1 Detectors RIT Course Number 1051-465 Lecture N: Lecture Title.

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Presentation transcript:

1 Detectors RIT Course Number Lecture N: Lecture Title

2 Section Title Slide

3 pn Junction Review PN junctions are fabricated from a monocrystalline piece of semiconductor with both a P-type and N-type region in proximity at a junction. The transfer of electrons from the N side of the junction to holes annihilated on the P side of the junction produces a barrier voltage. This is 0.6 to 0.7 V in silicon, and varies with other semiconductors. A forward biased PN junction conducts a current once the barrier voltage is overcome. The external applied potential forces majority carriers toward the junction where recombinetion takes place, allowing current flow. A reverse biased PN junction conducts almost no current. The applied reverse bias attracts majority carriers away from the junction. This increases the thickness of the nonconducting depletion region. Reverse biased PN junctions show a temperature dependent reverse leakage current. This is less than a µA in small silicon diodes.

4 N-type

5 Band Diagram: Acceptor Dopant in Semiconductor For Si, add a group III element to “accept” an electron and make p-type Si (more positive “holes”). “Missing” electron results in an extra “hole”, with an acceptor energy level E A just above the valence band E V. –Holes easily formed in valence band, greatly increasing the electrical conductivity. Fermi level E F moves down towards E V. EAEA ECEC EVEV EFEF p-type Si

6 P-type

7 Conduction in p/n-type Semiconductors

8

9 PN Junction: Band Diagram Due to diffusion, electrons move from n to p-side and holes from p to n-side. Causes depletion zone at junction where immobile charged ion cores remain. Results in a built-in electric field (10 3 to 10 5 V/cm), which opposes further diffusion. Note: E F levels are aligned across pn junction under equilibrium. Depletion Zone electrons pn regions in equilibrium holes EVEV EFEF ECEC EFEF EVEV EFEF ECEC – – – – – – – – – – – – p-type n-type

10 PN Junction: Band Diagram under Bias Forward Bias: negative voltage on n-side promotes diffusion of electrons by decreasing built-in junction potential  higher current. Reverse Bias: positive voltage on n-side inhibits diffusion of electrons by increasing built-in junction potential  lower current. Minority Carriers Forward BiasReverse BiasEquilibrium e– Majority Carriers p-typen-type p-typen-type p-typen-type –V +V

11 Forward & Reverse Biased

12 PN Junction: IV Characteristics Current-Voltage Relationship Forward Bias: current exponentially increases. Reverse Bias: low leakage current equal to ~I o. Ability of pn junction to pass current in only one direction is known as “rectifying” behavior. Reverse Bias Forward Bias

13 Current-Voltage Relationship Forward Bias: current exponentially increases. Reverse Bias: low leakage current equal to ~I o. Ability of pn junction to pass current in only one direction is known as “rectifying” behavior. PN Junction: IV Characteristics

14 Doped Silicon

15 Suitable doped silicon bandgaps for detectors

16 Generation & Recombination In intrinsic semiconductor –n = p = n i n i is strongly temperature dependent This is because at a give temperature –Recombination of electrons (r i )= thermal generation rate (g i ) r i = Bnp = g i (= Bn i **2 for intrinsic semiconductor)

17 Photon induced excess carriers

18 Photon induced excess carriers

19 Photon induced excess carriers

20 xx

21 xx

22 xx

23 xx

24 Rate of change of carrier concentration

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27 Diffusion

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32 PN Junction

33 PN Junction

34

35

36

37 Put it all together …

38 Steps PN junction is reversed biased. Shutter opened and photon enters semiconductor Interacts with lattice generates minority carrier Minority carrier diffuses till it reaches vicinity of junction Junction field drives minority carrier across junction and discharges junction capacitance At the end of some integration time measure voltage (V2)across junction. Reset junction voltage to initial reverse bias value and measure its value (V1). Difference in voltage is proportional to signal. ΔQ = C1(V1-Vbi) * (V1-vbi) – C2(V2-Vbi) * (V2-Vbi)

39 Designing a junction

40 Dark Signal

41 Slide Title xxxxxx

42 Section Title Slide

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44 Section Title Slide

45 Slide Title xxxxxx