I would like to couple a 2×2 silicon photomultiplier array (where each of the silicon photomultipliers serves as a "pixel" analog output) with a plastic scintillator piece in order to measure the intensity of light that is emitted when incident radiation passes through the scintillator. The purpose of this project is to (hopefully) detect cosmic-ray muons that exist at a natural background flux. I am a member of a high school research team (we are extremely amateur) that would like to detect this muon background and study whether we can track the positioning and trajectory of incident muons at a lower cost than the utilization of scintillating fiber or drift chambers.

The above diagram I made shows a crude depiction of the coupling of the scintillator and the 2×2 photomultiplier array. The purpose of the array is to look for a simultaneous signal "jump" that hopefully will be distinguishable from the dark count in the device. This will enable a muon transmission incidence to be determined according to the signal strength and replication in each of the four pixels via a chi-square test. We also intend to measure a 2-D coordinate approximation of the muon incidence based on the premise that all of the light from the transmission will attenuate evenly throughout the scintillating plastic, such that the position is triangulated by measuring the differential intensities of light received by each of the four pixel readouts (this is similar to the function of a gamma camera minus the collimator component. This is a goal we will likely not reach to an adequate degree of accuracy, but muon detection in general will be sufficient for our purposes).

Above is an extremely bare-bones schematic of our device that we are constructing, showing four scintillator pieces each coupled with 2×2 silicon photomultiplier arrays. The dimensioning of the device enables a small fraction of the total muon flux to be measured at a time. The trajectory will hopefully be constructed by combining the differential signals from all of the scintillator-array couplings, which will enable 2D coordinates to be established in each layer, and therefore a 3D trajectory when all of those are determined.

I have calculated a conservative "minimum" threshold of light intensity that would distinguish a muon incidence in this set-up, based on the properties of muon attenuation in materials and that of the scintillator itself (in this case a polyvinyltoluene-based compound). Based on a formula provided by SensL whitepaper documentation and its quoted photon detection efficiency for the array in question, I have determined that this threshold corresponds to a firing of at least 25 microcells at once within each of the four photomultiplying pixels (more on the microcells below). I have also tried to determine what the signal from the photomultipliers would look like on an oscilloscope before hand, but the research I have done has yielded formulas which involve advanced simulation techniques that I am not currently equipped to perform, or mathematical expressions that include components such as Fourier transforms that I could learn if I really need to, but am not familiar with (I have only taken two semesters of calculus). However, I first wanted to see if there was an easier way to simply design a read-out circuit for the photomultipliers.

My question: Based on the specifications provided for the photomultiplier array shown at the bottom, how can I determine the specification and circuit layout for a transimpedance amplifier (to convert current fluctuation into voltage fluctuation) and analog to digital conversion module, such that a digital readout of the photomultiplier activity can be communicated via USB to a desktop computer? Do I need to know the exact shape, frequency, and amplitude of the analog signal to do this? If so, what is the best way to go about that (i.e. where can I find a good source which walks through that process?) The SensL documentation tends to show a signal output of ~10mV over a span of ~50 ns at a time.

The array in question is sold by SensL and is identified by the following:

ArrayC-60035-4P-EVB

The 2×2 photomultiplier array is shown in the following images (Note: the source for all of these images/figures is SensL documentation):

This just shows the device in question, the ArrayC-60035-4P-EVB (a 2×2 silicon photomultiplier array with an attached evaluation board made by SensL)

The photomultipliers are supplied a break-down voltage such that an electric field of >5*10^5 V/cm is generated within the depletion region of the silicon substrate, which enables charge amplification via impact ionization. The breakdown voltage is supplied (~24.5 V for this product) with an additional over-voltage of 2.5 V as specified by the manufacturer.
Each of the 4 silicon photomultiplier pixels that compose a single array consists of 18,980 microcells. Each of these microcells consists of an avalanche photodiode in Geiger-mode, and a quench resistor. When a photon is incident upon one of these avalanche photodiodes, there is a rapid discharge current that decays exponentially when the voltage spike is dissipated across the quench resistor. A scaling output forms when the currents of all of these microcells are summed to show the approximate number of microcells discharging at a given time, which is indicative of the intensity of incident light, based on the particular quoted gain for the photomultiplier.

The above schematic shows how the four photomultiplying "pixels" appear in an equivalent circuit. The outputs labeled with "F" can be ignored because we will not be using fast output in this project. the outputs labeled with "S" are the standard analog channels which we want to process the current fluctuation from.

The above schematic shows the array of microcells (avalanche photodiodes) that are embedded within each of the four photomultipliers.

The above two figures show the ports located on the evaluation board provided by SensL. This includes a common cathode and four anodes for analog signal output in the form of current fluctuation.

The above figure shows the quenching cycle on each of the avalanche photodiodes. In this project, we would like to quantify the number of discharges that occur over a small interval of time, about 500 ns.

This shows the output of individual microcells in the array.

This is the type of output we would like to achieve in the end, showing how many photoelectron amplification events are occurring at a given time, in digital form (the figure above shows an analog signal that exhibits discrete thresholding from multiple microcell discharge).

Array specifications:
Number of microcells fired during desired signal: 25

Number of total microcells in photomultiplier: 18,980

Capacitance of entire device: 3400 pF

Overvoltage: 2.5 V (Breakdown voltage is 24.5V)

Microcell recharge time constant: 95ns (RC time constant, so this includes quench resistor)