Electroded avalanche amorphous selenium (a-Se) photosensor.

Although avalanche amorphous selenium (a-Se) is a very promising photoconductor for a variety of imaging applications, it is currently restricted to applications with electron beam readout in vacuum pick-up tube called a High-gain Avalanche Rushing Photoconductor (HARP). The electron beam readout is compatible with high definition television (HDTV) applications, but for use in solid-state medical imaging devices it should be replaced by an electronic readout with a two-dimensional array of metal pixel electrodes. However, due to the high electric field required for avalanche multiplication, it is a technological challenge to avoid possible dielectric breakdown at the edges, where electric field experiences local enhancement. It has been shown recently that this problem can be overcome by the use of a Resistive Interface Layer (RIL) deposited between a-Se and the metal electrode, however, at that time, at a sacrifice in transport properties.Here we show that optimization of RIL deposition technique allows for electroded avalanche a-Se with transport properties and time performance previously not achievable with any other a-Se structures. We have demonstrated this by detailed analysis of transport properties performed by Time-of-Flight (TOF) technique. Our results showed that a stable gain of 200 is reached at 104 V/µm for a 15-µm thick a-Se layer, which is the maximum theoretical gain for this thickness. We conclude that RIL is an enabling technology for practical implementation of solid-state avalanche a-Se image sensors.

A novel ultralow-illumination endoscope system.

BACKGROUND: Endoscopic surgery has become an accepted major type of minimally invasive surgery. However, complications arising from heat generated by sources of endoscopic illumination can include surgical fire or burns, and intense illumination during ob-gyn/fetoscopic surgery might damage fetal ocular development. Fiber-optic bundles for illumination within the endoscope essentially double the outer diameter of the endoscope, which is a major obstacle to miniaturization and decreasing costs. Light cables also decrease the maneuverability of the endoscope METHODS: We developed a novel endoscope with ultralow illumination to visualize dark body cavities and investigated its feasibility in vivo. An adaptor was created to connect a conventional endoscope to an ultrahigh-sensitivity camera developed by the Japan Broadcasting Corporation (NHK) for broadcasting. The ability to visualize rabbit visceral blood vessels in vivo by the new prototype and by a current endoscope under ultralow illumination provided by a standard light source was compared. In addition, the performance of the two endoscopes was compared using only an extracorporeal flashlight without any specific light source placed within body cavities. RESULTS: The new endoscope could visualize the target under ultralow illumination of approximately 100 lx. Very little could be visualized using the current endoscope, whereas the prototype generated clear images of the rabbit blood vessels under both ultralow illumination and extracorporeal illumination provided by a flashlight. CONCLUSIONS: The potential for damage caused by a light source can be minimized using our new endoscope, which results in safer and less invasive procedures. Further studies are under way to develop a nonilluminated endoscope without a light cable or source and to miniaturize the camera to decrease costs and improve the maneuverability of the entire endoscope system.

Indirect flat-panel detector with avalanche gain: fundamental feasibility investigation for SHARP-AMFPI (scintillator HARP active matrix flat panel imager).

An indirect flat-panel imager (FPI) with avalanche gain is being investigated for low-dose x-ray imaging. It is made by optically coupling a structured x-ray scintillator CsI(Tl) to an amorphous selenium (a-Se) avalanche photoconductor called HARP (high-gain avalanche rushing photoconductor). The final electronic image is read out using an active matrix array of thin film transistors (TFT). We call the proposed detector SHARP-AMFPI (scintillator HARP active matrix flat panel imager). The advantage of the SHARP-AMFPI is its programmable gain, which can be turned on during low dose fluoroscopy to overcome electronic noise, and turned off during high dose radiography to avoid pixel saturation. The purpose of this paper is to investigate the important design considerations for SHARP-AMFPI such as avalanche gain, which depends on both the thickness d(Se) and the applied electric field E(Se) of the HARP layer. To determine the optimal design parameter and operational conditions for HARP, we measured the E(Se) dependence of both avalanche gain and optical quantum efficiency of an 8 microm HARP layer. The results were used in a physical model of HARP as well as a linear cascaded model of the FPI to determine the following x-ray imaging properties in both the avalanche and nonavalanche modes as a function of E(Se): (1) total gain (which is the product of avalanche gain and optical quantum efficiency); (2) linearity; (3) dynamic range; (4) gain nonuniformity resulting from thickness nonuniformity; and (5) effects of direct x-ray interaction in HARP. Our results showed that a HARP layer thickness of 8 microm can provide adequate avalanche gain and sufficient dynamic range for x-ray imaging applications to permit quantum limited operation over the range of exposures needed for radiography and fluoroscopy.