-
rc3 prerol music
-
Herald: All right, fellow creatures, to be
honest, I never thought that I would be
-
introducing a talk on measuring
radioactivity like ever in my life, but
-
then again, considering the world stage,
current state at large, it might be not
-
such a bad idea to be prepared for these
things. Right? And gladly, our next
-
speaker, Oliver Keller, is an expert in
detecting radioactive stuff. Oliver is a
-
physicist and works at one of the most
prominent nerd happy places. The CERN
-
since 2013 is also doing a PhD project
about novel instruments and experiments on
-
natural radioactivity at the University of
Geneva and to even more to add even more
-
C3 pizzazz. Oliver is active in the open
science community and passionate about
-
everything open source. All that sounds
really cool to me. So without further ado,
-
let's give a warm, virtual welcome to
Oliver and let's hear what he has to say
-
about measuring radioactivity with using
low cost silicon sensors. Oliver, the
-
stream is yours.
-
Oliver: Thanks. That was a very nice
introduction. I'm really happy to have the
-
chance to present here. I'm a member since
quite some years and this is my first CCC
-
talk, so I'm quite excited. Yeah, you can
follow me on Twitter or I'm also on
-
Mastodon, not so active, and most of my
stuff is on GitHub. OK, so what will we
-
talk about in this talk? I'll give you a
short overview, also about the
-
radioactivity, because yeah, it's a topic
with many different details and then we
-
will look at the detector more in detail
and how that works in terms of the physics
-
behind it and the electronics. And then
finally, we look at things that can be
-
measured, how the measurement actually
works, what are interesting objects to
-
check and how this relates to silicon
detectors being used at CERN. So the
-
project is on GitHub called DIY Particle
Detector. It's an electronic design, which
-
is open hardware. There's a wiki with lots
of further details for building and for
-
troubleshooting. There is a little web
browser tool I will show later, briefly,
-
and there are scripts to record and nicely
plot the measurements. Those scripts are
-
BSD-licensed and written in Python. There
are two variants of this detector. One is
-
called electron detector, the other one
alpha spectrometer. They use the same
-
circuit board, but one is using four
diodes, the other one one photodiode...
-
There's a small difference between them,
but in general it's pretty similar. But
-
the electron detector is much easier to
build and much easier to get started
-
using. Then you have complete part lists
and even a complete kit can be bought on
-
kitspace.org, which is an open hardware
community repository, and I really
-
recommend you to check it out. It's a
great community platform and everyone can
-
register their own GitHub project quite
easily. Now, this is a particle detector
-
in a tin box, so you can use the famous
Altoids tin box or something for Swiss
-
chocolate, for example. You can see it's
rather small, the board about the size of
-
a nine volt block battery. And then you
need, in addition, about 20 resistors,
-
capacitors and these silicon
diodes plus an operational amplifier,
-
which is this little chip here, this
little black chip here on the right side,
-
you can see is all old school large
components. This is on purpose, so it's
-
easy to soldier for complete electronic
beginners. And this by the way, this
-
picture is already one user of this
project who posted their own build on
-
Twitter. OK, so natural radioactivity. So
I would say it's a story of many
-
misconceptions. Let's imagine we are this
little stick figure here on the ground.
-
Below us we have uranium and thorium. We
also have Potassium-40 in the ground and
-
Potassium-40 is is pretty specific and
peculiar. It actually makes all of us a
-
little bit radioactive. Every human has
about 4000 to 5000 radioactive decays
-
every second because of the natural
potassium and natural potassium comes with
-
a radioactive isotope, which is just
everywhere, it's in bananas. But it's also
-
in us because we need it for our body
chemistry. It's really important and even
-
some of those decays are even
producing anti-matter. So how cool is
-
that? OK, so what would we be measuring on
the on ground? Well, there could be some
-
gamma rays or electrons. Those are from
beta-decays. Or from the Uranium, there is
-
one radionuclide appearing in the decay
chain, which is called Radon, and Radon is
-
actually a gas. So from the ground the
Radon can diffuse upwards and travel with
-
air and spread around. So it's a bit like
a vehicle for radioactivity from
-
the ground to spread to other places. And
that Radon would decay with alpha
-
particles producing electrons and beta-
decays and also gamma radiation further
-
down in the decay chain. So just to
recapitulate, I've said it already twice,
-
so alpha particles are actually helium
nuclei, so it's just two protons and two
-
neutrons and the electrons are missing.
And in beta decay basically one neutron is
-
transformed into a proton and an electron.
And there's also an electron-anti-neutrino
-
generated. But this is super hard to
measure. So we're not measuring those.
-
Mostly we will be measuring electrons from
beta-decays. That's why you see all these
-
little e's indicating betadecays. Ok, if
you would go to the hospital here on the
-
left side, we would probably find some x
rays from checking our bones or something
-
like this, or even gamma rays or alpha
particles being used in treatments or very
-
modern even proton beams are sometimes
generated for medical applications. Now,
-
here on the right side, if you go close to
a nuclear power plant, we probably measure
-
nothing unless there's a problem in this
case, most likely we would find some gamma
-
radiation. But only if there is a problem.
OK, and then actually that's not the whole
-
story. This is terrestrial radiation. But
we also have radiation coming from
-
upwards, showering down on us every
minute, and there's actually nothing we
-
can do against it. So protons are
accelerated from in the universe.
-
Basically, the biggest particle
accelerator nature has. And once they hit
-
our atmosphere they break apart into less
energetic particles and it's many of them.
-
So in the first stage there's lots of pions
generated and also neutrons. But neutrons
-
are really hard to measure, so I'll ignore
them for most of the talk. Then those
-
pions can decay into gamma rays and then
trigger a whole chain of positron electron
-
decays, which again create gamma rays and
so forth. And this goes actually the whole
-
way down to the earth. We will have a
little bit of that on the sea level.
-
And the other more known part of
atmospheric radiation is actually muons.
-
So some pions decay into muons, which is
kind of a heavy electron and also
-
neutrinos. But neutrinos are, again, very
hard to measure. So I'll ignore them for
-
most of this talk. And if you look here on
the right side on this altitude scale,
-
you'll see an airplane would be basically
traveling where most of the atmospheric
-
radiation is produced. And this is why if
you go on such an airplane, you have
-
actually several times more radiation
in there than here on earth. And, of
-
course, on the ground, it also depends
where you are. There are different amounts
-
of uranium and thorium in the ground and
this is just naturally there. So but it
-
depends on the geology, of course. OK, so
I've talked quite a bit about radiation,
-
and I'm saying I want to use silicon to
detect it. So what radiation exactly?
-
Maybe. Let's let's take a step back and
think about what we know maybe from
-
school. So we have this rainbow for
visible light. Right. This is in terms of
-
wavelength. We have 800 to 400 nanometers
spanning from the infrared/red area to all
-
the green to blue and into the violet. And
lower down those wavelengths or let's say
-
bigger millimeter waves, meter waves and
even kilometer, that would be radio waves,
-
radio frequencies for our digital
communication systems, wi-fi, mobile
-
devices and so forth. But I want to look
actually more towards the right because
-
that's what we are measuring with these
detectors. It's shorter wavelength, which
-
actually means higher energy. So on the
right side, we would be having ultraviolet
-
radiation, which is kind of at the border
to what we can measure. And these 800 to
-
400nm translate into 1.5 to 3 eV, which is
a unit that particle physicists really
-
prefer because it basically relates the
energy of an electron after it has been
-
accelerated by 1 Volt and makes it
much easier to work with nuclear
-
particle physics, because everything, all
the energy is always related to an
-
electron. And this energy, this formula
here is just a reminder that the
-
wavelengths can be always converted into
energy and it's inversely proportional. So
-
wavelength increases to the left and the
energy to right. And if you increase
-
energy more from from the visible range,
so let's say thousands of electron volts,
-
then we arrive here. Millions - mega
electron volts, even GeV. And there is now
-
a pretty important distinction between
those two areas, and that is the right one
-
is ionizing radiation and the left one is
non ionizing radiation. UV is a little bit
-
in the middle of that. So some parts of
the UV spectrum can be ionizing. It also
-
depends a lot on the material that the
radiation is interacting with. For these
-
detectors I'm talking about today and
alpha, beta, gamma radiation, this is all
-
ionizing, so some examples, lowest energy
on the lower spectrum would be x rays than
-
electrons, gamma rays from radioactive
nuclides that already talked about in the
-
previous slide, alpha particles, and that
muons from the atmosphere would be more on
-
the GeV range and so forth. And for these
higher energies, of course, you need
-
something like the LHC to accelerate
particles to really high energies. And
-
then you can even access the TeV regime.
OK, silicon diodes. What kind of silicon
-
diodes? I'm using in this project, low
local silicon pin diodes, one is called
-
BPW34 it's manufactured from Vishay or
Osram, costs about 50 cents. So that's what
-
I mean with low cost. There's another one
called BPX61 from Osram. It's quite a bit
-
more expensive. This is the lower one here
on the right. It has a metal case, which
-
is the main reason why it's more
expensive. But it's quite interesting
-
because that one we can use for the alpha
detector. If you look closely, there is a
-
glass on top, but we can remove that. We
have a sensitive area. So this chip is
-
roughly 7mm² large and it has a thickness,
a sensitive thickness of about 50
-
micrometer, which is not a lot. So it's
basically the half of the width of a human
-
hair. And in total, it's a really small,
sensitive volume. But it's it's enough to
-
measure something. And just as a reminder,
how much of gamma rays or X-rays we will
-
detect with this, not a lot because it's
high, energetic photon radiation kind
-
doesn't interact very well in any kind of
matter. And because a sensitive area is so
-
thin, it would basically permeate through
it and most of the times not interact and
-
doesn't make a signal. OK, what's really
important, since we don't want to measure
-
light, we have to shield light away. We
need to block all of the light, that means
-
easiest way to do it is to put it in a
metal case. There is electromagnetically
-
shielded and completely protected from
light as well. Electromagnetic radiation
-
or radiowaves can also influence these
detectors because they are super
-
sensitive. So this sould be a complete
Faraday cage, complete metal structure
-
around it. There's a lot of hints and tips
how to achieve that on the wiki on the on
-
the GitHub of this project. OK, let's
think about one of those PIN diodes,
-
normally there is one part in the
silicon which is n-doped
-
negatively doped, and the other part
usually, which is positively dropped. And
-
then you arrive at a simple so called p-n-
junction, which is a regular
-
semiconducting diode. Now, pin diodes add
another layer of so-called intrinsic
-
layer, here shown with the i. And that
actually is the main advantage. Why this
-
kind of detector works quite well and have
a relatively large sensitive Sigma's. So
-
if you think about, let's say, a photon
from an x ray or gamma-decay or an
-
electron hitting the sensor. So by the
way, this is a cross-section view from the
-
side, but that doesn't really matter. But
let's say they come here from the top into
-
the... into the diode and we're looking
at the side then we have actually
-
ionization because this is ionizing
radiation, so we get free charges in the
-
form of electron-hole pairs. So electrons,
which here the blue ball and the red
-
circle would be the holes. And depending
on the radiation kind, how this ionization
-
takes place is quite different, but the
result is if you get a signal, it means
-
there was ionization. Now, if just this
would happen, we could not measure
-
anything. Those charges would quickly
recombine and on the outside of the diode,
-
it would be a little signal. But what we
can do is we can apply actually a voltage
-
from the outside. So here we just put a
battery. So we have a positive voltage
-
here, a couple of volts. And then what
happens is that the electrons would be
-
attracted by the positive voltage and the
holes will travel to the negative
-
potential. And we end up with a little net
current or a small bunch of charges that
-
can be measured across the diode as a
tiny, tiny current. The sensitive volume
-
is actually proportional to the voltage,
so the more voltage we put, the more the
-
bigger is our volume and the more we can
actually measure with certain limits, of
-
course, because the structure of the pin
diode has a maximum thickness just
-
according how it is manufactured. And
these properties can be estimated with
-
C-V-measurements. So here you see an
example of a couple of diodes, a few of
-
the same type. The two that I've
mentioned, they're different versions. One
-
has a transparent plastic case. One has a
black plastic case. Doesn't really matter.
-
You see, basically in all the cases, more
or less the same curve. And as you
-
increase the voltage, the capacitance goes
down. So it's great and basically shows us
-
those silicon chips are very similar, if
not exactly the same chip. Those
-
differences are easily explained by
manufacturing variances. And then because
-
this actually, if you think about it, it
looks a bit like a parallel plate
-
capacitor and actually you can treat it as
one. And if you know the capacitance and
-
the size, the area, you can actually
calculate the distance of these two plates
-
or basically width or the thickness of the
diode. And then we arrive at about 50
-
micrometer, if you put something like 8 or
10 volts. OK, now we have a tiny charge
-
current, now we need to amplify it, so we
have a couple of diodes, I'm explaining
-
now the electron detector, because it's
easier. We have four diodes at the input
-
and this is the symbol for an operational
amplifier. There are two of those in the
-
circuit. The first stage is really the
special one. So if you have a particle
-
striking the diode, we get a little charge
current hitting the amplifier. And then we
-
have here this important feedback
circuit. So the output is fed back into
-
the input, which in this case makes a
negative amplification. And the
-
amplification is defined actually by this
capacitance here. The resistor has a
-
secondary role with the small capacitance.
It is what makes the output voltage here
-
large. The smaller the capacitance, the
larger the output and it's inverted. Then
-
in the next amplifier step, we just
increase the voltage again to a level that
-
is useful for using it later. But all of
the signal quality that has been
-
achieved in the first stage will stay like
that. So signal to noise is defined by the
-
first stage. The second one is just to
better adapt it to the input of the
-
measurement device that's connected. So
here, this is a classic inverting
-
amplifier with just these two resistors
define the amplification factor. It's very
-
simple. It's just a factor of hundred in
this case. And so if you think again about
-
the charge pulse and this, the circuit
here is sensitive, starting from about
-
1000 liberated charges in those diodes as
a result from ionization. We get something
-
like 320 micro Volt at this first output,
and this is a spike that quickly
-
decreases. Basically these capacitors are
charged and quickly discharged with this
-
resistor and this is what we see here. And
then that is amplified again by a factor
-
of 100. And then we arrive at something
like at least 32 mV, which is conveniently
-
a voltage that is compatible with most
microphone or headset inputs of computers
-
or mobile phones, so that the regular
headset here has these four connectors and
-
the last ring actually connects the
microphone. The other is ground and reft.
-
Left, right for the earbuds. OK, how do we
record those pulses? This is an example of
-
1000 pulses overlayed and measured on an
oscilloscope here. So it's a bit more
-
accurate. You see the deposits a bit
better, kind of like the persistence mode
-
of an oscilloscope. And the size of the
pulse is proportional to energy that was
-
absorbed. And the circuit is made in such
a way that the width of the pulse is big
-
enough such that regular sampling
frequency of a sound card can actually
-
catch it and measure it. Yeah, this is
Potassium Salt. This is cut here. This is
-
called a low salt in the UK. There is also
a german variance, you can also just buy
-
it in the pharmacy or in certain organic
food stores as a replacement salt.
-
On the right side is an example from this
small Columbite Stone, which has traces of
-
uranium on it. And this is measured with
the alpha spectrometer. And you see those
-
pulses are quite a bit bigger here. We
have 50 microseconds and here we have more
-
like one milliseconds of pulse width. Now
there's a software on a browser. This is
-
something I wrote using the Web Audio API
and it works on most browsers, best is
-
Chrome, on iOs, of course, you have to use
Safari and that records once you plug the
-
detector, it records from the input at 48
or 44.1kHz the pulses. Here's an example
-
with the alpha spectrometer circuit, you
get these nice large pulses. In case of
-
the electron detector the pulse is much
shorter and you see it, you see the noise
-
much more amplified. This red line is kind
of the minimum level that the pulse needs
-
to trigger. This would be better. And
that's like the trigger level of an
-
oscilloscope. And you can set that with
those buttons in the browser. You need to
-
find a good value. Of course, if you
change your input volume settings, for
-
example, this will change. So you have to
remember which, with which settings it
-
works well. And it is pulsed, for example,
is even oscillating here. So for electron
-
detector, it's basically nice to count
particles. For the alpha detector it's
-
really the case where the size of the
pulse can be nicely evaluated and we can
-
actually do energy measurements. And these
energy measurements can be also called
-
spectrometry. So if you look closer at
these many pulses that have been recorded
-
and we find that there is really like much
more intensity, which means many more same
-
pulses were detected, we can relate it to
radium and radon. If we use a reference
-
alpha source and I have done this, I have
measured the whole circuit with the reference
-
sources and provide the calibration on
GitHub and you can reuse the GitHub
-
calibration if you use exactly the same
sound settings that I have used for
-
recording. And for example, these two very
weak lines here from two very distinctive
-
polonium isotopes from the uranium decay
chain. The top part here which is really
-
dark, corresponds basically in the
histogram view to this side on the left,
-
which is electrons. Most of these
electrons will actually enter the chip and
-
leave it without being completely
absorbed by it, but alpha particles
-
interact so strongly that they are
completely absorbed within the 50
-
micrometers of sensitive volume of these
diodes and OK here is a bit difficult to
-
see peaks. But the far end of the high
energy spectrum, you see two really clear
-
peaks and those can only stem from
polonium, actually. I mean, we know it's
-
uranium and that can only be polonium,
which is that isotope that produces the
-
most energetic alpha particles and
which is natural. And I said, if you use
-
the same setting like me, you can use it.
So the best is if you use actually the
-
same soundcard because they're if you put
it to hundred percent input sensitivity,
-
you will have exactly the same result,
like in my calibration case. And this
-
soundcard is pretty cheap, but also pretty
good. It costs just two dollars and has a
-
pretty range and resolves quite well, 16
bits and think, oh, you could do that with
-
Arduino as well, is actually a bit hard to
do. A really well defined 16 bit
-
measurement, even at 48 kHz. It's not so
easy and this keeps it cheap and kind of
-
straightforward. And you can have just
some Python scripts on the computer to
-
read it out. And this is as a reminder, in
order to measure alpha particles, we have
-
to remove the glass here on top of the
diode. So I'm doing it just cutting into
-
the metal frame and then the glass breaks
away easily. Is not a problem, there's
-
more on that on the wiki. Now we
can kind of compare alpha and gamma
-
spectrometry. Here's an example. This is
the uranium glazed ceramics. The red part
-
is uranium oxide that was used to create
this nice red color in the 50s, 60s, 70s.
-
And in the spectrum we have two very
distinctive peaks and nothing in the high
-
energy regime. Only this low energy range
has a signal. And this corresponds
-
actually to uranium 238 and 234 because
they use actually purified uranium. So all
-
of the high energy progeny or daughters of
uranium, they're not present here because
-
it was purified uranium. And this
measurement doesn't even need vacuum, I
-
put it just like this in a regular box. Of
course, if you would have vacuum, you
-
would improve this peaks by a lot. So this
widening here to the left, basically, that
-
this peak is almost below the other one.
That is due to the natural air at regular
-
air pressure, which already interacts a
lot with the particles and absorbs a lot
-
of energy before the particles hit the
sensor. So in terms of pros and cons, I
-
would say the small sensor is quite
interesting here in an alpha spectrometry
-
because it's enough to have a small
sensor. So it's cheap and you can measure
-
very precisely on specific spots. And on
the other hand, of course, the conditions
-
of the object influence the measurement a
lot. So, for example, if there's some
-
additional paint on top, the alpha
particles might not make it through. But
-
in most of these kind of samples, alpha
radiation actually makes it through the
-
top, a transparent paint layer. In terms
of gamma spectrometry, you would usually
-
have these huge and really expensive
sensors. And then the advantage, of
-
course, is that you can measure,
regardless of your object, you don't
-
really need to prepare the object a lot.
You might want some lead shielding around
-
it. That's again, expensive, but you can
do it. You can improve the measurement
-
like that. And it's basically costly
because the sensor is quite expensive.
-
Vice versa in the set setup for 15 to 30
euro. You have everything you need and
-
here you're looking at several hundred to
several thousand euros. OK, now measuring
-
I have to be a bit quicker now, I noticed.
So I talked about the potassium
-
salt. There's also fertilizer based on
potassium baking powder. Uranium glass is
-
quite nice. You can find that easily on
flea markets. Often also old radium
-
watches. Here's another example of a
uranium glaze, the kitchen tile in this
-
case, this was actually in the kitchen. So
the chances are that you at home find
-
actually some of those things in the
cupboards of your parents or your
-
grandparents. It is an example of
thoriated glass, which has this
-
distinctive brownish color, which actually
is from the radiation. And a nice little
-
experiment that I can really recommend you
to look up is radioactive balloon
-
experiment. Here, you charge the balloon
electrostaticly and then it would catch
-
polonium from the air. And it's really
great. You basically get a radioactive
-
balloon after it was just left for 15
minutes in a normal regular room. OK, now
-
the last kind of context of all of
this to end this presentation, I want to
-
quickly remind how important these silicon
detectors are for places like CERN. It's a
-
cross-section of the ATLAS detector. And
here you have basically the area where the
-
collisions happen in the ATLAS detector.
So this is just a fraction of a meter. And
-
you have today 50 to 100 head on collisions
of two protons happening every 25
-
nanoseconds. Not right now, but soon
again, machines will be started again next
-
year. And you also can, by the way, build
a similar project which has a slightly
-
different name. It's called Build Your Own
Particle Detector. This is Atlas and made
-
out of LEGO. And on this website, you
find a nice plan, how to build or ideas,
-
how to build it from LEGO to better
visualize the size and interact more with
-
particle physics. In case of the CMS
detector. This is the second biggest
-
detector at CERN. Here you see nicely that
in the middle, at the core of the
-
collision, you have many, many pixel and
microstrip detectors which are made of
-
silicon. And these are actually 16 m² of
silicon pixel detectors and 200m² of
-
microstrip detectors also made of silicon.
So without basically that silicon
-
technology modern detectors wouldn't work
because this fine segmentation is really
-
required to distinguish all of these newly
created particles as a result of the
-
collision. So to summarize the website is
on GitHub, there is really this big wiki,
-
which you should have a look at, and
there's a gallery of pictures from users.
-
There's some simulation software that I
used as well. I didn't develop it, but I
-
wrote how to use it because the spectra
can sometimes be difficult to interpret.
-
And there's a new discussion forum that I
would really appreciate if some of you had
-
some discussions there on GitHub. And most
of the things I saw today are actually
-
written in detail in a scientific article,
which is open access, of course. And I
-
want to highlight two related citizen
science projects on the one hand, as the
-
safecast, which is about a large, nice,
sensitive Geiger-Müller based detector
-
that has the GPS and people upload their
measurements there. This is quite nice.
-
And also opengeiger is another website,
mostly German content, but also some of it
-
is English, that also uses diode
detectors, showed many nice places. He
-
calls it Geiger caching, places around the
world where you can measure something,
-
some old mines, things like this. And if
you want updates, I would propose to
-
follow me on Twitter. I'm right now
writing up two other articles with more
-
ideas for measurements and some of the
things you have seen today. Thanks a lot.
-
Herald: Well, thanks a lot, Oliver. I hope
everyone can hear me now again. Yes,
-
thanks for mentioning the citizen science
project as well. It's really cool I think.
-
We do have a few minutes for the Q&A and
also a lot of questions coming up in our
-
instance at the IRC. So the first question
was, can you talk a bit more about the SNR
-
of the system? Did you pick particular
resistor values and or Opamps to optimize
-
for noise? Was it a problem?
Oliver: Yeah, so noise is the big
-
issue here. Basically, the amplifier is
one I found that this around four, four
-
euros, trying to find the slide. Yeah, you
have to look it up on GitHub to the
-
amplifier type, but this is the most
important one. And then actually the
-
resistors, here, the resistance in the
first stage, sorry, the capacitors is the
-
second important thing. They should be
really small since I'm limited here with
-
hand soldarable capacitors. Basically I
choose the one that were just still
-
available, let's say, and this is
basically what is available is basically a
-
10 pF capacitor. If you put two of them,
one after another, you half the
-
capacitance, so you get five. And this, by
the way, is also then the capacitor. So I
-
kind of tried to keep the same
resistor values as much as possible, and
-
here at the output, for example, this is
to adjust the output signal for a
-
microphone input in the alpha
spectrometer, I changed the values quite a
-
bit to make a large pulse. But, yeah,
it's basically playing with the time
-
constants of this network and this
network.
-
Herald: All right, I hope that answers for
the person. Yeah, but people can get a
-
contact to you right after the show maybe
as well. So there's another question. Have
-
you considered using an I²S Codec with a
Raspberry Pi? radiation H80 should be
-
almost no set up and completely
repeatable. So last ones are for comment.
-
Oliver: I don't know that component, but,
yeah, as I said, using a sound card, it's
-
actually quite straightforward. But of
course there's many ways to get fancy.
-
And this is really this should actually
attract teachers and high school students
-
as well, this project. So this is one of
the main reasons why certain technologies
-
have been chosen, rather simple than,
let's say, fancy.
-
Herald: Yeah, so it should work with a lot
of people, I guess, and one another
-
question was how consistent are the sound
cards? Did you find the same calibration
-
worked the same with several of them?
Oliver: So if you want to use my
-
calibration, you should really buy this
two dollar card from eBay, CM108. I
-
haven't seen a big difference from card to
card in this one. But of course, like from
-
one computer to the mobile phone, it's a
huge difference in input, sensitivity and
-
noise. And it's very difficult to reuse
the calibration in this case. But you
-
still can count particles and the electron
detector is anyway, um, mostly it actually
-
just makes sense for counting because the
electrons are not completely absorbed. So
-
you get an energy information, but it's
not the complete energy of the electron.
-
So yeah, you could use it for x rays, but
then you need an x ray machine. So yeah.
-
Herald: Who doesn't need an x ray machine,
right? laugs So maybe one question I
-
have, because I'm not very familiar with
the tech stuff, but what actually can be
-
done with it right in the field. So you
mentioned some working with teachers with
-
these detectors? What have you done with
that in the wild so to say?
-
Oliver: So what's quite nice is you can
characterize stones with it, for example.
-
So since you can connect it to a
smartphone this is completely mobile and
-
it goes quite well in combination with a
Geiger counter in this case. So with a
-
Geiger counter, you just look around,
where are some hot spots and then you can
-
go closer with the alpha spectrometer and
actually be sure that there is some traces
-
of thorium or uranium on the stone, for
example. Or in this type of ceramic, these
-
old ceramics, you can go to the flea
market and just look for these very bright
-
red ceramics and measure them on the spot
and then decide which one to buy.
-
Herald: OK, so that's what I'm going to do
with it. Thanks for for highlighting a bit
-
the practical side, I think it's really
cool to educate people about scientific
-
things as well. Another question from the
IRC. Didn't you have problems with common
-
mode rejection by connecting the device
through the sound card? If yes have you
-
tried to do a AD conversion digitization
on the bord itself already? Transfer
-
transfer wire SP dif?
Oliver: Yeah, so, of course, I mean, this
-
is the thing to do, if you want to make a
like a super stable, rock solid
-
measurement device, but it is really
expensive. I mean, we are looking here at
-
15 euros and yeah, that's the reason to
have this separate soundcard just to
-
enable with some very low resources to do
this. But I'm looking for these pulses. So
-
this common mode rejection is a problem.
And also this is kind of Überschwinger -
-
I'm missing the English term. This is kind
of oscillations here. If you design a
-
specific analog to digital conversion, of
course, you would take all of that into
-
account and it wouldn't happen. But here
this happens because the circuit can never
-
be exactly optimal for certain soundcard
input. It will always be some mismatch of
-
impedances and.
Herald: All right, so maybe these special
-
technical issues and details, this could
be something you could discuss with Oliver
-
on Twitter of maybe Oliver or want to join
the IRC room for your talk as well. People
-
were very engaged during your talk. So is
this always a good sign. In that sense I'd
-
say thank you for being part of this first
remote chaos experience. Thanks again for
-
for your talk and for taking the time and
yeah, best for you and enjoy the rest of
-
the conference of the Congress and a warm
round of virtual applause and big thank
-
you to you, Oliver.
Oliver: Thanks, I will join the chat room
-
right now.
-
rc3 postrol music
-
Subtitles created by c3subtitles.de
in the year 2021. Join, and help us!
