X-ray detectors are critical to healthcare diagnostics, cancer therapy and homeland security, with many potential uses limited by system cost and/or detector dimensions. Current X-ray detector sensitivities are limited by the bulk X-ray attenuation of the materials and consequently necessitate thick crystals (~1 mm–1 cm), resulting in rigid structures, high operational voltages and high cost. Here we present a disruptive, flexible, low cost, broadband, and high sensitivity direct X-ray transduction technology produced by embedding high atomic number bismuth oxide nanoparticles in an organic bulk heterojunction. These hybrid detectors demonstrate sensitivities of 1712 µC mGy−1 cm−3 for “soft” X-rays and ~30 and 58 µC mGy−1 cm−3 under 6 and 15 MV “hard” X-rays generated from a medical linear accelerator; strongly competing with the current solid state detectors, all achieved at low bias voltages (−10 V) and low power, enabling detector operation powered by coin cell batteries.
Hybrid inorganic-in-organic
semiconductors are an attractive class of materials for optoelectronic
applications. Traditionally, the thicknesses of organic semiconductors
are kept below 1 μm due to poor charge transport in such systems.
However, recent work suggests that charge carriers in such organic
semiconductors can be transported over centimeter length scales opposing
this view. In this work, a unipolar X-ray photoconductor based on
a bulk heterojunction architecture, consisting of poly(3-hexylthiophene),
a C70 derivative, and high atomic number bismuth oxide nanoparticles
operating in the 0.1–1 mm thickness regime is demonstrated,
having a high sensitivity of ∼160 μC mGy–1 cm–3. The high performance enabled by hole drift
lengths approaching a millimeter facilitates a device architecture
allowing a high fraction of the incident X-rays to be attenuated.
An X-ray imager is demonstrated with sufficient resolution for security
applications such as portable baggage screening at border crossings
and public events and scalable medical applications.
Organic‐inorganic hybrid semiconductors are an emerging class of materials for direct conversion X‐ray detection due to attractive characteristics such as high sensitivity and the potential to form conformal detectors. However, existing hybrid semiconductor X‐ray detectors display dark currents that are 1000–10 000× higher than industrially relevant values of 1–10 pA mm−2. Herein, ultra‐low dark currents of <10 pA mm−2, under electric fields as high as ≈4 V µm−1, for hybrid X‐ray detectors consisting of bismuth oxide nanoparticles (for enhanced X‐ray attenuation) incorporated into an organic bulk heterojunction consisting of p‐type Poly(3‐hexylthiophene‐2,5‐diyl) (P3HT) and n‐type [6,6]‐Phenyl C71 butyric acid methyl ester (PC70BM) are reported. Such ultra‐low dark currents are realized through the enrichment of the hole selective p‐type organic semiconductor near the anode contact. The resulting detectors demonstrate broadband X‐ray response including an exceptionally high sensitivity of ≈1.5 mC Gy−1 cm−2 and <6% variation in angular dependence response under 6 MV hard X‐rays. The above characteristics in combination with excellent dose linearity, dose rate linearity, and reproducibility over a broad energy range enable these detectors to be developed for medical and industrial applications.
X-ray detectors currently employed in dosimetry suffer from a number of drawbacks including the inability to conform to curved surfaces and being limited to smaller dimensions due to available crystal sizes. In this study, a hybrid X-ray detector (HXD) has been developed which offers real-time response with added advantages of being highly sensitive over a broad energy range, mechanically flexible, relatively inexpensive and able to be fabricated over large areas on the desired surface. The detector comprises of an organic matrix embedded with high atomic number inorganic nanoparticles which increase the radiation attenuation and within the device allows for simultaneous transfer of electrons and holes. The HXD delivers a peak response of 14 nA cm-2 , which corresponds to a sensitivity of 58 μC mGy-1 cm-3 , under the exposure of 15 MV hard X-rays generated by a medical linear accelerator. The angular dependence of the HXD has been studied, which offers a maximum variation of 26% in the posterior versus lateral beam directions. The flexible HXD can be conformed to the human body shape and is expected to eliminate variations due to source-to-skin distance with reduced physical evaluation complexities.
Insulating Bi2O3 nanoparticles are used for structuring the rear metal electrode in polymer solar cells creating a localized geometric electric field enhancement. In combination with the localized cells formed under the nanoparticles which are operating at short condition, the nanostructured electrode edges improve the overall charge extraction resulting in an overall power conversion efficiency gain of ≈30%.
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