1. Introduction:
1.1 Scope
This method
describes the collection and analysis of airborne tellurium. It is
applicable for both ceiling (c) and time- weighted averages (TWA)
exposure evaluations.
The analysis is based on the
utilization of a graphite furnace.
1.2
Uses
Tellurium is used as a coloring agent in chinaware,
porcelains, and glass. It is a reagent in producing a black finish
on silverware. it is used as a rubber improver; in tellurium vapor
"daylight" lamps; in cast iron, where minute amounts stabilize the
iron carbide and appreciably increase the depth of the chill. Tellurium
is a p-type semiconductor, and shows greater conductivity in certain
directions, depending on alignment of the atoms. Its conductivity
increases slightly with exposure to light. Tellurium is used in
ceramics. Bismuth telluride has been used in thermoelectric devices. One
such device, using two Bi-Te semiconductors, is reportedly capable of
freezing or boiling water in seconds with the power from two flashlight
batteries. The unit is said to be capable of bringing the temperature
down to -75°C, using only two amperes of current. The gray iron
industry uses hundreds of tons annually, a considerable amount being for
hardening the surface of car wheels. It is also used in malleable iron
to improve ductility and in stainless steel for machinability.
A fraction of 1 per cent alloyed with lead improves the
corrosion resistance, strength, and hardening properties of the
lead. Tellurium is used to increase the machinability of copper and
bronze, and to improve other metals and alloys. It is also used in
several chemical processes, including use as a catalyst.
1.3
Physical and chemical processes
Crystalline tellurium has a
silvery white appearance, and, when pure, exhibits a metallic luster. It
is brittle and easily pulverized. Amorphous tellurium, is formed by
precipitating tellurium from a solution of telluric or tellurous acid.
Whether this form is truly amorphous or trade of minute crystals is open
to question. In air, tellurium burns with a greenish-blue flame forming
the dioxide. See Table 1.
TABLE
I
|
|
Form I
|
Form II
|
| molecular formula |
Te |
Te |
| molecular weight (g/mole) |
127.60 |
127.60 |
| color/crystalline form |
brown black |
rhombic silver |
|
amorphous |
white met |
| index of refraction |
1.0025 |
1.0025 |
| specific gravity |
6.00 |
6.25 |
| melting point (°C) |
449.5 |
452 |
| boiling point (°C) |
1390 |
339 |
Solubility (g/100 ml)
|
|
|
| cold water |
insoluble |
insoluble |
| hot water |
insoluble |
insoluble |
| H2SO4 |
insoluble |
insoluble |
| HNO3 |
soluble |
soluble |
| aqua regia |
soluble |
soluble |
| KCN |
soluble |
soluble |
| KON |
soluble |
soluble |
| HC1 |
insoluble |
insoluble |
| CS2 |
insoluble |
insoluble | 2. Range and Detection Limit:
A lower
analytical limit, 0.4 µg/ml, was selected for routine
analysis.
3. Interferences:
None known
4.
Sampling Procedure
4.1 The sample is collected on a 0.8 µm AA cellulose
membrane filter using a flow rate between 1.5 and 2.0 liters per
minute. Suggested minimum air volume is 100 liters. A sample blank
should also be submitted. (If considerable loose dust is present in the
cassette, a clear. filter should be placed over the dust before
sealing).
4.2 The sample cassettes are plugged, sealed with
OSHA tape, labeled, and sent to the laboratory for
analysis.
4.3 No storage problems are normally anticipated.
Vibration or jolting of samples should be kept to a minimum to avoid
dislodging of dust from the filter.
5. Analytical
Procedure:
5.1 Apparatus
Atomic absorption
spectrophotometer equipped with graphite furnace, argon purge system,
and deuterium arc background corrector.
Chart
recorder.
Glassware.
2 or 3 piece filter
cassettes
AA filters (0.8 µm, cellulose membrane filters
37-mm dia)
Personal sampling pump (capable of sampling
between 1.0 and 2.0 L/pm).
5.2
Reagents
HCl, reagent grade
HNO3,
reagent grade
A certified aqueous standard such as "SPEX'
1,000 ppm standard follows:
1,000 ppm Ni solution
Diluting solution:
Twenty AA filters are ashed with 100 mL concentrated
HN03 and 100 mL of 1,000 ppm Ni solution to a volume of 20
- 40 mL, diluted to 500 mL with deionized water and 2 mL
HCl.
5.3 Standards
Preparation
Standards are prepared to match the matrix of
the samples (filter content acid and nickel concentration) as closely as
possible according to the dilution scheme of Table III.
The
0.2. 1, 2, 5. 10 and 20 ppm "stock solutions" are made by serial
dilution of the 1,000 ppm stock (with deionized water) as
5.4
Sample Preparation
Note: All Glassware must be rinsed with
1:1 HNO3 and deionized water prior to use. Conical
beakers used for the digestion are refluxed with 1:1 nitric acid and
rinsed with deionized water before use.
Place filter in 125
mL conical beaker, add 5 ml of 1000 ppm Ni solution and 5 ml
concentrated NHO3 and ash to approximately 1-2 ml volume. After sample
has cooled, add 2 drops HCl and swirl contents (no additional heating is
done).
Quantitatively transfer sample to 25 mL volume
flask, dilute to volume with deionized water, and mix. Additional
dilutions for samples over 2 ppm As are made with the diluting
solution.
TABLE II: STOCK
SOLUTIONS
|
STOCK SOL'N
|
SOL'N USED
|
M1 USED
|
M1 FINAL VOL
|
| 20 ppm |
|
1000 ppm stock |
|
2 |
|
100 |
| 10 ppm |
|
100 ppm stock |
|
10 |
|
100 |
| 5 ppm |
|
100 ppm stock |
|
5 |
|
100 |
| 2 ppm |
|
100 ppm stock |
|
2 |
|
100 |
| 1 ppm |
|
10 ppm stock |
|
10 |
|
100 |
| 0.2 ppm |
|
10 ppm stock |
|
2 |
|
100
|
The
diluted stock solutions should be prepared just before using them to
prepare the working standards as outlined in Table
III.
When preparing the working standards from the stock
solutions, all dilutions are made with the diluting
solution.
| TABLE III:
WORKING STANDARDS |
|
|
|
|
Standard
|
Stock
Sol'n used
|
mL
stock
|
H1 Final Vol.
|
| 0.1 ppm |
|
1.0 ppm |
|
5 |
|
50 |
|
| 0.2 ppm |
|
2.0 ppm |
|
5 |
|
50 |
|
| 0.5 ppm |
|
5.0 ppm |
|
5 |
|
50 |
|
| 1.0 ppm |
|
10.0 ppm |
|
10 |
|
100 |
|
| |
|
|
|
| Wavelength: 214.3 nm |
*Tellurium Conditions
|
| Slit 3 |
|
Dry= 90T, 50R, 40H,
150F |
|
|
Char= 500T, 50R, 30H,
100F |
|
|
Atomize= 2000T, Fr. 8H,
15F |
|
|
Chart= Range 10 |
|
|
EDL Power= 9 watts |
|
|
(Stds prepared same as
As) |
|
|
*These are guidelines
parameters and may differ from your
own. |
5.5 Sample
Analysis
The analysis for tellurium is performed using a
graphite furnace.
Instrumental parameters are as
follows:
Atomic absorption
unit:
|
Chart recorder:
|
| EDL wavelength: 214.3 nm |
10 mV range |
| UV mode |
20 mm/min speed |
| slit setting 3 |
SERVO function |
| Absorbance function |
|
| Repeat mode |
|
| D2 Background
ON |
|
| |
|
|
Temperature
programs
|
|
| Dry: |
90° temp |
|
|
50 sec ramp time |
|
|
40 sec ramp time |
150 ml/min INT flow |
| Char: |
500 temp |
|
|
50 sec hold time |
|
|
30 sec hold time |
100ml/min INT flow |
| Atomize: |
2000°
temp |
|
|
0 sec ramp time |
|
|
8 sec ramp time |
15 mL/min INT flow |
|
|
|
Injection volume: 10 µL
The 1.0 ppm standard
should give a near full scale deflection using these conditions.
The entire series of standards should be run at the beginning and
the end of the analysis. A standard should be run after every
fourth or fifth sample in the sample rings.
5.6
Calculations
A linear regression of standard ppm vs
standard peak height is performed using the OSHA Automatic AA program.
The sample results are calculated based on sample peak heights; a
function of sample absorption.
| mg/m³ = |
(ppm Te*) sample volume, mL)
(Dilution factor)
air volume, liters
|
*blank corrected
|
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