Zinc – LaMotte DC1600 Colorimeter User Manual

Page 89

ZINC

ZINCON METHOD

CODE 3667

QUANTITY

CONTENTS

CODE

30 mL

*Zinc Indicator Solution

*6314-G

100 mL

*Methyl Alcohol

*6319-J

10 g

Sodium Ascorbate Powder

6316-D

25 g

*Zinc Buffer Powder

*6315-G

15 mL

*Sodium Cyanide, 10%

*6565-E

30 mL

*Formaldehyde Solution, 37%

*5128-G

“Dilute Zinc Indicator Solution”

0128-MT

Bottle, with 1 mL pipet assembly

Graduated Cylinder, 10 mL, glass

0416

Spoon, 0.5 g, plastic

0698

Pipets, plain, plastic

0352

Spoon, 0.1 g, plastic

0699

*WARNING: Reagents marked with a * are considered hazardous substances. Material Safety Data Sheets (MSDS) are supplied for

these reagents. For your safety, read label and accompanying MSDS before using.

Zinc enters the domestic water supply from the deterioration of galvanized iron and brass pipes, and from industrial wastes.

Zinc is an essential element for body growth and development and is an important plant nutrient. Concentrations of zinc

above 5.0 mg/L in drinking water can cause a bitter astringent taste. In the U.S., zinc concentrations may vary between

0.06 to 7.0 mg/L, with an average value of 1.33 mg/L.

APPLICATION:

Drinking and surface waters, domestic and industrial waste water.

RANGE:

0.0 – 3.0 ppm Zinc

METHOD:

Zinc forms a blue colored complex with Zincon in a solution buffered at pH 9.0. Other heavy

metals are complexed by cyanide and the zinc cyanide complex is released by the addition of

formaldehyde before the other metal cyanide complexes are destroyed. Sodium ascorbate is

added to reduce the interference of manganese.

SAMPLE HANDLING

& PRESERVATION:

Sample should be analyzed within 6 hours after collection. The addition of hydrochloric acid

will help preserve the metal ion content, however the acid should be neutralized before

analysis.

INTERFERENCES:

The following ions interfere in concentrations greater than those listed.

ION

mg/L

Cd(II)

Al(III)

Mn(II)

Fe(III)

Fe(II)

Cr(III)

Ni(II)

Cn(II)

CrO

(II)