3B Scientific Teltron Perrin Tube S User Manual

2

3. Technical data

Filament voltage: ≤ 7.5 V AC/DC
Anode voltage:

2000 V to 5000 V

Anode current:

typ. 0.18 mA at U

A

= 4000 V

Beam current:

4 µA at U

A

= 4000 V

Plate voltage:

50 to 350 V

Glass bulb:

130 mm dia. approx.

Total length:

260 mm approx.

4. Operation

To perform experiments using the Perrin tube,

the following equipment is also required:
1 Tube holder S

1014525

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 Helmholtz pair of coils S

1000611

1 DC Power Supply 20 V, 5 A (115 V, 50/60 Hz)

1003311

or

1 DC Power Supply 20 V, 5 A (230 V, 50/60 Hz)

1003312

1 Electroscope

1001027

1 Analogue multimeter AM50

1003073

4.1 Setting up the tube in the tube holder

The tube should not be mounted or removed

unless all power supplies are disconnected.

•

Press tube gently into the stock of the holder

and push until the pins are fully inserted. Take

note of the unique position of the guide pin.

4.2 Removing the tube from the tube holder

•

To remove the tube, apply pressure with the

middle finger on the guide pin and the thumb

on the tail-stock until the pins loosen, then

pull out the tube.

5. Example experiments

5.1 Evidence of the particle nature of cath-

ode beam and establishment of their po-
larity

•

Set up the experiment as in fig. 1.

•

Apply a voltage to the anode between 2 kV

and 5 kV.

On the fluorescent screen the cathode beams

are visible as a round spot.

•

Slowly increase the coil current until the

electron beam is deflected into the Faraday

cage. If necessary, reverse the direction of

the coil current and turn the tube in the tube

holder so that the beam alls within the end

of the Faraday cage.

The electroscope will open to indicate the pres-

ence of a charge.

•

Turn off the voltage to the heater filament

and the anode.

The electroscope remains open.
If the charge on the Faraday cage were due to

the cathode beam being some kind of wave

radiation, the charge should disappear when the

filament ceases to radiate. Because the experi-

ment shows that the charge remains on the

cage when the filament is cold, the conclusion

must be that the beam comprises some con-

stituent of matter which is electrically charged.

These particles are called electrons.
The negative polarity of the cathode beam can be

demonstrated if the electroscope is charged by

rubbing a plastic or a glass rod (so that they are

negatively and positively charged respectively).

5.2 Estimation of the specific electron char-

ge e/m

•

Set up the experiment as in fig. 3.

When the electron beam is deflected into the

Faraday cage, the following applies to the spe-

cific charge e/m:

(

)

2

2

r

B

U

m

e

A

⋅

⋅

=

(1)

U

A

can be read out directly, the curvature radius r

derives from the geometric data of the tube (bulb

diameter 13 cm, Faraday cage at 45° to the

beam axis) to r = 16 cm approx. (refer to fig. 2).
With the coils at Helmholtz-geometry and the

coil current I, the following applies to the mag-

netic flux density B of the magnetic field

I

k

I

R

n

B

⋅

=

⋅

⋅

μ

⋅

⎟

⎠

⎞

⎜

⎝

⎛

=

0

2

3

5

4

(2)

with k = at good approximation 4.2 mT/A, n = 320

(no. of turns) and R = 68 mm (coil radius).

•

Substitute U

A

, r and B in equation 1 and

calculate e/m.

5.3 Deflection in crossed magnetic alternat-

ing fields (Lissajous figures)

The following equipment is also required:
1 Auxiliary coil

1000645

1 AC/DC power supply 12 V, 3 A (115 V, 50/60 Hz)

1002775

or

1 AC/DC power supply 12 V, 3 A (230 V, 50/60 Hz)

1002776

1 Function generator FG100 (115 V, 50/60 Hz)

1009956

or

1 Function generator FG100 (230 V, 50/60 Hz)

1009957

•

Set up the experiment as in fig. 5.

•

Place the auxiliary coil on the tube holder as

in fig. 4.