector types including a photomultiplier tube (PT), a

charge injection device (CID) or a charge coupled device (CCD).
65 Reagents

5.1 Ammonium citrate, dibasic, (NH ) HC H O , Formula Weight (FW) with a molecular

4 2 6 5 7
weight (MW) of 226,19, and a purity >greater than 98 % or 980,0 g/kg.

5.2 EDTA, disodium salt, dehydrate, C H N Na O ·2H O, FWwith a MW of 372,24, and a

10 14 2 2 8 2
purity >greater than 98 % or 980,0 g/kg.

5.3 Ammonium hydroxide, NH OH; FW , with a MW of 35,05; and a purity =equal to 28,0-

30,0 % as NH or ρ = = 0,91 g/ml.
5.4 Nitric acid, HNO , 67-70%, %, with a ρ = 1,40 g/ml.

5.5 Potassium dihydrogen phosphate, KH PO , FWwith a MW of 136.,09, certified at 26,93%

2 4

P or 269,3 with a purity greater than 99 % or 990,0 g/kg ; National Institute of Standards and

Technology (NIST) SRM 194a (Gaithersburg, MD), or comparable.

5.6 Potassium chloride, KCl, FWwith a MW of 74,55; and a purity >greater than 99 % or

990 g/kg.

1 SRM 194a is the trade name of a product supplied by National Institute of Standards and Technology (NIST). This information is given for the convenience of

users of this document and does not constitute an endorsement by ISO of the product named. Equivalent products may be used if they can be shown to lead to the

same results.
2 © ISO 2022 – All rights reserved
---------------------- Page: 9 ----------------------
ISO/DTS 20917:2022(E)

5.7 Potassium nitrate, KNO , FWwith a MW of 101.,10; NIST SRM193 with a purity greater

than 99 % or comparable, certified at 38,66% K or 386,6 990,0 g/kg .
Triton X-100, 5.8 Octyl phenol ethoxylate .

5.9 Beryllium, Be, stock solution – 10000 of 10 000 μg/ml;, commercially available.

5.10 Scandium, Sc, stock solution – 10000 of 10 000 μg/ml;, commercially available.

5.11 Cesium chloride, CsCl, FWMW of 168,36, with a purity >greater than 99.,99 % or

999,99 g/kg.

5.12 Lithium nitrate, LiNO , FWMW of 68,95, with a purity >greater than 99 % or 990,0 g/kg.

5.13 Citrate-EDTA extraction solution (0,11 M ammonium citrate and 0,033 M disodium-

EDTA).

Weigh and transfer 25 g disodium-EDTA and 50 g dibasic ammonium citrate to a 2 l volumetric

flask containing approximately 1500 500 ml of deionized (or equivalent) water. Adjust the pH

to near neutral by adding 30 ml of (1 + 1, v/v) ammonium hydroxide +and water (1:1, volume

fraction) solution in a fume hood. Adjust the final pH to 7,00 (±0,02) using a pH electrode and

meter while adding the ammonium hydroxide +and water (1 + :1, v/vvolume fraction) solution

drop-by-drop and stirring. After obtaining a stable pH of 7,00 (±± 0,02),, bring the flask to

volume with deionized water (or equivalent) and mix. Larger volumes of this solution can be

prepared; however, it is susceptible to microbial degradation resulting in a shelf life of no more

than 3three weeks, if stored in a dark location.
5.14 0,5 % or 5 mL/L Triton-X – ml/l octyl phenol ethoxylate.

Add 1 mL Triton X-100 ml of octyl phenol ethoxylate (5.8 above) to a 200 ml volumetric flask

and dilute to volume with deionized water.

5.15 Internal standard/ionization buffer (10 µg/ml Sc in 0,018 M CsCl and 4 % nitric acid).

– Add 1 mL 10000 ml 10 000 μg/ml Sc stock standard, 3 g cesium chloride, 40 ml nitric acid,

and 1 ml 0,5% Triton-X % octyl phenol ethoxylate to a 1 l volumetric flask containing

approximately 500 ml of deionized (or equivalent) water. Bring flask to volume with deionized

(or equivalent) water and mix. If Be is used as an internal standard, add 4 ml of 10000

10 000 μg/ml Be stock standard to obtain a concentration of 40 μg/ml Be.

5.15.1 Alternatively, Li from LiNO maycan be substituted for Cs as an ionization buffer at 7 g

LiNO3 per liter. litre.
2% Nitric Acid Rinse Solution – 5.16 4 % nitric acid rinse solution.

Add 20 40 ml of nitric acid (5.4) to approximately 500 ml of deionized or equivalent water

contained in a 1 l volumetric flask and bring to volume.

2 SRM 193 is the trade name of a product supplied by NIST. This information is given for the convenience of users of this document and does not constitute an

endorsement by ISO of the product named. Equivalent products may be used if they can be shown to lead to the same results.

3 Triton X-100 is the trade name of a product supplied by Sigma-Aldrich. This information is given for the convenience of users of this document and does not

constitute an endorsement by ISO of the product named. Equivalent products may be used if they can be shown to lead to the same results.

© ISO 2022 – All rights reserved 3
---------------------- Page: 10 ----------------------
ISO/DTS 20917:2022(E)
2500 5.17 2 500 µg/ml phosphorus from phosphate (PO4) – ).

Add 2,7461 746 1 g of potassium dihydrogen phosphate (5.5 above) to a 250 ml volumetric

flask, then bring to volume with deionized (or equivalent) water. This standard also contains

31563 156,5 μg/ml K; also, this standard maycan take several hours to solubilize and stabilize.

This standard should be prepared fresh each time. Alternatively, a commercial custom standard

from a phosphate source prepared in a water matrix and preserved with a biocide is acceptable.

NOTE : A commercial stock standard preserved in acid is not acceptable as the acid will

changechanges the matrix of the pH neutral ammonium citrate EDTA solution and produceproduces

erroneous results.
7500 5.18 7 500 µg/ml potassium from potassium chloride – .

Add 1,4300 430 0 g of potassium chloride (5.6 above) to a 100 ml volumetric flask, then bring to

volume with deionized (or equivalent) water. Alternatively, 1,9394 939 4 g of potassium nitrate

(5.7 above) can be used rather than potassium chloride. This standard should be prepared fresh

each time. Alternatively, a commercial custom standard from a potassium source prepared in a

water matrix and preserved with a biocide is acceptable.

NOTE : A commercial stock standard preserved in acid is not acceptable as the acid will

changechanges the matrix of the pH neutral ammonium citrate EDTA solution and produceproduces

erroneous results.
76 Apparatus
6.1 Analytical balance, with a readability to 0,1 mg.
6.2 pH meter, with a readability to pH 7,00.
6.3 pH combination electrode.

6.4 Constant temperature water bath, capable of maintaining temperaturesa temperature of

65 ± 2°C ± 2 °C.

6.5 Heated shaking water bath, capable of maintaining bath temperaturesa temperature of

65 ± 2°C, ± 2 °C and set to approximately 200 reciprocations/min. NA

A water bath is preferred, but alternatively an enclosed heated air shaker is also acceptable;

however, ensure the added citrate-EDTA solution (5.13) is at 65 ± °C ± 2 °C before starting.

6.6 ICP-OES instrument – .

A radial view instrument is preferred for potassium, while phosphorus can be determined in

either radial or axial view.
6.7 Rotating riffle splitter, or comparable.

6.8 Grinding mill –, capable of grinding fertilizer material to pass a 0,50 mm screen or sieve.

87 Sampling and sample preparation

7.1 Collect a field sample using a recognized sampling procedure (such as ISO 14820-1; or

comparable (see References [8] and [9]).
4 © ISO 2022 – All rights reserved
---------------------- Page: 11 ----------------------
ISO/DTS 20917:2022(E)
7.1 7.2 ,3).

Prepare solid and liquid fertilizer materials using a recognized sample preparation procedure

such as ISO 14820-12 or comparable.
98 Procedure
9.18.1 Extraction of P and K

For samples containing less than 45 % P2O5 or K2O, weigh 0,5 ± g ± 0,01 g of material and

completely transfer to a 250 ml class A volumetric flask. For samples containing 45 % or more

P O or K O, weigh 0,45 ± ± 0,01 g of ground fertilizer material and completely transfer to a

2 5 2

250 mL class A volumetric flask. Dispense 100 ml of 65 ± °C ± 2 °C preheated ammonium

citrate, disodium-EDTA extraction solution (5.13 above) into each flask and insert a rubber

stopper. Shake test solutions in a 65 ± °C ± 2 °C preheated water bath set to approximately

200 reciprocations per minute for exactly 60 min; then. Then, remove from the water bath,;

allow to cool to room temperature,; bring to volume with deionized (or equivalent) water,;

stopper, and mix. Filter any test solution containing suspended debris using P and K free filters.

Some slowly soluble phosphate compounds maycan continue to solubilize over time resulting in

a high bias, so test solutions should be run as soon as possible, but no more than 24 hoursh after

extraction.

NOTE: If a homogeneous ground laboratory sample is not attainable, the weights and

volumes listed should be at least doubled to improve representation.
9.58.2 Instrument conditions

Optimal instrument conditions identified during robustness testing are listed in Table 1. ICP-

OES’ differ in their design and options, so adjustment to the conditions listed in Table 1 maycan

be necessary; however, any adjustments to these conditions must be performance-based and

validated. Special attention should be paid to the recovery of P in fertilizer concentrates such as

(40% TSP
MAP + S concentrated superphosphate, diammonium phosphate (46 % of P O ), and
2 5
DAP (46% P O ), and MAP %
2 5 monoammonium phosphate (50 % or 52 % of P O ), since these
2 5
materials require optimal instrument performance
© ISO 2022 – All rights reserved 5
---------------------- Page: 12 ----------------------
ISO/DTS 20917:2022(E)
Table 1 – — Recommended ICP-OES conditions conditions
Factor Setting
Power, kW 1,4
Plasma flow, l/min 18,0
Auxiliary flow, l/min 2,25
Nebulizer pressure, l/min 0,7
Nebulizer Concentric type
Spray chamber Double path cyclonic
Sample pump tube black/black
Buffer/internal standard pump tube gray/gray
CsCl ionic buffer concentration, M 0,018
Buffer matrix 4 % nitric acid
Exposure length, s 10
Number of exposures 2
Rinse time, s 35
Total analysis time, min 2
NOTE: Other instrument conditions that produce equivalent test results
are an option provided the test conditions are validated.
9.68.3 Preparation of standards
9.6.18.3.1 Standards from reagent salts
Calibration standards can be made from potassium dihydrogen phosphate (5.17) and

potassium chloride (5.18). Several calibration standards are required for the following reasons:

a) multiple ICP-OES wavelengths are utilized to expand the dynamic calibration range, b) some

wavelengths are split into multiple calibration segments, and c) a minimum of 5 points per

curve is recommended. The standards used and their P and K concentrations expressed as

ug/mL and as their percent oxide forms are listed in Table 2. These standards are susceptible to

microbial degradation and have a shelf life of no more than 3 weeks, if stored in the dark.

9.6.28.3.2 Standards from commercial stock solutions

Alternatively, custom stock standards can also be purchased but must be in a water matrix and

preserved with a biocide as standards preserved in acid will change the pH of the matrix and

produce erroneous results.
6 © ISO 2022 – All rights reserved
---------------------- Page: 13 ----------------------
ISO/DTS 20917:2022(E)
Table 2 –— ICP P and K calibration standards
Citrate- P O
2 5

Standard ID Volume Volume of P Volume of K P P 2O 5 solution P 2O 5 K K 2O K 2O solution

K O
EDTA 2
standard standard fertilizer Fertilizer
(mL)
a b e
ml ml ml µg/ml % % µg/ml µg/ml %
fertilizer
µg/ml
Blank 250 100 0 0 0 0 0,00000000 00 0 0 0 0,00000000 00 0
d c
1 250 100 10 of Std 7 NA 12 27,5 0,00275002 75 1,4 15,2 18,3 0,00183001 83 0,9
d c
2 250 100 20 of Std 7 NA 24 55,0 0,00550005 50 2,7 30,3 36,5 0,00365003 65 1,8
3 250 100 5 NA 50 114,6 0,01146011 46 5,7 63,1 76,0 0,00760007 60 3,8
4 250 100 10 NA 100 229,1 0,02291022 91 11,5 126,3 152,1 0,01521015 21 7,6
5 250 100 15 NA 150 343,7 0,03437034 37 17,2 189,4 228,1 0,02281022 81 11,4

6 250 100 22 (15+7) NA 220 504,1 0,05041050 41 25,2 277,8 334,6 0,03346033 46 16,7

7 250 100 30 NA 300 687,4 0,06874068 74 34,4 378,8 456,3 0,04563045 63 22,8
8 250 100 40 NA 400 916,5 0,09165091 65 45,8 505 608,4 0,06084060 84 30,4
c c c c c
9 250 100 NA 20 NA NA NA NA 600 722,7 0,07227072 27 36,1
c c c c c
10 250 100 NA 25 NA NA NA NA 750 903,4 0,09034090 34 45,2
c c c c c
11 250 100 NA 30 NA NA NA NA 900 10841 084,1 0,10841108 41 54,2

P standard concentration = 2500 ugis equal to 2 500 µg/ml P as PO4 or 2,7461 746 1 g of potassium dihydrogen phosphate KH2PO4 is brought to 250 ml, which also

contains 31563 156,5 ug/ml K.

K standard concentration = 7500 ugis equal to 7 500 µg/ml K from KCl or 1,4300 430 0 g of potassium chloride or 1,9394 939 4 g of potassium nitrate is brought to 100 ml.

na = NA : not applicable.

Serial dilution from another standard; 10 of Std 7 = pipet 10 ml from standard 7.

Equivalent final result when based upon a 0.,5 g sample brought to a final volume of 250 ml.

NOTE 1 : A 52 % P2O5 fertilizer material weighed at 0,45 g rather than 0,5 g results in a concentration of 46,8 % P2O5, which is a 2 % extrapolation from the top

standard.

NOTE 2 : A 62 % K2O fertilizer material weighed at 0,45 g rather than 0,5 g results in a concentration of 55,8 % K2O, which is a 3 % extrapolation from the top standard.

© ISO 2022 – All rights reserved 1
---------------------- Page: 14 ----------------------
ISO/DTS 20917:2022(E)
9.6.38.3.3 Calibration and wavelength splitting

BecauseAs the higher points on the calibration curve have a much greater influence, this can

adversely impact the accuracy of the lower points. It is therefore recommended that the broad

calibration range be split into two segments, which are listed in Table 3. By splitting the same

wavelength into two separate curves [i.e. ((see Reference [1) and (2)]) or a low and high

concentration range] and/or by using two separate wavelengths, the quality of the lower P and

K concentrations will improve.

Table 3 – — Calibration criteria for ammonium citrate, disodium-EDTA soluble P and K

a a
ICP-OES OES

Element Wavelength, nm Preferred view Calibration Standards used Curve fit Spectral

range (see Table 1) deconvolution
, μg /ml
P 213.,618 (1) Radial or axial 0 to 100 Blank, 1, 2, 3, 4 Linear Cu 213.,598
P 213.,618 (2) Radial or axial 100 to 400 4, 5, 6, 7, 8 Linear Cu 213.,598
P 214.,914 (1) Radial or axial 0 to 100 Blank, 1, 2, 3, 4 Linear Cu 214.,898
P 214.,914 (2) Radial or axial 100 to 400 4, 5, 6, 7, 8 Linear Cu 214.,898
P 177.,434 (1) Axial 0 to 100 Blank, 1, 2, 3, 4 Linear None
P 177.,434 (2) Axial 100 to 400 4, 5, 6, 7, 8 Linear None
P 178.,222 (1) Axial 0 to 100 Blank, 1, 2, 3, 4 Linear None
P 178.,222 (2) Axial 100 to 400 4, 5, 6, 7, 8 Linear None
K 766.,485 (1) Radial 0 to 126 Blank, 1, 2, 3, 4 Linear None
K 766.,485 (2) Radial 126 to 505 4, 5, 6, 7, 8 Linear None
K 766.,485 (3) Radial 379 to 900 7, 8, 9, 10, 11 Linear None

Other instrument conditions that produce equivalent test results are an option provided the test conditions are

validated.

(1), (2) and (3) are used to distinguish between the same wavelength used multiple times to cover separate

concentration ranges.

Optional, less intense wavelengths without any spectral interference that maycan be considered.

9.6.48.3.4 Analysis

A test portion is prepared as described in section Clause 7 and extracted as described in section

8.1 and presented to the ICP-OES configured according to Tables 1 and 3 using calibration

standards outlined in Table 2.
8.4 8.4 Quality control
9.7.18.4.1 Reference material

Within each analytical batch of samples, inclusion of one or more certified or consensus

fertilizer materials for quality assurance purposes is recommended, especially for the fertilizer

concentrates (i.e., P2O5 and K2O > 40%). Some sources of these materials include Laboratory

© ISO 2022 – All rights reserved 1
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ISO/DTS 20917:2022(E)

Quality Services International (LQSI) (), and the Magruder () or AFPC () check sample programs.. P2O5

and K O greater than 40 %).
9.7.28.4.2 Duplicates

Duplicate pours from each extract solution are recommended. Duplicate phosphate results that

agree within 0.,183 and duplicate potash results that agree within 0.,148 are recommended as

outlined
...

FINAL
TECHNICAL ISO/DTS
DRAFT
SPECIFICATION 20917
ISO/TC 134
Fertilizers, soil conditioners
Secretariat: INSO
and beneficial substances —
Voting begins on:
2023-02-03 Determination of ammonium citrate,
disodium-EDTA soluble phosphorus
Voting terminates on:
2023-03-31
and potassium by ICP-OES in inorganic
fertilizers
RECIPIENTS OF THIS DRAFT ARE INVITED TO
SUBMIT, WITH THEIR COMMENTS, NOTIFICATION
OF ANY RELEVANT PATENT RIGHTS OF WHICH
THEY ARE AWARE AND TO PROVIDE SUPPOR TING
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Reference number
BEING ACCEPTABLE FOR INDUSTRIAL, TECHNO-
ISO/DTS 20917:2023(E)
LOGICAL, COMMERCIAL AND USER PURPOSES,
DRAFT INTERNATIONAL STANDARDS MAY ON
OCCASION HAVE TO BE CONSIDERED IN THE
LIGHT OF THEIR POTENTIAL TO BECOME STAN-
DARDS TO WHICH REFERENCE MAY BE MADE IN
NATIONAL REGULATIONS. © ISO 2023
---------------------- Page: 1 ----------------------
ISO/DTS 20917:2023(E)
FINAL
TECHNICAL ISO/DTS
DRAFT
SPECIFICATION 20917
ISO/TC 134
Fertilizers, soil conditioners
Secretariat: INSO
and beneficial substances —
Voting begins on:
Determination of ammonium citrate,
disodium-EDTA soluble phosphorus
Voting terminates on:
and potassium by ICP-OES in inorganic
fertilizers
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DOCUMENTATION.
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IN ADDITION TO THEIR EVALUATION AS
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Email: copyright@iso.org
BEING ACCEPTABLE FOR INDUSTRIAL, TECHNO­
ISO/DTS 20917:2023(E)
Website: www.iso.org
LOGICAL, COMMERCIAL AND USER PURPOSES,
DRAFT INTERNATIONAL STANDARDS MAY ON
Published in Switzerland
OCCASION HAVE TO BE CONSIDERED IN THE
LIGHT OF THEIR POTENTIAL TO BECOME STAN­
DARDS TO WHICH REFERENCE MAY BE MADE IN
© ISO 2023 – All rights reserved
NATIONAL REGULATIONS. © ISO 2023
---------------------- Page: 2 ----------------------
ISO/DTS 20917:2023(E)
Contents Page

Foreword ........................................................................................................................................................................................................................................iv

Introduction .................................................................................................................................................................................................................................v

1 Scope ................................................................................................................................................................................................................................. 1

2 Normative references ..................................................................................................................................................................................... 1

3 Terms and definitions .................................................................................................................................................................................... 1

4 Principle ........................................................................................................................................................................................................................ 1

5 Reagents ........................................................................................................................................................................................................................ 2

6 Apparatus .................................................................................................................................................................................................................... 3

7 Sampling and sample preparation .................................................................................................................................................... 4

8 Procedure ....................................................................................................................................................................................................................4

8.1 Extraction of P and K ........................................................................................................................................................................ 4

8.2 Instrument conditions ..................................................................................................................................................................... 4

8.3 Preparation of standards .............................................................................................................................................................. 5

8.3.1 Standards from reagent salts .................................................................................................................................. 5

8.3.2 Standards from commercial stock solutions ............................................................................................. 5

8.3.3 Calibration and wavelength splitting .............................................................................................................. 7

8.3.4 Analysis ...................................................................................................................................................................................... 7

8.4 Quality control ........................................................................................................................................................................................ 7

8.4.1 Reference material ........................................................................................................................................................... 7

8.4.2 Duplicates ................................................................................................................................................................................. 7

9 Calculations and expression of results ........................................................................................................................................ 7

9.1 Calculations ............................................................................................................................................................................................... 7

9.2 Precision ......... .................................................................................................................................. ............................................................ 8

9.2.1 General ........................................................................................................................................................................................ 8

9.2.2 Repeatability, r ..................................................................................................................................................................... 9

9.2.3 Reproducibility, R .............................................................................................................................................................. 9

10 Test report ...............................................................................................................................................................................................................10

Annex A (informative) Ring test background and results .........................................................................................................11

Annex B (informative) Critical factors ...........................................................................................................................................................24

Bibliography .............................................................................................................................................................................................................................26

iii
© ISO 2023 – All rights reserved
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ISO/DTS 20917:2023(E)
Foreword

ISO (the International Organization for Standardization) is a worldwide federation of national standards

bodies (ISO member bodies). The work of preparing International Standards is normally carried out

through ISO technical committees. Each member body interested in a subject for which a technical

committee has been established has the right to be represented on that committee. International

organizations, governmental and non­governmental, in liaison with ISO, also take part in the work.

ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of

electrotechnical standardization.

The procedures used to develop this document and those intended for its further maintenance are

described in the ISO/IEC Directives, Part 1. In particular, the different approval criteria needed for the

different types of ISO documents should be noted. This document was drafted in accordance with the

editorial rules of the ISO/IEC Directives, Part 2 (see www.iso.org/directives).

Attention is drawn to the possibility that some of the elements of this document may be the subject of

patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of

any patent rights identified during the development of the document will be in the Introduction and/or

on the ISO list of patent declarations received (see www.iso.org/patents).

Any trade name used in this document is information given for the convenience of users and does not

constitute an endorsement.

For an explanation of the voluntary nature of standards, the meaning of ISO specific terms and

expressions related to conformity assessment, as well as information about ISO's adherence to

the World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT), see

www.iso.org/iso/foreword.html.

This document was prepared by Technical Committee ISO/TC 134, Fertilizers, soil conditioners and

beneficial substances.

Any feedback or questions on this document should be directed to the user’s national standards body. A

complete listing of these bodies can be found at www.iso.org/members.html.
© ISO 2023 – All rights reserved
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ISO/DTS 20917:2023(E)
Introduction

Inductively coupled plasma-optical emission spectrometer (ICP-OES) instrumentation is becoming

increasingly popular in fertilizer testing laboratories (see References [1], [2] and [3]). Because these

instruments are automated and can determine multiple elements simultaneously, they offer significant

productivity gains. Also, the method does not generate hazardous wastes. The ammonium citrate

disodium etheylenediamine tetraacetic acid (EDTA) organic solvent and samples containing high

phosphorus and/or potassium concentrations pose some analytical challenges for the instrumentation,

which must be addressed. Due to the increasing use of this technology, this document was created.

For organic fertilizers and for liquid fertilizers containing phosphorous acid (H PO or phosphite), an

3 3

alternative method that specifically measures PO is preferred since the ICP­OES measures all elemental

phosphorus, which can result in a high bias for these types of fertilizer materials (see Reference [1]).

Due to the inability of the ICP-OES to differentiate between phosphorus species, under normal

operating conditions, this method is primarily intended for fertilizer materials in which the source(s)

of phosphorus is known. While this document can be used with minimal bias, the repeatability and

reproducibility is not consistent with other standards routinely used for inspection at this time, such as

[4] [5] [6]
EN 15959 , EN 15477 or ISO 22018 .

As a result, this document is intended for screening purposes, where a large number of fertilizer

phosphorus and potassium results must be obtained as efficiently as possible.
© ISO 2023 – All rights reserved
---------------------- Page: 5 ----------------------
TECHNICAL SPECIFICATION ISO/DTS 20917:2023(E)
Fertilizers, soil conditioners and beneficial substances —
Determination of ammonium citrate, disodium-EDTA
soluble phosphorus and potassium by ICP-OES in inorganic
fertilizers
1 Scope

This document specifies an inductively coupled plasma-optical emission spectrometer (ICP-OES)

method for the determination of the ammonium citrate, disodium-etheylenediamine tetraacetic acid

(EDTA) soluble phosphorus and potassium content in fertilizer extract solutions.

This document is applicable to all inorganic fertilizer products, whether compound or complex fertilizer

products or blends thereof, and straight concentrated fertilizer products.
2 Normative references

The following documents are referred to in the text in such a way that some or all of their content

constitutes requirements of this document. For dated references, only the edition cited applies. For

undated references, the latest edition of the referenced document (including any amendments) applies.

ISO 8157, Fertilizers, soil conditioners and beneficial substances — Vocabulary

ISO 14820­1, Fertilizers and liming materials — Sampling and sample preparation — Part 1: Sampling

ISO 14820­2, Fertilizers and liming materials — Sampling and sample preparation — Part 2: Sample

preparation
3 Terms and definitions

For the purposes of this document, the terms and definitions given in ISO 8157 apply.

ISO and IEC maintain terminology databases for use in standardization at the following addresses:

— ISO Online browsing platform: available at https:// www .iso .org/ obp
— IEC Electropedia: available at https:// www .electropedia .org/
4 Principle

Phosphorus and potassium contained in inorganic fertilizers that is soluble in a heated, dilute

ammonium citrate and disodium­EDTA solvent is determined. The neutral ammonium citrate is the

primary solvent for phosphate, while the EDTA is mainly included to chelate calcium, magnesium and

other soluble metallic cations to minimize their interaction with phosphate and eliminate the water­

wash step (see Reference [7]). Also, since this solvent is a relatively weak solution, it extracts primarily

the highly soluble potassium compounds and has been used for fertilizer potassium determination

since 1993. It compares very favourably with other soluble potash solvents such as ammonium oxalate.

The user of this document is not obligated to determine both phosphorus and potassium; however, one

of the main advantages of this approach is to measure both simultaneously in a single extract in a more

productive, cost-effective way.

The resulting extract solution is tested by ICP-OES to quantify the levels of phosphorus and potassium,

which can be converted to their equivalent P O and K O concentrations. The extract solution is

2 5 2
© ISO 2023 – All rights reserved
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ISO/DTS 20917:2023(E)

nebulized to produce a fine aerosol, which is introduced to a plasma or high energy source to ionize

or excite electrons to higher energy orbitals. As these electrons return to ground state, they emit

characteristic ultraviolet or visible wavelengths that are unique to each element. The intensity of the

wavelength emission is proportionate to the concentration, which can be quantified by various detector

types including a photomultiplier tube (PT), a charge injection device (CID) or a charge coupled device

(CCD).
5 Reagents

5.1 Ammonium citrate, dibasic, (NH ) HC H O , with a molecular weight (MW) of 226,19 and a

4 2 6 5 7
purity greater than 98 % or 980,0 g/kg.

5.2 EDTA, disodium salt, dehydrate, C H N Na O ·2H O, with a MW of 372,24 and a purity

10 14 2 2 8 2
greater than 98 % or 980,0 g/kg.

5.3 Ammonium hydroxide, NH OH, with a MW of 35,05 and a purity equal to 28,0-30,0 % as NH or

4 3
ρ = 0,91 g/ml.
5.4 Nitric acid, HNO , 67-70 %, with a ρ = 1,40 g/ml.

5.5 Potassium dihydrogen phosphate, KH PO , with a MW of 136,09, with a purity greater than

2 4
99 % or 990,0 g/kg .

5.6 Potassium chloride, KCl, with a MW of 74,55 and a purity greater than 99 % or 990 g/kg.

5.7 Potassium nitrate, KNO , with a MW of 101,10 with a purity greater than 99 % or 990,0 g/kg .

5.8 Octyl phenol ethoxylate .
5.9 Beryllium, Be, stock solution of 10 000 μg/ml, commercially available.
5.10 Scandium, Sc, stock solution of 10 000 μg/ml, commercially available.

5.11 Cesium chloride, CsCl, MW of 168,36, with a purity greater than 99,99 % or 999,99 g/kg.

5.12 Lithium nitrate, LiNO , MW of 68,95, with a purity greater than 99 % or 990,0 g/kg.

5.13 Citrate-EDTA extraction solution (0,11 M ammonium citrate and 0,033 M disodium­EDTA).

Weigh and transfer 25 g disodium-EDTA and 50 g dibasic ammonium citrate to a 2 l volumetric flask

containing approximately 500 ml of deionized (or equivalent) water. Adjust the pH to near neutral by

adding 30 ml of ammonium hydroxide and water (1:1, volume fraction) solution in a fume hood. Adjust

the final pH to 7,00 (±0,02) using a pH electrode and meter while adding the ammonium hydroxide and

water (1:1, volume fraction) solution drop-by-drop and stirring. After obtaining a stable pH of 7,00 ±

1) SRM 194a is the trade name of a product supplied by National Institute of Standards and Technology (NIST).

This information is given for the convenience of users of this document and does not constitute an endorsement by

ISO of the product named. Equivalent products may be used if they can be shown to lead to the same results.

2) SRM 193 is the trade name of a product supplied by NIST. This information is given for the convenience of users

of this document and does not constitute an endorsement by ISO of the product named. Equivalent products may be

used if they can be shown to lead to the same results.

3) Triton X-100 is the trade name of a product supplied by Sigma-Aldrich. This information is given for the

convenience of users of this document and does not constitute an endorsement by ISO of the product named.

Equivalent products may be used if they can be shown to lead to the same results.

© ISO 2023 – All rights reserved
---------------------- Page: 7 ----------------------
ISO/DTS 20917:2023(E)

0,02, bring the flask to volume with deionized water (or equivalent) and mix. Larger volumes of this

solution can be prepared; however, it is susceptible to microbial degradation resulting in a shelf life of

no more than three weeks, if stored in a dark location.
5.14 0,5 % or 5 ml/l octyl phenol ethoxylate.

Add 1 ml of octyl phenol ethoxylate (5.8) to a 200 ml volumetric flask and dilute to volume with

deionized water.

5.15 Internal standard/ionization buffer (10 µg/ml Sc in 0,018 M CsCl and 4 % nitric acid).

Add 1 ml 10 000 μg/ml Sc stock standard, 3 g cesium chloride, 40 ml nitric acid, and 1 ml 0,5 % octyl

phenol ethoxylate to a 1 l volumetric flask containing approximately 500 ml of deionized (or equivalent)

water. Bring flask to volume with deionized (or equivalent) water and mix. If Be is used as an internal

standard, add 4 ml of 10 000 μg/ml Be stock standard to obtain a concentration of 40 μg/ml Be.

Alternatively, Li from LiNO can be substituted for Cs as an ionization buffer at 7 g LiNO per litre.

3 3
5.16 4 % nitric acid rinse solution.

Add 40 ml of nitric acid (5.4) to approximately 500 ml of deionized or equivalent water contained in a

1 l volumetric flask and bring to volume.
5.17 2 500 µg/ml phosphorus from phosphate (PO ).

Add 2,746 1 g of potassium dihydrogen phosphate (5.5) to a 250 ml volumetric flask, then bring to

volume with deionized (or equivalent) water. This standard also contains 3 156,5 μg/ml K; also, this

standard can take several hours to solubilize and stabilize. This standard should be prepared fresh

each time. Alternatively, a commercial custom standard from a phosphate source prepared in a water

matrix and preserved with a biocide is acceptable.

NOTE A commercial stock standard preserved in acid is not acceptable as the acid changes the matrix of the

pH neutral ammonium citrate EDTA solution and produces erroneous results.
5.18 7 500 µg/ml potassium from potassium chloride.

Add 1,430 0 g of potassium chloride (5.6) to a 100 ml volumetric flask, then bring to volume with

deionized (or equivalent) water. Alternatively, 1,939 4 g of potassium nitrate (5.7) can be used rather

than potassium chloride. This standard should be prepared fresh each time. Alternatively, a commercial

custom standard from a potassium source prepared in a water matrix and preserved with a biocide is

acceptable.

NOTE A commercial stock standard preserved in acid is not acceptable as the acid changes the matrix of the

pH neutral ammonium citrate EDTA solution and produces erroneous results.
6 Apparatus
6.1 Analytical balance, with a readability to 0,1 mg.
6.2 pH meter, with a readability to pH 7,00.
6.3 pH combination electrode.

6.4 Constant temperature water bath, capable of maintaining a temperature of 65 °C ± 2 °C.

© ISO 2023 – All rights reserved
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ISO/DTS 20917:2023(E)

6.5 Heated shaking water bath, capable of maintaining a temperature of 65 °C ± 2 °C and set to

approximately 200 reciprocations/min.

A water bath is preferred, but alternatively an enclosed heated air shaker is also acceptable; however,

ensure the added citrate­EDTA solution (5.13) is at 65 °C ± 2 °C before starting.

6.6 ICP-OES instrument.

A radial view instrument is preferred for potassium, while phosphorus can be determined in either

radial or axial view.
6.7 Rotating riffle splitter, or comparable.

6.8 Grinding mill, capable of grinding fertilizer material to pass a 0,50 mm screen or sieve.

7 Sampling and sample preparation

7.1 Collect a field sample using a recognized sampling procedure such as ISO 14820-1 or comparable

(see References [8] and [9]).

7.2 Prepare solid and liquid fertilizer materials using a recognized sample preparation procedure

such as ISO 14820­2 or comparable.
8 Procedure
8.1 Extraction of P and K

For samples containing less than 45 % P O or K O, weigh 0,5 g ± 0,01 g of material and completely

2 5 2

transfer to a 250 ml class A volumetric flask. For samples containing 45 % or more P O or K O, weigh

2 5 2

0,45 ± 0,01 g of ground fertilizer material and completely transfer to a 250 mL class A volumetric flask.

Dispense 100 ml of 65 °C ± 2 °C preheated ammonium citrate, disodium-EDTA extraction solution

(5.13) into each flask and insert a rubber stopper. Shake test solutions in a 65 °C ± 2 °C preheated water

bath set to approximately 200 reciprocations per minute for exactly 60 min. Then, remove from the

water bath; allow to cool to room temperature; bring to volume with deionized (or equivalent) water;

stopper and mix. Filter any test solution containing suspended debris using P and K free filters. Some

slowly soluble phosphate compounds can continue to solubilize over time resulting in a high bias, so

test solutions should be run as soon as possible, but no more than 24 h after extraction.

8.2 Instrument conditions

Optimal instrument conditions identified during robustness testing are listed in Table 1. ICP­OES’ differ

in their design and options, so adjustment to the conditions listed in Table 1 can be necessary; however,

any adjustments to these conditions must be performance-based and validated. Special attention

should be paid to the recovery of P in fertilizer concentrates such as concentrated superphosphate,

diammonium phosphate (46 % of P O ), and monoammonium phosphate (50 % or 52 % of P O ), since

2 5 2 5
these materials require optimal instrument performance
© ISO 2023 – All rights reserved
---------------------- Page: 9 ----------------------
ISO/DTS 20917:2023(E)
Table 1 — Recommended ICP-OES conditions
Factor Setting
Power, kW 1,4
Plasma flow, l/min 18,0
Auxiliary flow, l/min 2,25
Nebulizer pressure, l/min 0,7
Nebulizer Concentric type
Spray chamber Double path cyclonic
Sample pump tube black/black
Buffer/internal standard pump tube gray/gray
CsCl ionic buffer concentration, M 0,018
Buffer matrix 4 % nitric acid
Exposure length, s 10
Number of exposures 2
Rinse time, s 35
Total analysis time, min 2
Other instrument conditions that produce equivalent test results are
an option provided the test conditions are validated.
8.3 Preparation of standards
8.3.1 Standards from reagent salts

Calibration standards can be made from potassium dihydrogen phosphate (5.17) and potassium

chloride (5.18). Several calibration standards are required for the following reasons: a) multiple ICP-

OES wavelengths are utilized to expand the dynamic calibration range, b) some wavelengths are split

into multiple calibration segments, and c) a minimum of 5 points per curve is recommended. The

standards used and their P and K concentrations expressed as ug/mL and as their percent oxide forms

are listed in Table 2. These standards are susceptible to microbial degradation and have a shelf life of no

more than 3 weeks, if stored in the dark.
8.3.2 Standards from commercial stock solutions

Alternatively, custom stock standards can also be purchased but must be in a water matrix and

preserved with a biocide as standards preserved in acid will change the pH of the matrix and produce

erroneous results.
© ISO 2023 – All rights reserved
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ISO/DTS 20917:2023(E)
© ISO 2023 – All rights reserved
Table 2 — ICP P and K calibration standards

Standard ID Volume Citrate-EDTA Volume of P Volume of K P P O P O solution P O ferti- K K O K O solution K O ferti-

2 5 2 5 2 5 2 2 2
ml ml standard standard lizer µg/ml lizer
a b e e
ml ml µg/ml µg/ml % % µg/ml % %
Blank 250 100 0 0 0 0 0,000 00 0 0 0 0,000 00 0
d c
1 250 100 10 of Std 7 NA 12 27,5 0,002 75 1,4 15,2 18,3 0,001 83 0,9
d c
2 250 100 20 of Std 7 NA 24 55,0 0,005 50 2,7 30,3 36,5 0,003 65 1,8
3 250 100 5 NA 50 114,6 0,011 46 5,7 63,1 76,0 0,007 60 3,8
4 250 100 10 NA 100 229,1 0,022 91 11,5 126,3 152,1 0,015 21 7,6
5 250 100 15 NA 150 343,7 0,034 37 17,2 189,4 228,1 0,022 81 11,4
6 250 100 22 (15+7) NA 220 504,1 0,050 41 25,2 277,8 334,6 0,033 46 16,7
7 250 100 30 NA 300 687,4 0,068 74 34,4 378,8 456,3 0,045 63 22,8
8 250 100 40 NA 400 916,5 0,091 65 45,8 505 608,4 0,060 84 30,4
c c c c c
9 250 100 NA 20 NA NA NA NA 600 722,7 0,072 27 36,1
c c c c c
10 250 100 NA 25 NA NA NA NA 750 903,4 0,090 34 45,2
c c c c c
11 250 100 NA 30 NA NA NA NA 900 1 084,1 0,108 41 54,2

P standard concentration is equal to 2 500 µg/ml P as PO or 2,746 1 g of potassium dihydrogen phosphate KH PO is brought to 250 ml, which also contains 3 156,5 ug/ml K.

4 2 4

K standard concentration is equal to 7 500 µg/ml K from KCl or 1,430 0 g of potassium chloride or 1,939 4 g of potassium nitrate is brought to 100 ml.

NA : not applicable.

Serial dilution from another standard; 10 of Std 7 = pipet 10 ml from standard 7.

Equivalent final result when based upon a 0,5 g sample brought to a final volume of 250 ml.

NOTE 1 A 52 % P2O5 fertilizer material weighed at 0,45 g rather than 0,5 g results in a concentration of 46,8 % P2O5, which is a 2 % extrapolation from the top standard.

NOTE 2 A 62 % K2O fertilizer material weighed at 0,45 g rather than 0,5 g results in a concentration of 55,8 % K2O, which is a 3 % extrapolation from the top standard.

---------------------- Page: 11 ----------------------
ISO/DTS 20917:2023(E)
8.3.3 Calibration and wavelength splitting

As the higher points on the calibration curve have a much greater influence, this can adversely impact

the accuracy of the lower points. It is therefore recommended that the broad calibration range be split

into two segments, which are listed in Table 3. By splitting the same wavelength into two separate

curves (see Reference [1]) or a low and high concentration range and/or by using two separate

wavelengths, the quality of the lower P and K concentrations will improve.

Table 3 — Calibration criteria for ammonium citrate, disodium-EDTA soluble P and K by

ICP-OES

Element Wavelength Preferred view Calibration Standards used Curve fit Spectral

nm range (see Table 1) deconvolution
μg /ml
P 213,618 (1) Radial or axial 0 to 100 Blank, 1, 2, 3, 4 Linear Cu 213,598
P 213,618 (2) Radial or axial 100 to 400 4, 5, 6, 7, 8 Linear Cu 213,598
P 214,914 (1) Radial or axial 0 to 100 Blank, 1, 2, 3, 4 Linear Cu 214,898
P 214,914 (2) Radial or axial 100 to 400 4, 5, 6, 7, 8 Linear Cu 214,898
P 177,434 (1) Axial 0 to 100 Blank, 1, 2, 3, 4 Linear None
P 177,434 (2) Axial 100 to 400 4, 5, 6, 7, 8 Linear None
P 178,222 (1) Axial 0 to 100 Blank, 1, 2, 3, 4 Linear None
P 178,222 (2) Axial 100 to 400 4, 5, 6, 7, 8 Linear None
K 766,485 (1) Radial 0 to 126 Blank, 1, 2, 3, 4 Linear None
K 766,485 (2) Radial 126 to 505 4, 5, 6, 7, 8 Linear None
K 766,485 (3) Radial 379 to 900 7, 8, 9, 10, 11 Linear None

Other instrument conditions that produce equivalent test results are an option provided the test conditions are validated.

(1), (2) and (3) are used to distinguish between the same wavelength used mult
...

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    5 pages
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ISO
ISO 22887:2020(Main)
Determination of total sulfur in fertilizers by high temperature combustion

This document specifies a method to measure the total sulfur content in fertilizer and soil conditioner materials. This method is applicable for measuring total sulfur concentration in solid and liquid fertilizers and its raw inputs in the range of 0,1 % to 97 %.

  • Standard
    8 pages
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    9 pages
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    8 pages
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    9 pages
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ISO
ISO 14820-3:2020(Main)
Fertilizers and liming materials — Sampling and sample preparation — Part 3: Sampling of static heaps

This document is applicable to the sampling of mineral fertilizers and liming materials supplied or ready for supply to third parties, as a lot or in smaller lots, where such supply or readiness for supply is subject to legal requirements. This document specifies plans and methods of sampling of a lot of solid fertilizer or liming material, if sampling in motion is not possible, to obtain samples from bulk static heaps in order to ascertain compliance with legal requirements, in particular in relation to the accuracy of compulsory or permitted statutory declarations. The methods specified in this document are not applicable to obtain samples for physical size analysis or for chemical analysis which may be altered by particle granulometric segregation. This document is applicable to single nutrient fertilizers, to uniform complex fertilizers and to milled or granulated fertilizers and liming materials. The methods described in this document are not suitable for sampling other types of fertilizer, for example blended fertilizers. NOTE The term 'fertilizer' is used throughout the body of this document and includes liming materials unless otherwise indicated.

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    11 pages
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    12 pages
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    11 pages
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ISO
ISO 19747:2020(Main)
Fertilizers and soil conditioners — Determination of monosilicic acid concentrations in nonliquid fertilizer materials

This document establishes a method for the determination of monosilicic acid concentrations in nonliquid fertilizer materials. Monosilicic acid is reported as silicon (Si). This extraction method is applicable to the detection of monosilicic acid in nonliquid fertilizer products, blended products, and beneficial substances at silicon (Si) concentrations of 2 to 84 g/kg, with a limit of detection (LOD) of 0,6 g/kg Si, and a limit of quantification (LOQ) of 2 g/kg correlating well with plant uptake. This method is not applicable to liquid silicon fertilizer sources due to an expected low bias of Si recovery and low correlation with plant uptake.

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    10 pages
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    10 pages
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ISO
ISO 23381:2020(Main)
Determination of salt out (crystallization) temperature of liquid fertilizers

This document specifies the test procedure for the determination of the salt out temperature (SOT), also known as the crystallization temperature (CT) of liquid (fluid) fertilizers, using an inexpensive and simple technique. This method might not be applicable to the binary and ternary fertilizers, especially with regards to the last crystal to disappear (LCTD). Some of these exceptions are discussed in the procedure (Clause 8).

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    10 pages
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    10 pages
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