Cooling detectors in particle physics Gavin Leithall CCLRC Rutherford Appleton Laboratory.

Cooling detectors in particle physicsGavin Leithall

CCLRC Rutherford Appleton Laboratory

Gavin Leithall, RAL Placement Conference 2006 2

CCLRC Rutherford Appleton Laboratory

• Government funded central research laboratory which supports a wide range of university research activities

• Located in Oxfordshire• I work in the Particle

Physics Department on the vertex detector for the International Linear Collider

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The International Linear Collider

• Will collide beams of electrons and positrons with energies from 91 - 500 GeV (upgrade to 1000 GeV)

• Scheduled to begin operation in 2015

• Will have a total length of about 30 km

• Intended to complement the Large Hadron Collider by being a more precise measuring tool

• Together they are hoped to discover new particles and test theories (e.g. the Higgs Boson and Supersymmetry)

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What is a vertex detector?

• Collisions produce a spray of high energy particles

• A large detector is built around the beam pipe to work out what happened in the collision

• The vertex detector is the one closest to the collision point

• Used to reconstruct particle tracks to determine their production point (vertex)

• Required to have little material to minimise scattering

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Linear Collider Flavour Identification

• LCFI (my project group) is designing the vertex detector for the ILC

• The detecting elements called ladders are layered in concentric barrels

• The ‘hits’ generated when a particle passes through enable track reconstruction

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Detector Technology

• The main technology being developed by LCFI is the Column Parallel Charge Coupled Device (CPCCD)

• These are composed of tiny pixels which accumulate charge when particles pass through

• Similar to the CCDs in digital cameras, but with a much faster readout

• The readout chips are placed at the end of the ladders

“Classic CCD”Readout time NM/Fout

N

M

N

Column Parallel CCDReadout time = N/Fout

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Detector Cooling

• The vertex detector will produce heat which will need to be removed.

• It will also need to be maintained at a constant operating temperature (possibly as low as -70 deg C)

• It therefore needs a cooling system to meet these requirements

• Conventional cooling systems would add material to the detector volume, so are not ideal

• Blowing cold gas from the ends of the detector is a possible solution

• My project is to investigate the effectiveness of this

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Cooling Test Rig• Built a system to produce a controlled nitrogen gas flow with

– Variable temperatures (-100oC to 20oC)– Variable flow rates (0-20 litres / min)

• Built a system to read temperatures from platinum resistors• Designed programs to enable remote control of both of these

systems

Gas Massflow

controller

Heat exchangerFilter

Regulator

HeaterThermocouple

Liquid nitrogen

ControlBox

To

Computer

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Detector model

• A quarter barrel model was decided upon because it would be easier to build than a full barrel, while maintaining all the essential physics.

• It has:– Stainless steel ladders and aluminium end-plates– Resistors in the place of the readout chips to simulate

heating– Platinum resistors at various positions within the

quarter barrel

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Quarter barrel construction

End plate

Inlet Outlet

Side view of quarter barrelResistors

Ladders

End plates

GasIn

GasOut

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The Physics

Quarter barrel

Temperature = Tq

Gas In

Temperature = Ti

Flow rate = v

Gas Out

Temperature = To

Flow rate = v

Heating power = Pi

Power lost to surroundings = Ps

Surrounding temperature = Ts

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Formulation of the problem

• Pg (power gain of gas) can be calculated by

Pg = cv (To – Ti) (c = specific heat capacity)

• Using energy conservationPi = Ps + Pg

• Using Newton’s Law of CoolingPs = L (Tq – Ts) (L = thermal loss coefficient)

• A graph of (Pi - Pg) against Tq should– Be a straight line with gradient L

– Pass through Pi – Pg = 0 when Tq = Ts

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• This graph

– Is a straight line with a gradient giving L ~ 0.26 W / deg C

– Suggests a room temperature of Ts ~ 19 deg C

(P i - P g ) against T q (5 litres / min)

y = 0.26x - 4.97

-4

-2

0

2

4

6

8

10

10 20 30 40 50

T q (deg C)

(Pi

- P

g)

(W)

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A hypothesis

• I can make a hypothesis about the form of Pg:

Pg = hv (Tq – Ti)

– h is the heat transfer coefficient, assumed constant, but could be a function of v, Tq, Ti

• This can be tested by plotting graphs of Pg against the other variables

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P g against (T q - T i )

-2

0

2

4

6

-5 0 5 10 15 20 25

(T q - T i ) (deg C)

Pg (

W)

20 litres / min17.5 litres / min15 litres / min12.5 litres / min10 litres / min7.5 litres / min5 litres / min

• This graph gives strong support to the hypothesis that Pg is proportional to (Tq – Ti)

• By plotting the gradient (i.e. Pg / (Tq – Ti)) of each line against its flow rate, the hypothesis can be tested further

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• This graph supports the hypothesis that Pg / (Tq – Ti) is proportional to v

• The gradient of this graph gives h ~ 0.022 W / deg C / (litre/min)

(P g /(T q - T i )) against v

y = 0.022x - 0.015

-0.1

0.0

0.1

0.2

0.3

0.4

0.5

0 5 10 15 20

v (litres / min)

Pg

/(T

q -

Ti)

(W

/de

g C

)

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Conclusions

• Thermal loss coefficientL ~ 0.26 W / deg C

• The form of Pg is

Pg = hv (Tq – Ti)• Heat transfer coefficient

h ~ 0.022 W / deg C / (litre / min)• Maximum Pg ~ 5 W when v = 20 litres /

min and (To – Ti) ~ 11 deg C

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Summary

• Testing the effectiveness of gaseous cooling for the vertex detector for the International Linear Collider

• Results so far show behaviour that is consistent with predictions

• Move on to investigate new configurations– More inlets, and with different positions– Different sizes and angles of inlets

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• Plotting the value of Pg predicted by the hypothesis against the value obtained by the earlier measurement provides a useful crosscheck

• This yields a graph which provides good support for the hypothesis

Predicted value of P g against its measured value

y = 1.00x + 0.02

-2

-1

0

1

2

3

4

5

-2 -1 0 1 2 3 4 5

Predicted value of P g (W)

Mea

sure

d v

alu

e o

f Pg

(W)