Low‐Temperature Operation of High‐Efficiency Germanium Quantum Dot Photodetectors in the Visible and Near Infrared

Siontas, Stylianos; Li, Dongfang; Liu, Pei; Aujla, Sartaj; Zaslavsky, Alexander; Pacifici, Domenico

doi:10.1002/pssa.201700453

Cited by 7 publications

(11 citation statements)

References 28 publications

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“…In the last decade, many research groups have paid attention on amorphous germanium nanoparticles (Ge-NPs) embedded in different oxide matrices because of their attractive electrical and optical properties which are suitable for different applications like photo-detectors 1–3 , solar cells 4 , light-emitting diodes 5 , memory devices 6 , MOSFET transistors 7,8 and lithium-ion batteries with high charge-discharge rate 9,10 . This effort has the main aim to extend the sensitivity domain of photodetectors toward near infrared (NIR) and therefore to develop the optoelectronics in this wavelength range as Si based photodetectors are usually limited to 1.1–1.2 μ m. Ge is the main candidate that has attracted attention for Si replacement because Ge has a higher carrier mobility than Si 11 .…”

Section: Introductionmentioning

confidence: 99%

Ge nanoparticles in SiO2 for near infrared photodetectors with high performance

Stavarache

Teodorescu

Prepelita

et al. 2019

Sci Rep

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In this work we prepared films of amorphous germanium nanoparticles embedded in SiO 2 deposited by magnetron sputtering on Si and quartz heated substrates at 300, 400 and 500 °C. Structure, morphology, optical, electrical and photoconduction properties of all films were investigated. The Ge concentration in the depth of the films is strongly dependent on the deposition temperature. In the films deposited at 300 °C, the Ge content is constant in the depth, while films deposited at 500 °C show a significant decrease of Ge content from interface of the film with substrate towards the film free surface. From the absorption curves we obtained the Ge band gap of 1.39 eV for 300 °C deposited films and 1.44 eV for the films deposited at 500 °C. The photocurrents are higher with more than one order of magnitude than the dark ones. The photocurrent spectra present different cutoff wavelengths depending on the deposition temperature, i.e. 1325 nm for 300 °C and 1267 nm for 500 °C. These films present good responsivities of 2.42 AW −1 (52 μ W incident power) at 300 °C and 0.69 AW −1 (57 mW) at 500 °C and high internal quantum efficiency of ∼445% for 300 °C and ∼118% for 500 °C.

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Section: Introductionmentioning

confidence: 99%

Ge nanoparticles in SiO2 for near infrared photodetectors with high performance

Stavarache

Teodorescu

Prepelita

et al. 2019

Sci Rep

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“…For T ¼ 100 K, I ph shows a sublinear behavior across the entire incident power range for both illumination wavelengths, which is attributed to the saturation of the QD charging process and the reduction of available tunneling paths through the QD network as temperature is lowered, due to suppressed phonon-assisted tunneling. 16 The sublinear behavior of the photocurrent for T ¼ 100 K at both k results in an increasing IQE as P in is reduced, reaching a maximum of 1000% for k ¼ 1550 nm at P in ¼ 10 nW.…”

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confidence: 95%

“…Previously, we reported PDs based on Ge QDs embedded in a SiO 2 matrix, fabricated on Si substrates, with spectral responsivities up to 4 A/W and high internal gain up to 700% in the k ¼ 400-1100 nm range. [13][14][15][16] However, those PDs were incapable of producing a significant photoresponse beyond k ¼ 1100 nm, corresponding to the Si substrate bandgap. 17 In this work, Ge QD PDs were fabricated on Ge substrates, extending the working spectral range up to the k ¼ 1550 nm telecom wavelength.…”

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confidence: 99%

“…The fabrication process followed was the same as described in previous work, 15,16 but here Ge and SiO 2 targets were co-sputtered on n-Ge substrates so as to extend the photoresponse up to k ¼ 1550 nm, based on the fact that photon absorption takes place predominantly in the substrate, which in turn determines the PD's working spectral range. 13 The n-Ge substrates used were lightly doped (q ¼ 2.6 X cm) with the aim of minimizing recombination of photogenerated carriers and were kept at 400 C during deposition.…”

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confidence: 99%

“…Finally, the structure was completed by attaching the device to a sapphire substrate with a back indium contact. 15,16 The schematic geometry of the Ge QD PD structure is depicted in Fig. 1(a), whereas the energy band diagram including the corresponding interband optical transitions responsible for the photoresponse is provided in Fig.…”

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confidence: 99%

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Broadband visible-to-telecom wavelength germanium quantum dot photodetectors

Siontas

Wang

et al. 2018

Applied Physics Letters

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Germanium (Ge) quantum dot (QD) photodetectors (PDs) were fabricated on Ge substrates exhibiting a broadband, visible to near-infrared (near-IR) photoresponse in the k ¼ 400-1550 nm range. Room-temperature responsivities (R sp) up to 1.12 A/W and internal quantum efficiency IQE ¼ 313% were obtained, superior to conventional silicon and germanium photodiodes. Noise analysis was performed at visible k ¼ 640 nm and telecom k ¼ 1550 nm wavelengths, both yielding room-temperature specific detectivity D* ' 2 Â 10 10 cm Hz 1/2 W À1. Lowering the operating temperature and incident power led to sharply enhanced performance, with D * ¼ 1.1 Â 10 12 cm Hz 1/2 W À1 and IQE ¼ 1000% at T ¼ 100 K for an incident power of 10 nW at k ¼ 1550 nm. Based on their simple fabrication and silicon technology compatibility, these Ge QD PDs represent a promising alternative for broadband, high-performance visible to near-IR detection.

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Surface Engineering of Quantum Dots for Remarkably High Detectivity Photodetectors

Shen

Zheng

et al. 2018

J. Phys. Chem. Lett.

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Ternary alloyed CdSe Te colloidal QDs trap-passivated by iodide-based ligands (TBAI) are developed as building blocks for UV-NIR photodetectors. Both the few surface traps and high loading of QDs are obtained by in situ ligand exchange with TBAI. The device is sensitive to a broad wavelength range covering the UV-NIR region (300-850 nm), showing an excellent photoresponsivity of 53 mA/W, a fast response time of ≪0.02s, and remarkably high detectivity values of 8 × 10 Jones at 450 nm and 1 × 10 Jones at 800 nm without an external bias voltage. Such performance is superior to what has been reported earlier for QD-based photodetectors. The photodetector exhibits excellent stability, keeping 98% of photoelectric responsivity after 2 months of illumination in air even without encapsulation. In addition, the semitransparent device is successfully fabricated using a Ag nanowires/polyimide transparent substrate. Such self-powered photodetectors with fast response speed and a stable, broad-band response are expected to function under a broad range of environmental conditions.

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Low‐Temperature Operation of High‐Efficiency Germanium Quantum Dot Photodetectors in the Visible and Near Infrared

Cited by 7 publications

References 28 publications

Ge nanoparticles in SiO2 for near infrared photodetectors with high performance

Ge nanoparticles in SiO2 for near infrared photodetectors with high performance

Broadband visible-to-telecom wavelength germanium quantum dot photodetectors

Surface Engineering of Quantum Dots for Remarkably High Detectivity Photodetectors

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