Capacitively coupled pickup in MCP-based photodetectors using a conductive metallic anode

TL;DR

This paper presents a novel capacitively coupled internal anode design for MCP-based photodetectors, enabling high-bandwidth signal pickup without electrical connections through the vacuum package.

Contribution

The authors introduce a robust, capacitively coupled internal anode with a multi-channel pickup array that maintains high bandwidth and can be easily customized for various applications.

Findings

Achieved 80% of directly coupled amplitude with pad pattern

Maintained fast pulse rise-time for both pickup patterns

Demonstrated high bandwidth and physical decoupling benefits

Abstract

We have designed and tested a robust 20 $\times$ 20 cm$^2$ thin metal film internal anode capacitively coupled to an external array of signal pads or micro-strips for use in fast microchannel plate photodetectors. The internal anode, in this case a 10nm-thick NiCr film deposited on a 96% pure Al$_2$O$_3$ 3mm-thick ceramic plate and connected to HV ground, provides the return path for the electron cascade charge. The multi-channel pickup array consists of a printed-circuit card or glass plate with metal signal pickups on one side and the signal ground plane on the other. The pickup can be put in close proximity to the bottom outer surface of the sealed photodetector, with no electrical connections through the photodetector hermetic vacuum package other than a single ground connection to the internal anode. Two pickup patterns were tested using a small commercial MCP-PMT as the signal source: 1) parallel 50$\Omega$ 25-cm-long micro-strips with an analog bandwidth of 1.5 GHz, and 2) a 20 $\times$ 20 cm$^2$ array of 2-dimensional square `pads' with sides of 1.27 cm or 2.54 cm. The rise-time of the fast input pulse is maintained for both pickup patterns. For the pad pattern, we observe 80% of the directly coupled amplitude. For the strip pattern we measure 34% of the directly coupled amplitude on the central strip of a broadened signal. The physical decoupling of the photodetector from the pickup pattern allows easy customization for different applications while maintaining high analog bandwidth.