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 Introduction 

To begin with, we have chosen this topic due to the fact that silicon radiation detectors are one of the main type of particle detectors used in the radiation detection industry nowadays. Hence, it is crucial for an engineer in this field to know the history of silicon production as well as the development process and concrete examples of the different types of detectors.

In this wiki page  we are studying the rapid progress of the silicon radiation detectors, the design of the single sided stereo angle silicon strip detector, cadmium telluride (CdTe)  and  cadmium zinc telluride (CdZnTe) or CZT pixel detectors and the development of the detectors in Finland. The information was collected from Institute of Electrical and Electronics Engineers/Institution of Electrical Engineers (IEEE/IEE) Electronic Library online.

 History of silicon radiation detectors

According to Rehak (2003), silicon is the main material which is used in electronics and radiation detection industries. Moreover, there was a rapid development in the field of silicon radiation detectors in the last decade, which could be noted as a considerable progress after 1982, when planar technology was invented. [1.] Furthermore, according to Orava et al (2007), even today new development activity is initiated with introduction of 3D detector technologies, active edge silicon processing and other perspective inventions in the field. [3.] It has to be said that there is always interaction between electronics industry and silicon radiation detectors because they both use silicon as the main component. The main point is that silicon used for radiation detectors should have 3-4 times more resistivity and lower density of traps than the one used for electronics. [1.]

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Planar technology was introduced in 1982, which led to the rapid progress in development of the silicon detectors. Among others, strip detectors were invented and matched to meet the requirements of the Large Hadron Collider (LHC) developed at The European Organization for Nuclear Research (CERN). Main advantages were lower noise, smaller capacitance, room working temperature, easier production, reduced cooling requirements and larger area coverage. [1;3]

Strip silicon radiation detectors 

Strip silicon detectors consist of n type material while having p type aluminium strips on the surface which are separated by a thin insulator. At the same time there is an electric field between the p strips and the n type material. When a radiation particle passes the detector, silicon atoms are ionized and free electrons leave these atoms with an electron vacancy (holes). After they reach the p type strip they are collected and then create a charge on the aluminium strip which is possible to be measured with special electronics.

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Furthermore, detector is designed in a way that every second strip is long while short strips are crossing them which helps to register particles at better angles to the surface of the sensor. Consequently, the high efficiency and proper special resolution are achieved. [3].

CdTe and CdZnTe pixel detectors 

Cadmium telluride (CdTe) is a stable crystalline compound composed from cadmium and tellurium. Doped with a small amount of Zn it produces cadmium zinc telluride, (CdZnTe) or CZT.
CdTe and CdZnTe pixel detectors are implementing implemented in imaging systems which are widely used in medical diagnostics (mammography, dental phantoms), astronomy, and industrial research.
CdTe and CdZnTe pixel detectors are very appealing due to their high energy resolution at normal conditions which is not high enough in currently implementing materials [4, 1]. Another advantage of those detectors is their perfect efficiency while working with X-ray energy spectrum as well as compatibility with gamma rays, alpha and beta particles [5, 3]. 
Nowadays, there are two ways of using CdTe/CZT detectors. The first one is focused on single channel detectors which are used in X- and gamma- ray spectroscopy. The second is proposed for multi-channel devices in nuclear medicine mostly. [5, 26]

Materials and manufacturing technologies

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Strip silicon detectors consist of n type material while having p type aluminium strips (which are used to collect the charge) on the surface which are separated by a thin insulator.The crystalline structure is diamond cubic (FCC). Polysilicon consists of small Si crystals randomly oriented.

 

• Are metals used? Which ones? Why?
  aluminium strips 

 

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There are two types of material used for package of detector: ceramic or polymer.

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Some materials are more favorable than others

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due smaller capacitance, lower noise, room working temperature, easier production, reduced cooling requirements and larger area coverage.

 Typical manufacturing process steps (Figure 13):

 

 

• How is the sensor manufactured?

1.  Starting Point: single-crystal n-doped wafer.  Wafer is a very thin slice of silicon crystal which is used to produce the actual detectors.
2.  Surface passivation by SiO2-layer. E.g. growing by (dry) thermal oxidation at 1030 °C.
3.  Window opening using photolithography technique with etching, e.g. for strips!
4. Doping using either 

•  Thermal diffusion (furnaceproduce a thin layer of oxide  on the surface of a wafer)
•  Ion implantation (introduction of dopants in a semiconductor by accelerating ions)

5.  After ion implantation: Curing of damage via thermal annealing at approx. 600°C, (activation of dopant atoms by incorporation into silicon lattice)
6.  Metallization of front side: sputtering or CVDside: sputtering or CVD (chemical vapor deposition) to produce thin film
7.  Removing of excess metal by photolitographyby photolithography: etching of non-covered areas
8.  Full-area metallization of backplane with annealing at approx. 450°C for better adherence between metal and silicon

9. Wafer dicing (cutting)

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• What are the typical manufacturing process steps?
  Silicon micromachining
  Photolithography

between metal and silicon

9.  Wafer dicing (cutting) [12].

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 Figure 13. Manufacturing process steps. Reprinted from : http://indico.cern.ch/event/124392/contribution/0/material/slides/0.pdf [12].

 

Silicon radiation detectors characteristics

As an example, we have considered datasheets of 2 sensors. Those are DT Standard Photodiode Products [7] and First Sensor PIN PD [8]. 

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 Figure 6.First Sensor PIN PD characteristics. Reprinted from http://www.marubun.co.jp [8].

Interface electronic circuits

As almost all other sensors, radiation detectors need to be interfaced before being able to process the data.  An interface or a signal conditioning circuit has a specific purpose:  to bring the signal from the sensor up to the format which is compatible with the load device [10]. Cremat Inc. radiation detection electronics can be used with a wide range of detectors, including compound semiconductor radiation detectors, scintillator-photodiode detectors, avalanche photodiodes etc [9].

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Development in Finland

Today there are two big companies which implement CdTe/CZT detectors in Finland. 

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VTT Technical Research Centre of Finland has been developing strip silicon radiation detectors for many years. What is more, VTT have been closely working with CERN which conducts the most important experiments on particle physics in the world.

Wafer is a very thin slice of silicon crystal which is used to produce the actual detectors. The production line at VTT can make wafers up to 200 mm in diameter using planar technology. Furthermore, the thickness of the strip detectors is only 150 μm or 300 μm which can be implemented for different bias configurations. Area of the detectors is from 5 x 5 cm² to 1 x 1 cm². Interestingly, the modern fabrication techniques such as etching, planarization, lithography and bonding are applied. The most important thing is that leakage currents of the detectors are under few nanoamperes, which makes it acceptable for radiation detection. [2].

References

1.  Rehak, P. ; Brookhaven Nat. Lab., Upton, NY, USA. Silicon radiation detectors [online]. Nuclear Science Symposium Conference Record, 2003 IEEE  (Volume:5 ); 19-25 Oct. 2003, 2492-2497.

   URL: http://ieeexplore.ieee.org.ezproxy.metropolia.fi/stamp/stamp.jsp?tp=&arnumber=1352629, Accessed 16 March 2014.

   
   

2. Virolainen, T. ; Kamarainen, V. ; Ji, F. ; Garcia, F. ; Orava, R. ; van Remortel, N. ; Santala, M. Silicon radiation detector development at VTT [online]. Nuclear Science Symposium Conference Record, 2007. NSS '07. IEEE  (Volume:2 ); Oct. 26 2007-Nov. 3 2007, 1494-1497.

   URL: http://ieeexplore.ieee.org.ezproxy.metropolia.fi/stamp/stamp.jsp?tp=&arnumber=4437282, Accessed 16 March 2014.

   
   

3. Huhtinen, M. ; Res. Inst. for High Energy Phys., Helsinki, Finland ; Orava, R. ; Pimia, M. ; Tuuva, T. Single sided stereo angle silicon strip detector [online]. Nuclear Science, IEEE Transactions on  (Volume:40 ,  Issue: 4 ); Aug 1993, 227-229.

   URL: http://ieeexplore.ieee.org.ezproxy.metropolia.fi/stamp/stamp.jsp?tp=&arnumber=256575, Accessed 16 March 2014.

   
   
4.  Yossi Eisen, Asher Shor, Israel Mardor (2004) CdTe and CdZnTe X-Ray and Gamma-Ray Detectors for Imaging Systems. IEEE transactions on  nuclear science; June 2004, Val. 51, No. 3.

   URL:  http://ieeexplore.ieee.org.ezproxy.metropolia.fi/stamp/stamp.jsp?tp=&arnumber=1312040&tag=1,  Accessed 17 March 2014.

   
   
5.  Tom Schulman (2006) Si, CdTe and CdZnTe radiation detectors for imaging applications. University of Helsinki, Finland; June 19, 2006.
   
   
   
6.  AJAT Ltd. official webpage 

   URL:  http://www.ajat.fi/, Accessed 17 March 2014.

   
   
   
7.  Detection Technology Oy official webpage
   

   URL: http://www.deetee.com/en_US/home.html, Accessed  5 April 2014.

   
   
   
   
8. Marubun Corporation official webpage
   

   URL: http://www.marubun.co.jp/product/measurement/sensor/8ids6e000000k1lh-att/X100-7SMD.pdf, Accessed  5 April 2014.

   
   
9. Cremat Inc. official webpage 

   URL: http://www.cremat.com/ , Accessed  10 April 2014.

   
   
10. Jacob Fraden–3rd ed. Handbook of modern sensors : physics, designs, and applications. Springer-Verlag New York, Inc., USA; 2004
    
    
11.  Integrated Digital conference Official website.  International Workshop on Semiconductor Pixel Detectors for Particles and Imaging. Hotel Listel Inawashiro, Inawashiro, Japan; 2-9 Spt. 2012.
     URL: http://indico.cern.ch/event/137337/material/slides/0?contribId=10&sessionId=5 , Accessed  8 April 2014.
    
    
    
12. Integrated Digital conference Official website. Silicon strips and pixels technologies event, CERN, Switzerland; 31.01.2011-10.02.2011.

URL: http://indico.cern.ch/event/124392/contribution/0/material/slides/0.pdf , Accessed  28 April 2014.