Your search keyword '"Palaferri, Daniele"' showing total 18 results

1. Long-wavelength infrared photovoltaic heterodyne receivers using patch-antenna quantum cascade detectors

Author

Bigioli, Azzurra, Armaroli, Giovanni, Vasanelli, Angela, Gacemi, Djamal, Todorov, Yanko, Palaferri, Daniele, Li, Lianhe, Davies, Alexander Giles, Linfield, Edmund, and Sirtori, Carlo

Subjects

Physics - Applied Physics, Physics - Instrumentation and Detectors, Physics - Optics

Abstract

Quantum cascade detectors (QCD) are unipolar infrared devices where the transport of the photo excited carriers takes place through confined electronic states, without an applied bias. In this photovoltaic mode, the detector's noise is not dominated by a dark shot noise process, therefore, performances are less degraded at high temperature with respect to photoconductive detectors. This work describes a 9 um QCD embedded into a patch-antenna metamaterial which operates with state-of-the-art performances. The metamaterial gathers photons on a collection area, Acoll, much bigger than the geometrical area of the detector, improving the signal to noise ratio up to room temperature. The background-limited detectivity at 83 K is 5.5 x 10^10 cm Hz^1/2 W^-1, while at room temperature, the responsivity is 50 mA/W at 0 V bias. Patch antenna QCD is an ideal receiver for a heterodyne detection set-up, where a signal at a frequency 1.4 GHz and T=295 K is reported as first demonstration of uncooled 9um photovoltaic receivers with GHz electrical bandwidth. These findings guide the research towards uncooled IR quantum limited detection.

Published

2020

2. Room temperature 9 $\mu$m photodetectors and GHz heterodyne receivers

Author

Palaferri, Daniele, Todorov, Yanko, Bigioli, Azzurra, Mottaghizadeh, Alireza, Gacemi, Djamal, Calabrese, Allegra, Vasanelli, Angela, Li, Lianhe, Davies, A. Giles, Linfield, Edmund H., Kapsalidis, Filippos, Beck, Mattias, Faist, Jérôme, and Sirtori, Carlo

Subjects

Physics - Applied Physics, Physics - Instrumentation and Detectors, Physics - Optics

Abstract

Room temperature operation is mandatory for any optoelectronics technology which aims to provide low-cost compact systems for widespread applications. In recent years, an important technological effort in this direction has been made in bolometric detection for thermal imaging$^1$, which has delivered relatively high sensitivity and video rate performance ($\sim$ 60 Hz). However, room temperature operation is still beyond reach for semiconductor photodetectors in the 8-12 $\mu$m wavelength band$^2$, and all developments for applications such as imaging, environmental remote sensing and laser-based free-space communication$^{3-5}$ have therefore had to be realised at low temperatures. For these devices, high sensitivity and high speed have never been compatible with high temperature operation$^{6, 7}$. Here, we show that a 9 $\mu$m quantum well infrared photodetector$^8$, implemented in a metamaterial made of subwavelength metallic resonators$^{9-12}$, has strongly enhanced performances up to room temperature. This occurs because the photonic collection area is increased with respect to the electrical area for each resonator, thus significantly reducing the dark current of the device$^{13}$. Furthermore, we show that our photonic architecture overcomes intrinsic limitations of the material, such as the drop of the electronic drift velocity with temperature$^{14, 15}$, which constrains conventional geometries at cryogenic operation$^6$. Finally, the reduced physical area of the device and its increased responsivity allows us, for the first time, to take advantage of the intrinsic high frequency response of the quantum detector$^7$ at room temperature. By beating two quantum cascade lasers$^{16}$ we have measured the heterodyne signal at high frequencies up to 4 GHz.

Published

2017

3. Room-temperature nine-m-wavelength photodetectors and GHz-frequency heterodyne receivers

Author

Palaferri, Daniele, Todorov, Yanko, Bigioli, Azzurra, Mottaghizadeh, Alireza, Gacemi, Djamal, Calabrese, Allegra, Vasanelli, Angela, Li, Lianhe, Davies, A. Giles, Linfield, Edmund H., Kapsalidis, Filippos, Beck, Mattias, Faist, Jrme, and Sirtori, Carlo

Subjects

Resonators -- Usage, Materials research, Temperature -- Research, Wavelength -- Research, Photodetectors -- Materials -- Thermal properties, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Author(s): Daniele Palaferri [1]; Yanko Todorov [1]; Azzurra Bigioli [1]; Alireza Mottaghizadeh [1]; Djamal Gacemi [1]; Allegra Calabrese [1]; Angela Vasanelli [1]; Lianhe Li [2]; A. Giles Davies [2]; Edmund [...]

Published

2018

4. Mixing Properties of Room Temperature Patch-Antenna Receivers in a Mid-Infrared (lambda approximate to 9 mu m) Heterodyne System

Author

Bigioli, Azzurra, Gacemi, Djamal, Palaferri, Daniele, Todorov, Yanko, Vasanelli, Angela, Suffit, Stephan, Li, Lianhe, Davies, A. Giles, Linfield, Edmund H., Kapsalidis, Filippos, Beck, Mattias, Faist, Jérôme, and Sirtori, Carlo

Subjects

010309 optics, metamaterials, mid‐infrared detection, heterodyne detection, quantum well infrared detectors, 0103 physical sciences, Physics::Optics, 02 engineering and technology, 021001 nanoscience & nanotechnology, 0210 nano-technology, 01 natural sciences, 3. Good health

Abstract

A room‐temperature mid‐infrared (λ = 9 µm) heterodyne system based on high‐performance unipolar optoelectronic devices is presented. The local oscillator (LO) is a quantum cascade laser (QCL), while the receiver is an antenna coupled quantum well infrared photodetector optimized to operate in a microcavity configuration. Measurements of the saturation intensity show that these receivers have a linear response up to very high optical power, an essential feature for heterodyne detection. By providing an accurate passive stabilization of the LO, the heterodyne system reaches at room temperature the record value of noise equivalent power (NEP) of 30 pW at 9 µm and in the GHz frequency range. Finally, it is demonstrated that the injection of microwave signal into the receivers shifts the heterodyne beating over the large bandwidth of the devices. This mixing property is a unique valuable function of these devices for signal treatment in compact QCL‐based systems., Laser & Photonics Reviews, 14 (2), ISSN:1863-8880, ISSN:1863-8899

Published

2020

5. Long-wavelength infrared photovoltaic heterodyne receivers using patch-antenna quantum cascade detectors

Author

Bigioli, Azzurra, primary, Armaroli, Giovanni, additional, Vasanelli, Angela, additional, Gacemi, Djamal, additional, Todorov, Yanko, additional, Palaferri, Daniele, additional, Li, Lianhe, additional, Davies, A. Giles, additional, Linfield, Edmund H., additional, and Sirtori, Carlo, additional

Published

2020

6. Mixing Properties of Room Temperature Patch‐Antenna Receivers in a Mid‐Infrared (λ ≈ 9 µm) Heterodyne System

Author

Bigioli, Azzurra, primary, Gacemi, Djamal, additional, Palaferri, Daniele, additional, Todorov, Yanko, additional, Vasanelli, Angela, additional, Suffit, Stephan, additional, Li, Lianhe, additional, Davies, A. Giles, additional, Linfield, Edmund H., additional, Kapsalidis, Filippos, additional, Beck, Mattias, additional, Faist, Jérôme, additional, and Sirtori, Carlo, additional

Published

2019

7. Homogeneous photonic integration of mid-infrared quantum cascade lasers with low-loss passive waveguides on an InP platform

Author

Jung, Seungyong, primary, Palaferri, Daniele, additional, Zhang, Kevin, additional, Xie, Feng, additional, Okuno, Yae, additional, Pinzone, Christopher, additional, Lascola, Kevin, additional, and Belkin, Mikhail A., additional

Published

2019

8. Difference‐Frequency Generation in Polaritonic Intersubband Nonlinear Metasurfaces

Author

Liu, Yingnan, primary, Lee, Jongwon, additional, March, Stephen, additional, Nookala, Nishant, additional, Palaferri, Daniele, additional, Klem, John F., additional, Bank, Seth R., additional, Brener, Igal, additional, and Belkin, Mikhail A., additional

Published

2018

9. Room-Temperature, Wide-Band, Quantum Well Infrared Photodetector for Microwave Optical Links at 4.9 μm Wavelength

Author

Rodriguez, Etienne, primary, Mottaghizadeh, Alireza, additional, Gacemi, Djamal, additional, Palaferri, Daniele, additional, Asghari, Zahra, additional, Jeannin, Mathieu, additional, Vasanelli, Angela, additional, Bigioli, Azzurra, additional, Todorov, Yanko, additional, Beck, Mattias, additional, Faist, Jerome, additional, Wang, Qi Jie, additional, and Sirtori, Carlo, additional

Published

2018

10. Room-temperature 9um photodetectors and GHz heterodyne receivers (Conference Presentation)

Author

Sirtori, Carlo, primary, Palaferri, Daniele, additional, Todorov, Yanko, additional, Bigioli, Azzura, additional, Vasanelli, Angela, additional, Gacemi, Djamal, additional, Li, Lianhe H., additional, and Linfield, Edmund H., additional

Published

2018

11. GHz Heterodyne generation using Two DFB Mid-IR QCL lasers on a 9μm QWIP

Author

Palaferri, Daniele, primary, Todorov, Yanko, additional, Bigioli, Azzurra, additional, Gacemi, Djamal, additional, Mottaghizadeh, Alireza, additional, Calabrese, Allegra, additional, Vasanelli, Angela, additional, Li, Lianhe, additional, Davies, A. Giles, additional, Linfield, Edmund H., additional, Kapsalidis, Filippos, additional, Beck, Mattias, additional, Faist, Jérôme, additional, and Sirtori, Carlo, additional

Published

2018

12. Monolithic integration of mid-infrared quantum cascade lasers coupled with passive InGaAs waveguides

Author

Jung, Seungyong, primary, Palaferri, Daniele, additional, Xu, Jiaming, additional, Xie, Feng, additional, Okuno, Yae, additional, Pinzone, Christopher, additional, Lascola, Kevin, additional, and Belkin, Mikhail A., additional

Published

2018

13. Ultra-subwavelength resonators for high temperature high performance quantum detectors

Author

Palaferri, Daniele, primary, Todorov, Yanko, additional, Mottaghizadeh, Alireza, additional, Frucci, Giulia, additional, Biasiol, Giorgio, additional, and Sirtori, Carlo, additional

Published

2016

14. Hydrogen doping of Indium Tin Oxide due to thermal treatment of hetero-junction solar cells

Author

Ritzau, Kurt-Ulrich, primary, Behrendt, Torge, additional, Palaferri, Daniele, additional, Bivour, Martin, additional, and Hermle, Martin, additional

Published

2016

15. Room-temperature nine-µm-wavelength photodetectors and GHz-frequency heterodyne receivers.

Author

Palaferri, Daniele, Todorov, Yanko, Bigioli, Azzurra, Mottaghizadeh, Alireza, Gacemi, Djamal, Calabrese, Allegra, Vasanelli, Angela, Li, Lianhe, Davies, A. Giles, Linfield, Edmund H., Kapsalidis, Filippos, Beck, Mattias, Faist, Jérôme, and Sirtori, Carlo

Abstract

Room-temperature operation is essential for any optoelectronics technology that aims to provide low-cost, compact systems for widespread applications. A recent technological advance in this direction is bolometric detection for thermal imaging, which has achieved relatively high sensitivity and video rates (about 60 hertz) at room temperature. However, owing to thermally induced dark current, room-temperature operation is still a great challenge for semiconductor photodetectors targeting the wavelength band between 8 and 12 micrometres, and all relevant applications, such as imaging, environmental remote sensing and laser-based free-space communication, have been realized at low temperatures. For these devices, high sensitivity and high speed have never been compatible with high-temperature operation. Here we show that a long-wavelength (nine micrometres) infrared quantum-well photodetector fabricated from a metamaterial made of sub-wavelength metallic resonators exhibits strongly enhanced performance with respect to the state of the art up to room temperature. This occurs because the photonic collection area of each resonator is much larger than its electrical area, thus substantially reducing the dark current of the device. Furthermore, we show that our photonic architecture overcomes intrinsic limitations of the material, such as the drop of the electronic drift velocity with temperature, which constrains conventional geometries at cryogenic operation. Finally, the reduced physical area of the device and its increased responsivity allow us to take advantage of the intrinsic high-frequency response of the quantum detector at room temperature. By mixing the frequencies of two quantum-cascade lasers on the detector, which acts as a heterodyne receiver, we have measured a high-frequency signal, above four gigahertz (GHz). Therefore, these wide-band uncooled detectors could benefit technologies such as high-speed (gigabits per second) multichannel coherent data transfer and high-precision molecular spectroscopy. [ABSTRACT FROM AUTHOR]

Published

2018

16. Mixing Properties of Room Temperature Patch‐Antenna Receivers in a Mid‐Infrared (λ ≈ 9 µm) Heterodyne System.

Author

Bigioli, Azzurra, Gacemi, Djamal, Palaferri, Daniele, Todorov, Yanko, Vasanelli, Angela, Suffit, Stephan, Li, Lianhe, Davies, A. Giles, Linfield, Edmund H., Kapsalidis, Filippos, Beck, Mattias, Faist, Jérôme, and Sirtori, Carlo

Subjects

HETERODYNE detection, QUANTUM cascade lasers, OPTOELECTRONIC devices, QUANTUM wells, INFRARED detectors, TEMPERATURE

Abstract

A room‐temperature mid‐infrared (λ = 9 µm) heterodyne system based on high‐performance unipolar optoelectronic devices is presented. The local oscillator (LO) is a quantum cascade laser (QCL), while the receiver is an antenna coupled quantum well infrared photodetector optimized to operate in a microcavity configuration. Measurements of the saturation intensity show that these receivers have a linear response up to very high optical power, an essential feature for heterodyne detection. By providing an accurate passive stabilization of the LO, the heterodyne system reaches at room temperature the record value of noise equivalent power (NEP) of 30 pW at 9 µm and in the GHz frequency range. Finally, it is demonstrated that the injection of microwave signal into the receivers shifts the heterodyne beating over the large bandwidth of the devices. This mixing property is a unique valuable function of these devices for signal treatment in compact QCL‐based systems. [ABSTRACT FROM AUTHOR]

Published

2020

17. Manufacturing and characterization of amorphous silicon alloys passivation layers for silicon hetero-junction solar cells

Author

Palaferri, Daniele, thesis supervisor: Cavalcoli, Daniela, Palaferri, Daniele, and thesis supervisor: Cavalcoli, Daniela

Abstract

Nel presente lavoro di tesi magistrale sono stati depositati e caratterizzati film sottili (circa 10 nm) di silicio amorfo idrogenato (a-Si:H), studiando in particolare leghe a basso contenuto di ossigeno e carbonio. Tali layer andranno ad essere implementati come strati di passivazione per wafer di Si monocristallino in celle solari ad eterogiunzione HIT (heterojunctions with intrinsic thin layer), con le quali recentemente è stato raggiunto il record di efficienza pari a 24.7% . La deposizione è avvenuta mediante PECVD (plasma enhanced chemical vapour deposition). Tecniche di spettroscopia ottica, come FT-IR (Fourier transform infrared spectroscopy) e SE (spettroscopic ellipsometry) sono state utilizzate per analizzare le configurazioni di legami eteronucleari (Si-H, Si-O, Si-C) e le proprietà strutturali dei film sottili: un nuovo metodo è stato implementato per calcolare i contenuti atomici di H, O e C da misure ottiche. In tal modo è stato possibile osservare come una bassa incorporazione (< 10%) di ossigeno e carbonio sia sufficiente ad aumentare la porosità ed il grado di disordine a lungo raggio del materiale: relativamente a quest’ultimo aspetto, è stata sviluppata una nuova tecnica per determinare dagli spettri ellisometrici l’energia di Urbach, che esprime la coda esponenziale interna al gap in semiconduttori amorfi e fornisce una stima degli stati elettronici in presenza di disordine reticolare. Nella seconda parte della tesi sono stati sviluppati esperimenti di annealing isocrono, in modo da studiare i processi di cristallizzazione e di effusione dell’idrogeno, correlandoli con la degradazione delle proprietà optoelettroniche. L’analisi dei differenti risultati ottenuti studiando queste particolari leghe (a-SiOx e a-SiCy) ha permesso di concludere che solo con una bassa percentuale di ossigeno o carbonio, i.e. < 3.5 %, è possibile migliorare la risposta termica dello specifico layer, ritardando i fenomeni di degradazione di circa 50°C.

18. Manufacturing and characterization of amorphous silicon alloys passivation layers for silicon hetero-junction solar cells

Author

Palaferri, Daniele, thesis supervisor: Cavalcoli, Daniela, Palaferri, Daniele, and thesis supervisor: Cavalcoli, Daniela

Abstract

Nel presente lavoro di tesi magistrale sono stati depositati e caratterizzati film sottili (circa 10 nm) di silicio amorfo idrogenato (a-Si:H), studiando in particolare leghe a basso contenuto di ossigeno e carbonio. Tali layer andranno ad essere implementati come strati di passivazione per wafer di Si monocristallino in celle solari ad eterogiunzione HIT (heterojunctions with intrinsic thin layer), con le quali recentemente è stato raggiunto il record di efficienza pari a 24.7% . La deposizione è avvenuta mediante PECVD (plasma enhanced chemical vapour deposition). Tecniche di spettroscopia ottica, come FT-IR (Fourier transform infrared spectroscopy) e SE (spettroscopic ellipsometry) sono state utilizzate per analizzare le configurazioni di legami eteronucleari (Si-H, Si-O, Si-C) e le proprietà strutturali dei film sottili: un nuovo metodo è stato implementato per calcolare i contenuti atomici di H, O e C da misure ottiche. In tal modo è stato possibile osservare come una bassa incorporazione (< 10%) di ossigeno e carbonio sia sufficiente ad aumentare la porosità ed il grado di disordine a lungo raggio del materiale: relativamente a quest’ultimo aspetto, è stata sviluppata una nuova tecnica per determinare dagli spettri ellisometrici l’energia di Urbach, che esprime la coda esponenziale interna al gap in semiconduttori amorfi e fornisce una stima degli stati elettronici in presenza di disordine reticolare. Nella seconda parte della tesi sono stati sviluppati esperimenti di annealing isocrono, in modo da studiare i processi di cristallizzazione e di effusione dell’idrogeno, correlandoli con la degradazione delle proprietà optoelettroniche. L’analisi dei differenti risultati ottenuti studiando queste particolari leghe (a-SiOx e a-SiCy) ha permesso di concludere che solo con una bassa percentuale di ossigeno o carbonio, i.e. < 3.5 %, è possibile migliorare la risposta termica dello specifico layer, ritardando i fenomeni di degradazione di circa 50°C.