ISO-TECH SYSTEM, VARANASI Analysis by ph and ion selective electrodes

Similar documents
S ENTEK Unit 6 & 7 Crittall Court, Crittall Drive, Springwood Industrial Estate, Braintree, Essex, CM7 2SE Tel: +44 (0) Fax: +44 (0)

Operating Instructions for Ammonium ISE Specifications

Use a pipet bulb when pipeting cyanide solutions, as these solutions are highly toxic.

GENERAL INSTRUCTIONS GENERAL PREPARATION

GENERAL INSTRUCTIONS GENERAL PREPARATION

C = concentration as ppm sulfide V t = volume of titrant at endpoint V s = volume of standard used (10 ml)

Ion Selective Electrodes for the Laboratory. Presented by Chris Cushman OTCO Water Laboratory Analyst Workshop Thursday, May 14, 2015

Measurements with Ion Selective Electrodes: Determination of Fluoride in Toothpaste

METHOD 9210 POTENTIOMETRIC DETERMINATION OF NITRATE IN AQUEOUS SAMPLES WITH ION-SELECTIVE ELECTRODE

PRACTICAL 3 ph AND BUFFERS

Applications of Ion-Selective Electrodes

COLE-PARMER INDUSTRIAL POTASSIUM ION ELECTRODE INSTRUCTION MANUAL

GENERAL INSTRUCTIONS GENERAL PREPARATION

COLE-PARMER INDUSTRIAL AMMONIUM ION ELECTRODE INSTRUCTION MANUAL

COLE-PARMER LABORATORY AMMONIUM ION ELECTRODE INSTRUCTION MANUAL

Buffer Preparation. Learning Objectives:

COLE-PARMER LABORATORY CALCIUM ION ELECTRODE INSTRUCTION MANUAL

1) A ph/mv meter or an ion meter, either line operated or portable.

The Cole-Parmer Ammonium Ion Electrode is used to quickly, simply, accurately, and economically measure ammonium ions in aqueous solutions.

Ion Selective Electrodes

COLE-PARMER LABORATORY CYANIDE ION ELECTRODE INSTRUCTION MANUAL

The Cole-Parmer Nitrate Ion Electrodes are used to quickly, simply, accurately, and economically measure nitrate in aqueous solutions.

F- Cl- Br- I- CN- S2- NO3-

The Oakton Cadmium Ion Electrodes are used to quickly, simply, accurately, and economically measure cadmium ions in aqueous solutions.

COLE-PARMER LABORATORY NITRATE ION ELECTRODE INSTRUCTION MANUAL

2. Relative molecular mass, M r - The relative molecular mass of a molecule is the average mass of the one molecule when compared with

5072 CHEMISTRY (NEW PAPERS WITH SPA) BASIC TECHNIQUES 5067 CHEMISTRY (NEW PAPERS WITH PRACTICAL EXAM) BASIC TECHNIQUES

COLE-PARMER LABORATORY CUPRIC ION ELECTRODE INSTRUCTION MANUAL

User Manual. Thermo Scientific Orion Fluoride Ion Selective Electrode

ICSE Chemistry Model Paper-9

COLE-PARMER REPLACEABLE MEMBRANE CALCIUM ION ELECTRODES INSTRUCTION MANUAL

Electrodes for ph measurements. - when you need to be sure...

THE ST. MICHAEL SCHOOL THIRD FORM CHEMISTRY MANUAL 3 SYMBOLS AND FORMULAE, CHEMICAL BONDING AND CHEMICAL EQUATIONS

Direct Measurement ISE Method Method to 4.00 mg/l NO 3 N TISAB Solution

Method Abstract. Flow Solution Fluoride, USGS by ISE and FIA

TYPES OF CHEMICAL REACTIONS

Stoichiometry ( ) ( )

phoenix Electrode Company Silver/Sulfide Ion Electrodes Instruction Manual 1. A ph/mv meter or an ion meter, either line operated or portable.

[Agilent Technologies] [Electrochemistry Products] Quick Reference

CHEMISTRY PAPER 1999

... so we need to find out the NEW concentrations of each species in the system.

COLE-PARMER INDUSTRIAL CALCIUM ION ELECTRODE INSTRUCTION MANUAL

phoenix Electrode Company Ammonia Gas-Sensing Electrode Instruction Manual

The Oakton Lead Ion Electrodes are used to quickly, simply, accurately, and economically measure lead or sulfate ions in aqueous solutions.

perfection Guidebook perfection Combination Fluoride Electrode Successful Ion Measurement

Guide to ph Analysis.

Question. 4. Which organisation approves the names of elements all over the world? Write the symbol of gold. Answer.

COLE-PARMER INDUSTRIAL NITRATE ION ELECTRODE INSTRUCTION MANUAL

IGCSE Double Award Extended Coordinated Science

Chloride, HR, Direct Measurement ISE Method Method g/l to 35 g/l Cl Powder Pillow ISA

Chemical Reaction Defn: Chemical Reaction: when starting chemical species form different chemicals.

173 Buffer calculation: Tris buffer - Tris(hydroxymethyl)-aminomethane. tris base

C hapter ATOMS. (c) (ii) and (iii) (d) (ii) and (iv)

Class XI Chapter 1 Some Basic Concepts of Chemistry Chemistry

NCERT Solutions for Atoms and Molecules

COLE-PARMER INDUSTRIAL SILVER/SULFIDE ION ELECTRODE INSTRUCTION MANUAL

Chemical Reaction Defn: Chemical Reaction: when starting chemical species form different chemicals.

Chapter 6. Chemical Reactions. Sodium reacts violently with bromine to form sodium bromide.

CHEMICALS & REAGENTS

Chemistry 20 In Class Assignment

Appendices towards the Operation Manual of Ultrasonic milk analyzer Lactoscan

Set 4 Marking Scheme: Acid Bases & Salts 2010

CH 221 Chapter Four Part II Concept Guide

2014 Chemistry 1 st Semester Exam Review Packet

Na+ K+ Ag+ Ca2+ NH + 4. F- Cl- Br- I- CN- S2- NO3-

4. Magnesium has three natural isotopes with the following masses and natural abundances:

EXPERIMENTS. Testing products of combustion: Reducing Copper(III) Oxide to Copper. Page 4

Part A Answer all questions in this part.

Class IX Chapter 3 Atoms and Molecules Science

Extra Questions. Chemical Formula IUPAC Name Ionic, Molecular, or Acid. ethanol. sulfurous acid. titanium (IV) oxide. gallium sulfate.

CHEMISTRY. SCIENCE Paper 2

METHOD 9012 TOTAL AND AMENABLE CYANIDE (COLORIMETRIC, AUTOMATED UV)

Fluoride Sealed Electrode Sensor Bundle Product Number: ENFLU049

Test Booklet. Subject: SC, Grade: HS CST High School Chemistry Part 2. Student name:

Unit (2) Quantitative Chemistry

3. Which postulate of Dalton s atomic theory is the result of the law of conservation of mass?

NITROGEN AND ITS COMPOUNDS Q30 (i) Explain how the following would affect the yield of ammonia. An increase in (i). Pressure.

ph electrodes: what users should know

COLE-PARMER INDUSTRIAL NITRATE ION ELECTRODE INSTRUCTION MANUAL

Chapter 1 Chemical Reactions & Equations

Unit-8 Equilibrium. Rate of reaction: Consider the following chemical reactions:

Experiment 8 - Double Displacement Reactions

GETTING THE END POINT TO APPROXIMATE. Two hours

SPECIFICATION & TEST PROCEDURE SODIUM SALICYLATE Technical. Molecular weight : Reference : In-house

Acid, Bases and Salts (IGCSE Chemistry Syllabus )

Thermo Scientific Orion Fluoride Ion Selective Electrodes The standard in fluoride ion analysis EPA compliant

CHAPTER 14: ELECTRODES AND POTENTIOMETRY

(a) Complete Figure 9 by placing one tick in each row to show whether the salt is soluble or insoluble. salt soluble insoluble.

IGCSE TEST_ (Ch. 2,3,4,5,6) Name... Date...

EXPERIMENT 6. Properties of Buffers INTRODUCTION

Name Solutions and Acids/Bases/Salts

UNIVERSITY OF CAMBRIDGE INTERNATIONAL EXAMINATIONS General Certificate of Education Advanced Subsidiary Level and Advanced Level

Class X. Exercises solution

for free revision past papers visit:

POTASSIUM ION SELECTIVE ELECTRODE

The Mole. Relative Atomic Mass Ar

Chemistry. Approximate Timeline. Students are expected to keep up with class work when absent.

ICSE Board. Class X Chemistry. Board Paper Time: 1½ hrs Total Marks: 80

2 nd Term Worksheet [ ] Subject Chemistry Class VII Name : Sec. :

Ion Selective Electrode Probe

Transcription:

ISO-TECH SYSTE, VARANASI-221010 Related link : ph Combination Electrodes Analysis by ph and ion selective electrodes A comparative view of analysis by ph and Ion Selective Electrodes. Types of ISE electrodes. easurement techniques. Standard addition methods. olarity to ppm for electrode species. Electrode filling solutions and Internal Stabilization Adjusters (ISA). Preparation and use of TISAB. On this page - click to jump to the following info : Types of ISE's Electrode storage ISE methods ISE Filling solutions Special ISE buffers olarity to ppm conversions Analysis by Electrodes Ion selective electrodes are a technology that gives direct measurement of cations and anions such as sodium and fluoride, and can also measure dissolved gases such as ammonia and sulphur dioxide. Time consuming steps such as filtrations, weighings and distillation are not required in most cases. Concentrations can be read out directly on a ph/v/ion meter, or can be read from a constructed calibration curve. This instrument can also do double duty as a precision ph meter. Electrode methods save time, and since electrodes are portable, measurements can be made on a laboratory bench, the bank of a river or pond, the floor of a manufacturing plant, or the tray of a truck. About ph and ISE The ph electrode measures only the hydronium ion [H 3 O + ] concentration in a solution, whereas the ion selective electrode (ISE) measures the ionic concentration of an electrode species. A ph electrode will measure the alkalinity or acidity of a solution in the range of ph 0-14. Ph 1-7 is acidic and ph 7-14 is basic. However, ph 7 is neutral, since it is neither acidic nor basic. A Fluoride ISE will measure the concentration of F - ions in solution and a sodium ISE will measure the Na + ions in solution. ph Glass membrane Composition : 22% Na 2 O, 6% CaO and 72% SiO 2 - highly selective to hydrogen ions, the phelectrode. In ISE, the silicon dioxide glass matrix is doped with a specific chemical e.g. sodium to make the sodium ion specific electrode. Reference electrode Silver/siver chloride or calomel ph reference electrodes are used only for ph measurements. For ion selective electrodes a special single or double junction reference electrode must be used. A ph reference electrode cannot be used as a reference electrode for an ISE determination. Combination electrode The C30F lab now use the combination type electrodes instead of the half cell types for both ph and ISE determinations. It is convenient, can be used with small volumes, and can be easilly moved in and out of measuring solutions. In a ph combination electrode the reference is housed in the same cylindrical body as the sensor head. This produces a simple compact unit for making measurements. In a specific ion combination electrode, a sleeve type reference electrode and a solid-state sensing element is incorporated into a single 13 mm diameter electrode body.

Types of ion selective electrodes An ion selective electrode measures the potential of a specifc ion in solution against a stable reference electrode of constant potential. The potential difference depends upon the activity of the specific ion in solution. The activity is related to the concentration of that specific ion, hence an alytical measurement can be made. The most important feature of an ion selective electrode is the selective membrane that it is made off. There are two main types of membrane material : Solid crystal matrix - a single crystal or a polycrystalline compressed pelet. Ion carrier - a complex organic molecule impregnated into a plastic, PVC. or rubber film which acts as an ion carrier. Glass membrane : the silicon glass matrix is doped with a specific chemical e.g. sodium to make the sodium ion specific electrode. Liquid membrane : consist of various ion exchange materials on an inert, hydrophobic PVC, polyethelene, or silicone rubber. Used in aqueous solutions only. It comes with a ready to use pre-tested sensing module screwed into a lower replaceable body. e.g. the selective ion electrodes of K, Ca, and Nitrate. Solid-state : sensing element is a crystal sealed flush into one end of the electrode body; a La crystal for the Fluoride ISE and a compressed Ag 2 S for silver / sulphide electrodes. ade of unbreakable epoxy bodies, resistant to most inorganic reagents, and can be used intermittantly in most common organic solvents such as methanol, acetone and dioxane. ust not be used with strong polar solvents such as DF, or chloroform. Examples of this type of electrodes are silver / sulphide, chloride, fluoride, and copper. Gas sensing : has a gas permeable membrane, and an internal buffer solution whose ph changes as the gas reacts with it, and this change is detected by a combination ph sensor within the electrode housing There is therefore no need for a reference electrode. There are special ISE construction designs for ammonia, carbon dioxide, nitrogen dioxide, and oxygen. Reference : mono electrode or half-cells designed specially for specific ion electrode systems. Has sleeve type construction that minimizes liquid junction potential and avoids clogging problems encountered with frit and fiber type electrodes. ade from virtually unbreakable, chemically resistant plastics. Combination : A sleeve type reference electrode and a solid-state sensing element is incorporated into a single electrode body. Flush clean design - reduce time in cleaning and maintainance. Laboratory practice Problems 1. If electrodes function properly in buffers and standards but not in sample, it may be adversely affected by substances in the sample (interferences). Consult electrode instruction manual for more info. 2. If you get an "off scale" or "over range" reading on meter, it could be that the electrode is not properly connected to the meter, an abrazed cable, or the electrode is not immersed into the measuring solution. olarity to ppm The molecular weight of a species is equal to the concentration in ppm at 10-3. For example, Fluoride has a molecular weight of 19. Hence, a 10-3 concentration is equal to 19 ppm. See Electrode Conversion Factors (Table III).

Storage Put ph electrodes in ph buffer 7 storage solution when not in use, and put ion selective electrodes in a 0.1 solution of the respective ion of the electrode. Store a fluoride electrode in 0.1 sodium fluoride solution when not in use. Try to avoid storing electrodes in distilled water because the filling solution will be diluted and the electrode response will be slow. ph sensing electrode Fill reference chamber with filling solution, cover fill hole, and put protective cap containing a few drops of storage solution over sensing element. Ion selective electrode Drain electrode, rinse internal chamber with distilled water and store dry with protective cap covering sensing element. Sodium electrode Do not store sodiun ISE in water or air. Keep electrode in 10-2 sodium standard. For long term storage, rinse electrode with sodium standard and store dry with protective cap covering sensing element. Technique Rinse electrodes in deionised water between measurements to prevent contamination by carry over on the electrode, but do not wipe the ph glass electrode bulb because transfer of static charge onto the glass bulb will result in slow or drirty response. Also, do not wipe the liquid membrane tip or surface of an ion selective electrode which may cause damage or contamination to the sensing element. Remove fill hole cover in ph electrodes during calibration and measurement to ensure a uniform flow of electrode filling solution. Fill electrode filling chamber with electrode filling solution. The filling solution level should be about 1 inch above sample heihght in beakar. Cover fill hole after use and during storage. Use a magnetic stirrer at uniform speed to stirr standards and samples in order to get representative measurement and improved electrode response time. Temperature To account for ph slope, buffer and sample changes due to temperature, an ATC probe must be used. For ion selective electrodes, calibration and measurement should be done at the same temperature, and ISA buffers added to both standards and samples. Calibration Calibration verifies electrode slope and proper function of the meter. For ph, calibrate with 2 or 3 buffers or standards that bracket the expected sample range. Use ph buffers 4 and 7 or 9. ISE standards should be made up in decade series of concentration e.g. 10-2, 10-3, 10-4 standards of the electrode species of interest. You should have an estimate of the values for the samples you are analysing in order to prepare a relevant calibration range, which will bracket the sample values. A reading of about 56 V per decade concentration is optimal for monovalent ions, and about 28 mv for divalent ions. Calibrate once a day with 2 to 4 standards. Always use fresh standards and buffers. ph buffers may absorb CO 2 from the air causing shift in ph value. ISE standards may become contaminated or prepared wrongly. ISE atrix effects atrix effects are eliminated by adding a few mls. of a recommended ionic strength adjuster (ISA) to both standards and samples before measurement. The ISA "swamps out" differences in sample ionic strength and makes the ionic strength of samples and standards about the same.

ISE ethods ISE can measure the ion concentration of samples at very high values ( > 1000 ppm) to very low levels ( < 1 ppm) Direct analysis Sample electrode potentials (v) are compared to that of standards, having added ionic strength adjusters (ISA) to both standards and samples. However the V/ION eter must first be calibrated with at least three standards and concentration read from a calibration curve of concentration vs V. Concentrations can also be read out directly from the meter in any concentration unit such as molarity, ppm, or percentage. Incremental methods These are spiking techniques, adding stadard to sample, or sample to standards. These are standard addition or known addition (KA), known subtraction or standard subtraction (KS), sample addition or analate addition (AA), sample subtraction or analate subtraction (AS). A 1 : 100 ratio of standard to sample ratio is optimal. For a monovalent electrode, the standard addition should result in a 15-30 mv change. For a divalent electrode, a 7-10 mv change is acceptable. However, for incremental methods, certain inputs must be given in order to get a direct readout from the meter. For example, the required inputs for a 50 ml volume sample in know addition is: Slope =58 mv Sample volume = 50 ml Standard volume = 10 ml ISA volume = 50 ml Standard concentration = 100 ppm The meter (Accumet AR-50) will prompt you through the method to enter the appropriate parameters at the appropriate time. These techniques are summarized in Table I below. Table I Incremental ethods Parameter Does electrode directly sense species being analysed Does electrode sense standard species Solution in which initial electrode potential is measured Increment used Solution in which final electrode potential is measured Known addition Known subtraction Yes Yes Yes Yes No. Standard precipitates or complexes sample species Known volume of sample solution (typically 100 ml) Known volume of standard solution (typically 1 to 10 ml) 100 x to 10 x expected sample concentration Sample solution plus standard solution Analate addition Yes Analate subtraction No. Sample species pecipitates or complexes standard species Yes Known volume of standard solution (typically 100 ml) 0.01 x to 0.1 x expected sample concentration Known volume of sample solution (typically 1 to 10 ml) Standard solution plus sample solution

ISA and Filling solutions Always use the recommended ISA and Filling solutions for a given ion selective electrode. See Table II below. Volumes of ISA to be used For Fluoride and silver electrodes: Add 50 ml ISA to 50 ml volume sample and standard. For Nitrite and Carbon dioxide electrodes, add 10 ml ISA to 100 ml sample and standard. For all other electrodes: Add 2 ml ISA to 100 ml sample and standard. Table II ISE Filling solutions and Ionic strength adjusters Electrode Concentration range ph range Filling soln Buffer/ISA Ammonia Calcium Chloride Fluoride Nitrate Potassium Silver Sulphide Sodium 1.0 to 5 x 10-7 17000 to 0.01 ppm 1.0 to 5 x 10-7 40,100 to 0.02 ppm 1.0 to 5 x 10-5 35,500 to 1.8 ppm saturated to 10-6 saturated to 0.02 ppm 1.0 to 7 x 10-6 14,000 to 0.01 ppm 1.0 to 10-6 39,000 to 0.01 ppm 1.0 to 10-7 107,900 to 0.01 ppm as Ag+ 1.0 to 10-7 32,100 to 0.003 ppm as S-- saturated to 10 6 saturated to 0.02 ppm 11-13 6-8 2-11 5-8 3-10 3-10 2-9 13-14 9-10 0.1 NH 4 Cl 0.5349 g/100 ml 0.1 KCl 0.7455 g/100 ml 0.4 NH 4 SO 4 0.5286 g/100 ml 0.1 NaCl 0.5844 g/100 ml 10 NaOH 400 g/l 1 KCl 74.55 g/l 5 KNO 3 424.97 g/l TISAB 2 (NH 4 SO 4 ) 2 264.28 g/l 1 NaCl 58.44 g/l 5 KNO 3 424.97 g/l SAOB 1 NH 4 OH 35 mls/l SPECIAL ISE BUFFERS TISAB II (Total ionic strength adjuster) Used for low level F (-), < 0.4 ppm (2 x 10-5 ) Salt required is CDTA:trans 1,2, diaminocyclohexane N,N,N1,N1-tetra acetic acid, also known as cyclohexylene dinitro tetra acetic acid, or cyclohexylenediamine tetra acetic acid): C 6 H 10 {N(CH 2 CO 2 H) 2 } 2.xH 2 O: FW = 364.34 Dissolve 4 g CDTA, together with 57 mls glacial acetic acid and 58 g NaCl in about 500 mls distilled water, and using a ph meter, adjust to between 5 and 5.5 ph by adding 5 NaOH (200 g/l) and dilute to 1 liter with distilled water (about 130 mls NaOH). TISAB III Dissolve 300 g sodium citrate.2h 2 O (FW=294.10), 22 g CDTA, and 60 g NaCl in 1 liter water. Use 10% buffer per volume standard and sample. (add 5 ml TISAB III to 50 ml volumes of standard and sample). TISAB IV Complexes more than 100 ppm iron or aluminium in presence of 1 ppm F (-) Dissolve 84 ml conc. HCl, 242 g TRIS (hydroxymethyl aminomethane, and 239 g sodium tartrate (FW=230.08), in about 500 mls water, cool, and transfer to 1 liter volumetric flask and make up to mark. Use a 1 :1 volume to standard and sample.

An alternative preparation for TISAB. Dissolve 58.44g NaCl, 61.50g sodium acetate, 0.29g sodium citrate and 15 ml acetic acid in 1 liter distilled water. SAOB (Sulphide Anti-oxidant Buffer.) (Salt required is ascorbic acid FW = 176.12; 0.2 in 2 NaOH). Dissolve 36 g ascorbic acid and 80 g NaOH in one about 600 mls distilled water, add 67g disodium EDTA, stir, and make up to 1 liter. Discard and make fresh solution when color changes to brown. The ascorbic acid retards air oxidation of species being measured, makes the solution basic for measurement, and adjusts the ionic strength. Use a 1 : 1 ratio of sample and standard to SAOB. Table III Conversion Factors: olarity and ppm See also : ppm conversions Electrode Species 10-3 1 ppm Electrode Species 10-3 1 ppm Aluminium 27.0 ppm 3.7 x 10-5 Fluoride 19.0 ppm 5.2 x 10-5 Ammonia 17.0 ppm 5.9 x 10-5 Hardness, as CaCO 3 Ammonia, as N 14.0 ppm 7.1 x 10-5 Iodide 127 ppm Ammonium 18.0 ppm 5.6 x 10-5 Lead 207 ppm 100 ppm 1.0 x 10-5 0.79 x 10-5 0.48 x 10-5 Boron 10.8 ppm 9.3 x 10-5 agnesium 24.3 ppm 4.1 x 10-5 Bromide 79.9 ppm 1.3 x 10-5 ercury 200 ppm Cadmium 112.0 ppm 0.89 x 10-5 Nickel 0.50 x 10-5 58.7 ppm 1.7 x 10-5 Calcium 40.1 ppm 2.5 x 10-5 Nitrate 62.0 ppm 1.6 x 10-5 Calcium, as CaCO 3 100 ppm 1.0 x 10-5 Nitrate, as N 14.0 ppm 7.1 x 10-5 Carbon dioxide 44 ppm 2.3 x 10-5 Perchlorate 99.5 ppm 1.0 x 10-5 Carbonate, as CaCO 3 Chloride Chlorine 100 ppm 2.8 x 10-5 Potassium 39.1 ppm 2.6 x 10-5 35.5 ppm 2.8 x 10-5 70.9 ppm 1.4 x 10-5 Silver Phosphorus, as P 2 O 5 70.9 ppm 1.4 x 10-5 107.9 ppm 0.93 x 10-5 Chromium 52.0 ppm 1.9 x 10-5 Sodium 23.0 ppm 4.4 x 10-5 Chromium, as CrO 4 = 116 ppm 0.86 x 10-5 Sulphate 96.1 ppm 1.0 x 10-5 Cobalt 58.9 ppm 1.7 x 10-5 Sulphide 32.1 ppm 3.1 x 10-5 Copper 63.5 ppm 1.6 x 10-5 Sulphur dioxide 64 ppm 1.6 x 10-5 Cyanide 26.0 ppm 3.8 x 10-5 Zinc 65.4 ppm 1.5 x 10-5