3B Scientific Teltron Luminescence Tube D User Manual
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3. Technical data
Filament voltage:
6.3 V AC/DC (8.0 V max.)
Filament current:
1.8 A typical at U
F
= 6.3 V
Anode voltage:
2000 - 5000 V DC
Anode current:
180 µA typical at
U
A
= 4000 V
Screen current:
100 µA typical at
U
S
= 4000 V
Glass bulb:
130 mm diam. approx.
Total length:
260 mm approx.
Luminescence screen:
5.1: fluorescent blue, approx. 450 nm, me-
dium decay time
5.2: fluorescent red, approx. 625 nm, me-
dium short decay time
5.3: fluorescent green, approx. 510 nm fluo-
rescent, approx. 515 nm phosphorescent,
long decay time
4. Operation
To perform experiments using the luminescence
tube, the following equipment is also required:
1 Tube holder D
1008507
1 High voltage power supply 5 kV (115 V, 50/60 Hz)
1003309
or
1 High voltage power supply 5 kV (230 V, 50/60 Hz)
1003310
1 Analogue multimeter AM51
1003074
1 High-pressure mercury vapour lamp 1000852
Spectrum tube power supply (115 V, 50/60 Hz)
1003195
or
Spectrum tube power supply (230 V, 50/60 Hz)
1003196
1 Infra-red light source
Additionally recommended:
Protective Adapter, 2-Pole
1009961
4.1 Setting up the tube in the tube holder
•
The tube should not be mounted or removed
unless all power supplies are disconnected.
•
Push the jaw clamp sliders on the stanchion
of the tube holder right back so that the jaws
open.
•
Push the bosses of the tube into the jaws.
•
Push the jaw clamps forward on the stan-
chions to secure the tube within the jaws.
•
If necessary plug the protective adapter onto
the connector sockets for the tube.
4.2 Removing the tube from the tube holder
•
To remove the tube, push the jaw clamps
right back again and take the tube out of the
jaws.
5. Example experiments
5.1 Excitation by cathode ray bombardment
•
To better observe the afterglow effects
(phosphorescence), carry out the the last
step of the experiment in a darkened room.
•
Set up the luminescence tube as shown in
fig.1.
•
Connect both the screens and the anode to
earth for maximum safety.
•
Set the voltage U
A
to about 3500 V.
•
Observe the luminescence.
The three phosphors fluoresce at different wave-
lengths (colours).
•
Vary the voltage between 2000 V and 4000 V.
•
Observe the change of the luminous phe-
nomenon.
While the intensity of the fluorescence varies
with the voltage, wavelength does not.
•
With U
A
at 4000 V use a hand held spectro-
scope to view the emissions from each
phosphor.
Note that the emission from the red phosphor
comprises a number of discrete emission lines.
•
Switch off the power supply and observe the
afterglow (phosphorescence).
The removal of the source of thermionic bom-
bardment causes luminescence to cease. The
decay of emission from the phosphors is particu-
larly apparent on the green phosphor.
5.2 Excitation by ultra-violet light
•
Carry out the experiment in a darkened
room.
•
Set up the luminescence tube as shown in
fig.2.
•
Do not switch on the power supply.
Note that there is no visible photoluminescence
due to the ambient light levels.
•
Illuminate the gun side of the screen with
ultra-violet light and note the initial time de-
pendency of emission intensity.
The three phosphors fluoresce at the same
wavelength as when excited by cathode ray
bombardment.
•
Vary the intensity of the ulta-violet light, ei-
ther by changing the distance between the
light source and the phosphor, or by inter-
posing suitable filters.
While the intensity of the fluorescence varies
with the intensity and energy of the exciting ra-
diation, wavelength does not.
•
Remove the ultraviolet light and observe the
afterglow (phosphorescence).
The decay characteristic of the green phosphor
appears longer than was observed after removal
of cathode ray bombardment. The reason for
this is that the phosphorescence of this material
is quenched by infra-red radiation. When the
filament supply is switched off there remains