Your search keyword '"Greiffenberg, D."' showing total 210 results

1. Optimizing Charge Transport Simulation for Hybrid Pixel Detectors

Author

Xie, X., Barten, R., Bergamaschi, A., Braham, B., Brückner, M., Carulla, M., Dinapoli, R., Ebner, S., Ferjaoui, K., Fröjdh, E., Greiffenberg, D., Hasanaj, S., Heymes, J., Hinger, V., King, T., Kozlowski, P., Lopez-Cuenca, C., Mezza, D., Moustakas, K., Mozzanica, A., Paton, K. A., Ruder, C., Schmitt, B., Sieberer, P., Thattil, D., and Zhang, J.

Subjects

Physics - Instrumentation and Detectors

Abstract

To enhance the spatial resolution of the M\"ONCH 25 \textmu m pitch hybrid pixel detector, deep learning models have been trained using both simulation and measurement data. Challenges arise when comparing simulation-based deep learning models to measurement-based models for electrons, as the spatial resolution achieved through simulations is notably inferior to that from measurements. Discrepancies are also observed when directly comparing X-ray simulations with measurements, particularly in the spectral output of single pixels. These observations collectively suggest that current simulations require optimization. To address this, the dynamics of charge carriers within the silicon sensor have been studied using Monte Carlo simulations, aiming to refine the charge transport modeling. The simulation encompasses the initial generation of the charge cloud, charge cloud drift, charge diffusion and repulsion, and electronic noise. The simulation results were validated with measurements from the M\"ONCH detector for X-rays, and the agreement between measurements and simulations was significantly improved by accounting for the charge repulsion., Comment: Prepared for submission to JINST as a proceeding for 25th International Workshops on Radiation Imaging Detectors

Published

2024

2. Detection of MeV electrons using a charge integrating hybrid pixel detector

Author

Fröjdh, E., Baruffaldi, F., Bergamaschi, A., Carulla, M., Dinapoli, R., Greiffenberg, D., Heymes, J., Hinger, V., Ischebeck, R., Mathisen, S., McKenzie, J., Mezza, D., Moustakas, K., Mozzanica, A., Schmitt, B., and Zhang, J.

Subjects

Physics - Instrumentation and Detectors

Abstract

Electrons are emerging as a strong complement to X-rays for diffraction based studies. In this paper we investigate the performance of a JUNGFRAU detector with 320 um thick silicon sensor at a pulsed electron source. Originally developed for X-ray detection at free electron lasers, JUNGFRAU features a dynamic range of 120 MeV/pixel (implemented with in-pixel gain switching) which translated to about 1200 incident electrons per pixel and frame in the MeV region. We preset basic characteristics such as energy deposited per incident particle, resulting cluster size and spatial resolution along with dynamic (intensity) range scans. Measurements were performed at 4, 10 and 20 MeV/c. We compare the measurements with GEANT4 based simulations and extrapolate the results to different sensor thicknesses using these simulations.

Published

2022

3. Calibration methods for charge integrating detectors

Author

Mezza, D., Becker, J., Carraresi, L., Castoldi, A., Dinapoli, R., Goettlicher, P., Graafsma, H., Greiffenberg, D., Hirsemann, H., Klujev, A., Kuhn, M., Lange, S., Laurus, T., Maffessanti, S., Marras, A., Mozzanica, A., Poehlsen, J., Redford, S., Ruder, C., Schmitt, B., Sheviakov, I., Shi, X., Trunk, U., Vetter, S., Zhang, J., and Zimmer, M.

Published

2022

4. Challenges for the Adaptive Gain Integrating Pixel Detector (AGIPD) design due to the high intensity photon radiation environment at the European XFEL

Author

Becker, J., Bianco, L., Göttlicher, P., Graafsma, H., Hirsemann, H., Jack, S., Klyuev, A., Marras, S. Lange A., Trunk, U., Klanner, R., Schwandt, J., Zhang, J., Dinapoli, R., Greiffenberg, D., Henrich, B., Mozzanica, A., Schmitt, B., Shi, X., Gronewald, M., and Krüger, H.

Subjects

Physics - Instrumentation and Detectors

Abstract

The European X-ray Free Electron Laser (XFEL) is a new research facility currently under construction in Hamburg, Germany. With a pulse length of less than 100 fs and an extremely high luminosity of 27000 flashes per second the European XFEL will have a unique time structure that demands the development of new detectors tailored to the requirements imposed by the experiments while complying with the machine specific operation parameters. The Adaptive Gain Integrating Pixel Detector (AGIPD) is one response to the need for large 2D detectors, able to cope with the 4.5 MHz frame rate, as well as with the high dynamic range needed by XFEL experiments ranging from single photons to more than 10$^4$ 12 keV photons per pixel per pulse. In addition it has to withstand doses of up to 1 GGy over three years., Comment: revised version after review

Published

2013

5. Characterization of the AGIPD1.1 readout chip and improvements with respect to AGIPD1.0

Author

Mezza, D., Allahgholi, A., Becker, J., Delfs, A., Dinapoli, R., Goettlicher, P., Graafsma, H., Greiffenberg, D., Hirsemann, H., Klyuev, A., Kuhn, M., Lange, S., Laurus, T., Marras, A., Mozzanica, A., Poehlsen, J., Ruder, C., Schmitt, B., Schwandt, J., Sheviakov, I., Shi, X., Trunk, U., Zhang, J., and Zimmer, M.

Published

2019

6. Towards MYTHEN 3: Characterization of prototype chips

Author

Andrä, M., Dinapoli, R., Bergamaschi, A., Barten, R., Brückner, M., Chiriotti Alvarez, S., Fröjdh, E., Greiffenberg, D., Lopez-Cuenca, C., Mezza, D., Mozzanica, A., Redford, S., Ruder, C., Schmitt, B., Shi, X., Thattil, D., Tinti, G., Vetter, S., and Zhang, J.

Published

2019

7. Balancing gain and dynamic range in a 25 µm pitch hybrid pixel detector

Author

Heymes, J., primary, Barten, R., additional, Baruffaldi, F., additional, Bergamaschi, A., additional, Brückner, M., additional, Carulla, M., additional, Dinapoli, R., additional, Ebner, S., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Hasanaj, S., additional, Hinger, V., additional, King, T., additional, Kozłowski, P., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Moustakas, K., additional, Mozzanica, A., additional, Paton, K.A., additional, Ruder, C., additional, Schmitt, B., additional, Thattil, D., additional, Xie, X., additional, and Zhang, J., additional

Published

2024

8. High-Z sensors for synchrotron sources and FELs

Author

Greiffenberg, D., primary, Baruffaldi, F., additional, Bergamaschi, A., additional, Carulla, M., additional, Dinapoli, R., additional, Fröjdh, E., additional, Heymes, J., additional, Hinger, V., additional, Mezza, D., additional, Moustakas, K., additional, Mozzanica, A., additional, Paton, K. A., additional, Schmitt, B., additional, Xie, X., additional, and Zhang, J., additional

Published

2023

9. The new Matterhorn detector for 4th generation synchrotrons

Author

Mezza, D., primary, Barten, R., additional, Baruffaldi, F., additional, Bergamaschi, A., additional, Brueckner, M., additional, Carulla, M., additional, Dinapoli, R., additional, Ebner, S., additional, Froejd, E., additional, Greiffenberg, D., additional, Hasanaj, S., additional, Heymes, J., additional, Hinger, V., additional, King, T., additional, Kozlowski, P., additional, Lopez-Cuenca, C., additional, Mozzanica, A., additional, Moustakas, K., additional, Paton, K. A., additional, Ruder, C., additional, Schmitt, B., additional, Thattil, D., additional, Xie, X., additional, and Zhang, J., additional

Published

2023

10. Characterization of AGIPD1.0: The full scale chip

Author

Mezza, D., Allahgholi, A., Arino-Estrada, G., Bianco, L., Delfs, A., Dinapoli, R., Goettlicher, P., Graafsma, H., Greiffenberg, D., Hirsemann, H., Jack, S., Klanner, R., Klyuev, A., Krueger, H., Marras, A., Mozzanica, A., Poehlsen, J., Schmitt, B., Schwandt, J., Sheviakov, I., Shi, X., Trunk, U., Xia, Q., Zhang, J., and Zimmer, M.

Published

2016

11. Study of the internal quantum efficiency of FBK sensors with optimized entrance windows

Author

Carulla, M., primary, Centis Vignali, M., additional, Barten, R., additional, Baruffaldi, F., additional, Bergamaschi, A., additional, Borghi, G., additional, Boscardin, M., additional, Brückner, M., additional, Dinapoli, R., additional, Ebner, S., additional, Ficorella, F., additional, Fröjd, E., additional, Greiffenberg, D., additional, Hammad Ali, O., additional, Hasanaj, S., additional, Heymes, J., additional, Hinger, V., additional, King, T., additional, Kozlowski, P., additional, Lopez Cuenca, C., additional, Mezza, D., additional, Moustakas, K., additional, Mozzanica, A., additional, Paternoster, G., additional, Ronchin, S., additional, Ruder, C., additional, Schmitt, B., additional, Thattil, D., additional, and Zhang, J., additional

Published

2023

12. Detection of MeV electrons using a charge integrating hybrid pixel detector

Author

Fröjdh, E., primary, Baruffaldi, F., additional, Bergamaschi, A., additional, Carulla, M., additional, Dinapoli, R., additional, Greiffenberg, D., additional, Heymes, J., additional, Hinger, V., additional, Ischebeck, R., additional, Mathisen, S., additional, McKenzie, J., additional, Mezza, D., additional, Moustakas, K., additional, Mozzanica, A., additional, Schmitt, B., additional, and Zhang, J., additional

Published

2022

13. First demonstration of on-chip interpolation using a single photon counting microstrip detector

Author

Bergamaschi, A., primary, Andrä, M., additional, Barten, R., additional, Baruffaldi, F., additional, Brückner, M., additional, Carulla, M., additional, Chiriotti, S., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Hasanaj, S., additional, Heymes, J., additional, Hinger, V., additional, Kozlowski, P., additional, Cuenca, C.L., additional, Mezza, D., additional, Mozzanica, A., additional, Moustakas, K., additional, Ruder, C., additional, Schmitt, B., additional, Thattil, D., additional, and Zhang, J., additional

Published

2022

14. Development of LGAD sensors with a thin entrance window for soft X-ray detection

Author

Zhang, J., primary, Barten, R., additional, Baruffaldi, F., additional, Bergamaschi, A., additional, Borghi, G., additional, Boscardin, M., additional, Brückner, M., additional, Carulla, M., additional, Centis Vignali, M., additional, Dinapoli, R., additional, Ebner, S., additional, Ficorella, F., additional, Fröjj¨dh, E., additional, Greiffenberg, D., additional, Hammad Ali, O., additional, Heymes, J., additional, Hasanaj, S., additional, Hinger, V., additional, King, T., additional, Kozlowski, P., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Moustakas, K., additional, Mozzanica, A., additional, Paternoster, G., additional, Ronchin, S., additional, Ruder, C., additional, Schmitt, B., additional, and Thattil, D., additional

Published

2022

15. Advancing the JUNGFRAU detector toward low-energy X-ray applications

Author

Hinger, V., primary, al Haddad, A., additional, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Carulla, M., additional, Chiriotti-Alvarez, S., additional, Dinapoli, R., additional, Ebner, S., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Hasanaj, S., additional, King, T., additional, Kozlowski, P., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Moustakas, K., additional, Mozzanica, A., additional, Ozerov, D., additional, Ruder, C., additional, Schmitt, B., additional, Schnorr, K.A., additional, Thattil, D., additional, and Zhang, J., additional

Published

2022

16. Front end electronics for European XFEL sensor: The AGIPD project

Author

Marras, A., Trunk, U., Klyuev, A., Becker, J., Graafsma, H., Shi, X., Greiffenberg, D., and Schmitt, B.

Published

2013

17. Observation of radiation damage in CdTe Schottky sensors created by 20 keV photons

Author

Meyer, M., primary, Andrä, M., additional, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Busca, P., additional, Carulla Areste, M., additional, Chiriotti, S., additional, Dinapoli, R., additional, Fajardo, P., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Heymes, J., additional, Hinger, V., additional, Kozlowski, P., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Mozzanica, A., additional, Redford, S., additional, Ruat, M., additional, Ruder, C., additional, Schmitt, B., additional, Thattil, D., additional, Tinti, G., additional, Vetter, S., additional, and Zhang, J., additional

Published

2022

18. Preliminary characterisation of CdTe M–π–n diode structures

Author

Greiffenberg, D., Fauler, A., Zwerger, A., Baumbach, T., and Fiederle, M.

Published

2011

19. High-spatial resolution measurements with a GaAs:Cr sensor using the charge integrating MÖNCH detector with a pixel pitch of 25 μm

Author

Chiriotti, S., primary, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Carulla, M., additional, Chsherbakov, I., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Hasanaj, S., additional, Hinger, V., additional, King, T., additional, Kozlowski, P., additional, Lopez-Cuenca, C., additional, Lozinskaya, A., additional, Marone, F., additional, Mezza, D., additional, Moustakas, K., additional, Mozzanica, A., additional, Ruder, C., additional, Schmitt, B., additional, Thattil, D., additional, Tolbanov, O., additional, Tyazhev, A., additional, Zarubin, A., additional, and Zhang, J., additional

Published

2022

20. Electron detection with CdTe and GaAs sensors using the charge integrating hybrid pixel detector JUNGFRAU

Author

Fröjdh, E., primary, Abrahams, J.P., additional, Andrä, M., additional, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Chiriotti, S., additional, Dinapoli, R., additional, Greiffenberg, D., additional, Hinger, V., additional, Lovacik, L., additional, King, T., additional, Kozlowski, P., additional, Lopez-Cuenca, C., additional, Jürgen, M., additional, Mezza, D., additional, Mozzanica, A., additional, Ruder, C., additional, Schmitt, B., additional, Hasanaj, S., additional, Thattil, D., additional, van Genderen, E., additional, Vetter, S., additional, and Zhang, J., additional

Published

2022

21. Detection efficiency of ATLAS-MPX detectors with respect to neutrons

Author

Greiffenberg, D., Fiederle, M., Vykydal, Z., Král, V., Jakůbek, J., Holý, T., Pospíšil, S., Maneuski, D., O’Shea, V., Suk, M., Králík, M., Lebel, C., and Leroy, C.

Published

2009

22. The Medipix2-based network for measurement of spectral characteristics and composition of radiation in ATLAS detector

Author

Vykydal, Z., Bouchami, J., Campbell, M., Dolezal, Z., Fiederle, M., Greiffenberg, D., Gutierrez, A., Heijne, E., Holy, T., Idarraga, J., Jakubek, J., Kral, V., Kralik, M., Lebel, C., Leroy, C., Llopart, X., Maneuski, D., Nessi, M., O’Shea, V., Platkevic, M., Pospisil, S., Suk, M., Tlustos, L., Vichoudis, P., Visschers, J., Wilhelm, I., and Zemlicka, J.

Published

2009

23. Energy calibration measurements of MediPix2

Author

Fiederle, M., Greiffenberg, D., Idárraga, J., Jakůbek, J., Král, V., Lebel, C., Leroy, C., Lord, G., Pospíšil, S., Sochor, V., and Suk, M.

Published

2008

24. Growth of thick films CdTe from the vapor phase

Author

Sorgenfrei, R., Greiffenberg, D., Bachem, K.H., Kirste, L., Zwerger, A., and Fiederle, M.

Published

2008

25. Growth of thick films CdTe from the vapor phase

Author

Greiffenberg, D., Sorgenfrei, R., Bachem, K.H., and Fiederle, M.

Subjects

Crystallography -- Analysis, Thick films -- Analysis, Business, Electronics, Electronics and electrical industries

Abstract

100 [micro]m thick films of CdTe were grown on semi-insulating (100) GaAs substrates by Physical Vapor Transport (PVT) in a modified Molecular Beam Epitaxy facility. The grown layers were highly oriented as revealed from X-ray pole figure measurements. Temperature- and intensity-dependent photoluminescence measurements were taken before and after the chemical removal of the substrate to determine the effect of the GaAs substrate and to estimate the crystallographic quality of the layers. Current-voltage characteristics were performed to obtain the resistitivity of the layers with [10.sup.8] [OMEGA]cm. Index Terms--CdTe, MBE, photoluminescence, radiation detector, thick films, x-ray diffraction.

Published

2007

26. Design and first tests of the Gotthard-II readout ASIC for the European X-ray Free-Electron Laser

Author

Zhang, J., primary, Andrä, M., additional, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Chiriotti-Alvarez, S., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Kozlowski, P., additional, Kuster, M., additional, Lopez-Cuenca, C., additional, Meyer, M., additional, Mezza, D., additional, Mozzanica, A., additional, Ramilli, M., additional, Ruder, C., additional, Schmitt, B., additional, Shi, X., additional, Thattil, D., additional, Tinti, G., additional, Turcato, M., additional, and Vetter, S., additional

Published

2021

27. First full dynamic range scan of the JUNGFRAU detector performed at an XFEL with an accurate intensity reference

Author

Redford, S., primary, Andrä, M., additional, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Chiriotti, S., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Kim, K.S., additional, Lee, J.H., additional, Lopez-Cuenca, C., additional, Meyer, M., additional, Mezza, D., additional, Mozzanica, A., additional, Park, S.-Y., additional, Ruder, C., additional, Schmitt, B., additional, Shi, X., additional, Thattil, D., additional, Tinti, G., additional, Vetter, S., additional, and Zhang, J., additional

Published

2020

28. High-spatial resolution measurements with a GaAs:Cr sensor using the charge integrating MĂ–NCH detector with a pixel pitch of 25 ÎĽm.

Author

Chiriotti, S., Barten, R., Bergamaschi, A., Brückner, M., Carulla, M., Chsherbakov, I., Dinapoli, R., Fröjdh, E., Greiffenberg, D., Hasanaj, S., Hinger, V., King, T., Kozlowski, P., Lopez-Cuenca, C., Lozinskaya, A., Marone, F., Mezza, D., Moustakas, K., Mozzanica, A., and Ruder, C.

Published

2022

29. Segmented flow generator for serial crystallography at the European X-ray free electron laser.

Author

Echelmeier, A, Cruz Villarreal, J, Messerschmidt, M, Kim, D, Coe, JD, Thifault, D, Botha, S, Egatz-Gomez, A, Gandhi, S, Brehm, G, Conrad, CE, Hansen, DT, Madsen, C, Bajt, S, Meza-Aguilar, JD, Oberthür, D, Wiedorn, MO, Fleckenstein, H, Mendez, D, Knoška, J, Martin-Garcia, JM, Hu, H, Lisova, S, Allahgholi, A, Gevorkov, Y, Ayyer, K, Aplin, S, Ginn, HM, Graafsma, H, Morgan, AJ, Greiffenberg, D, Klujev, A, Laurus, T, Poehlsen, J, Trunk, U, Mezza, D, Schmidt, B, Kuhn, M, Fromme, R, Sztuk-Dambietz, J, Raab, N, Hauf, S, Silenzi, A, Michelat, T, Xu, C, Danilevski, C, Parenti, A, Mekinda, L, Weinhausen, B, Mills, G, Vagovic, P, Kim, Y, Kirkwood, H, Bean, R, Bielecki, J, Stern, S, Giewekemeyer, K, Round, AR, Schulz, J, Dörner, K, Grant, TD, Mariani, V, Barty, A, Mancuso, AP, Weierstall, U, Spence, JCH, Chapman, HN, Zatsepin, N, Fromme, P, Kirian, RA, Ros, A, Echelmeier, A, Cruz Villarreal, J, Messerschmidt, M, Kim, D, Coe, JD, Thifault, D, Botha, S, Egatz-Gomez, A, Gandhi, S, Brehm, G, Conrad, CE, Hansen, DT, Madsen, C, Bajt, S, Meza-Aguilar, JD, Oberthür, D, Wiedorn, MO, Fleckenstein, H, Mendez, D, Knoška, J, Martin-Garcia, JM, Hu, H, Lisova, S, Allahgholi, A, Gevorkov, Y, Ayyer, K, Aplin, S, Ginn, HM, Graafsma, H, Morgan, AJ, Greiffenberg, D, Klujev, A, Laurus, T, Poehlsen, J, Trunk, U, Mezza, D, Schmidt, B, Kuhn, M, Fromme, R, Sztuk-Dambietz, J, Raab, N, Hauf, S, Silenzi, A, Michelat, T, Xu, C, Danilevski, C, Parenti, A, Mekinda, L, Weinhausen, B, Mills, G, Vagovic, P, Kim, Y, Kirkwood, H, Bean, R, Bielecki, J, Stern, S, Giewekemeyer, K, Round, AR, Schulz, J, Dörner, K, Grant, TD, Mariani, V, Barty, A, Mancuso, AP, Weierstall, U, Spence, JCH, Chapman, HN, Zatsepin, N, Fromme, P, Kirian, RA, and Ros, A

Abstract

Serial femtosecond crystallography (SFX) with X-ray free electron lasers (XFELs) allows structure determination of membrane proteins and time-resolved crystallography. Common liquid sample delivery continuously jets the protein crystal suspension into the path of the XFEL, wasting a vast amount of sample due to the pulsed nature of all current XFEL sources. The European XFEL (EuXFEL) delivers femtosecond (fs) X-ray pulses in trains spaced 100 ms apart whereas pulses within trains are currently separated by 889 ns. Therefore, continuous sample delivery via fast jets wastes >99% of sample. Here, we introduce a microfluidic device delivering crystal laden droplets segmented with an immiscible oil reducing sample waste and demonstrate droplet injection at the EuXFEL compatible with high pressure liquid delivery of an SFX experiment. While achieving ~60% reduction in sample waste, we determine the structure of the enzyme 3-deoxy-D-manno-octulosonate-8-phosphate synthase from microcrystals delivered in droplets revealing distinct structural features not previously reported.

Published

2020

30. Segmented flow generator for serial crystallography at the European X-ray free electron laser

Author

Echelmeier, A., Cruz Villarreal, J., Messerschmidt, M., Kim, D., Coe, J. D., Thifault, D., Botha, S., Egatz-Gomez, A., Gandhi, S., Brehm, G., Conrad, C. E., Hansen, D. T., Madsen, C., Bajt, S., Meza-Aguilar, J. D., Oberthür, D., Wiedorn, M. O., Fleckenstein, H., Mendez, D., Knoška, J., Martin-Garcia, J. M., Hu, H., Lisova, S., Allahgholi, A., Gevorkov, Y., Ayyer, K., Aplin, S., Ginn, H. M., Graafsma, H., Morgan, A. J., Greiffenberg, D., Klujev, A., Laurus, T., Poehlsen, J., Trunk, U., Mezza, D., Schmidt, B., Kuhn, M., Fromme, R., Sztuk-Dambietz, J., Raab, N., Hauf, S., Silenzi, A., Michelat, T., Xu, C., Danilevski, C., Parenti, A., Mekinda, L., Weinhausen, B., Mills, G., Vagovic, P., Kim, Y., Kirkwood, H., Bean, R., Bielecki, J., Stern, S., Giewekemeyer, K., Round, A. R., Schulz, J., Dörner, K., Grant, T. D., Mariani, V., Barty, A., Mancuso, A. P., Weierstall, U., Spence, J. C. H., Chapman, H. N., Zatsepin, N., Fromme, P., Kirian, R. A., Ros, A., Echelmeier, A., Cruz Villarreal, J., Messerschmidt, M., Kim, D., Coe, J. D., Thifault, D., Botha, S., Egatz-Gomez, A., Gandhi, S., Brehm, G., Conrad, C. E., Hansen, D. T., Madsen, C., Bajt, S., Meza-Aguilar, J. D., Oberthür, D., Wiedorn, M. O., Fleckenstein, H., Mendez, D., Knoška, J., Martin-Garcia, J. M., Hu, H., Lisova, S., Allahgholi, A., Gevorkov, Y., Ayyer, K., Aplin, S., Ginn, H. M., Graafsma, H., Morgan, A. J., Greiffenberg, D., Klujev, A., Laurus, T., Poehlsen, J., Trunk, U., Mezza, D., Schmidt, B., Kuhn, M., Fromme, R., Sztuk-Dambietz, J., Raab, N., Hauf, S., Silenzi, A., Michelat, T., Xu, C., Danilevski, C., Parenti, A., Mekinda, L., Weinhausen, B., Mills, G., Vagovic, P., Kim, Y., Kirkwood, H., Bean, R., Bielecki, J., Stern, S., Giewekemeyer, K., Round, A. R., Schulz, J., Dörner, K., Grant, T. D., Mariani, V., Barty, A., Mancuso, A. P., Weierstall, U., Spence, J. C. H., Chapman, H. N., Zatsepin, N., Fromme, P., Kirian, R. A., and Ros, A.

Abstract

Serial femtosecond crystallography (SFX) with X-ray free electron lasers (XFELs) allows structure determination of membrane proteins and time-resolved crystallography. Common liquid sample delivery continuously jets the protein crystal suspension into the path of the XFEL, wasting a vast amount of sample due to the pulsed nature of all current XFEL sources. The European XFEL (EuXFEL) delivers femtosecond (fs) X-ray pulses in trains spaced 100 ms apart whereas pulses within trains are currently separated by 889 ns. Therefore, continuous sample delivery via fast jets wastes >99% of sample. Here, we introduce a microfluidic device delivering crystal laden droplets segmented with an immiscible oil reducing sample waste and demonstrate droplet injection at the EuXFEL compatible with high pressure liquid delivery of an SFX experiment. While achieving ~60% reduction in sample waste, we determine the structure of the enzyme 3-deoxy-D-manno-octulosonate-8-phosphate synthase from microcrystals delivered in droplets revealing distinct structural features not previously reported.

Published

2020

31. Towards MYTHEN III - prototype characterisation of MYTHEN III.0.2

Author

Andrä, M., primary, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Casati, N., additional, Cervellino, A., additional, Chiriotti, S., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Lopez-Cuenca, C., additional, Meister, D., additional, Meyer, M., additional, Mezza, D., additional, Mozzanica, A., additional, Redford, S., additional, Ruder, C., additional, Schmitt, B., additional, Shi, X., additional, Thattil, D., additional, Tinti, G., additional, Vetter, S., additional, and Zhang, J., additional

Published

2019

32. Characterization of GaAs:Cr sensors using the charge-integrating JUNGFRAU readout chip

Author

Greiffenberg, D., primary, Andrä, M., additional, Barten, R., additional, Bergamaschi, A., additional, Busca, P., additional, Brückner, M., additional, Alvarez, S. Chiriotti, additional, Chsherbakov, I., additional, Dinapoli, R., additional, Fajardo, P., additional, Fröjdh, E., additional, Lopez-Cuenca, C., additional, Lozinskaya, A., additional, Meyer, M., additional, Mezza, D., additional, Mozzanica, A., additional, Redford, S., additional, Ruat, M., additional, Ruder, C., additional, Schmitt, B., additional, Shi, X., additional, Thattil, D., additional, Tinti, G., additional, Tolbanov, O., additional, Tyazhev, A., additional, Vetter, S., additional, Zarubin, A., additional, and Zhang, J., additional

Published

2019

33. Operation and performance of the JUNGFRAU photon detector during first FEL and synchrotron experiments

Author

Redford, S., primary, Andrä, M., additional, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Chiriotti, S., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Leonarski, F., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Mozzanica, A., additional, Ruder, C., additional, Schmitt, B., additional, Shi, X., additional, Thattil, D., additional, Tinti, G., additional, Vetter, S., additional, and Zhang, J., additional

Published

2018

34. The JUNGFRAU Detector for Applications at Synchrotron Light Sources and XFELs

Author

Mozzanica, A., primary, Andrä, M., additional, Barten, R., additional, Bergamaschi, A., additional, Chiriotti, S., additional, Brückner, M., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Leonarski, F., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Redford, S., additional, Ruder, C., additional, Schmitt, B., additional, Shi, X., additional, Thattil, D., additional, Tinti, G., additional, Vetter, S., additional, and Zhang, J., additional

Published

2018

35. The MÖNCH Detector for Soft X-ray, High-Resolution, and Energy Resolved Applications

Author

Bergamaschi, A., primary, Andrä, M., additional, Barten, R., additional, Borca, C., additional, Brückner, M., additional, Chiriotti, S., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Huthwelker, T., additional, Kleibert, A., additional, Langer, M., additional, Lebugle, M., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Mozzanica, A., additional, Raabe, J., additional, Redford, S., additional, Ruder, C., additional, Scagnoli, V., additional, Schmitt, B., additional, Shi, X., additional, Staub, U., additional, Thattil, D., additional, Tinti, G., additional, Vaz, C. F., additional, Vetter, S., additional, Vila-Comamala, J., additional, and Zhang, J., additional

Published

2018

36. Hybrid Detectors for High Resolution Imaging.

Author

Bergamaschi, A., primary, Andra, M., additional, Barten, R., additional, Bruckner, M., additional, Chiriotti, S., additional, David, C., additional, Dinapoli, R., additional, Frojdh, E., additional, Greiffenberg, D., additional, Lebugle, M., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Mozzanica, A., additional, Ramilli, M., additional, Redford, S., additional, Ruder, C., additional, Schmitt, B., additional, Shi, X., additional, Thattil, D., additional, Tinti, G., additional, Vetter, S., additional, and Zhang, J., additional

Published

2018

37. Photon counting microstrip X-ray detectors with GaAs sensors

Author

Ruat, M., primary, Andrä, M., additional, Bergamaschi, A., additional, Barten, R., additional, Brückner, M., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Lopez-Cuenca, C., additional, Lozinskaya, A.D., additional, Mezza, D., additional, Mozzanica, A., additional, Novikov, V.A., additional, Ramilli, M., additional, Redford, S., additional, Ruder, C., additional, Schmitt, B., additional, Shi, X., additional, Thattil, D., additional, Tinti, G., additional, Tolbanov, O.P., additional, Tyazhev, A., additional, Vetter, S., additional, Zarubin, A.N., additional, and Zhang, J., additional

Published

2018

38. Towards Gotthard-II: development of a silicon microstrip detector for the European X-ray Free-Electron Laser

Author

Zhang, J., primary, Andrä, M., additional, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Mozzanica, A., additional, Ramilli, M., additional, Redford, S., additional, Ruat, M., additional, Ruder, C., additional, Schmitt, B., additional, Shi, X., additional, Thattil, D., additional, Tinti, G., additional, Turcato, M., additional, and Vetter, S., additional

Published

2018

39. First full dynamic range calibration of the JUNGFRAU photon detector

Author

Redford, S., primary, Andrä, M., additional, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Mozzanica, A., additional, Ramilli, M., additional, Ruat, M., additional, Ruder, C., additional, Schmitt, B., additional, Shi, X., additional, Thattil, D., additional, Tinti, G., additional, Vetter, S., additional, and Zhang, J., additional

Published

2018

40. Performance evaluation of the analogue front-end and ADC prototypes for the Gotthard-II development

Author

Zhang, J., primary, Andrä, M., additional, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Mozzanica, A., additional, Ramilli, M., additional, Redford, S., additional, Ruat, M., additional, Ruder, C., additional, Schmitt, B., additional, Shi, X., additional, Thattil, D., additional, Tinti, G., additional, Turcato, M., additional, and Vetter, S., additional

Published

2017

41. The EIGER detector for low-energy electron microscopy and photoemission electron microscopy

Author

Tinti, G., primary, Marchetto, H., additional, Vaz, C. A. F., additional, Kleibert, A., additional, Andrä, M., additional, Barten, R., additional, Bergamaschi, A., additional, Brückner, M., additional, Cartier, S., additional, Dinapoli, R., additional, Franz, T., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Mozzanica, A., additional, Nolting, F., additional, Ramilli, M., additional, Redford, S., additional, Ruat, M., additional, Ruder, Ch., additional, Schädler, L., additional, Schmidt, Th., additional, Schmitt, B., additional, Schütz, F., additional, Shi, X., additional, Thattil, D., additional, Vetter, S., additional, and Zhang, J., additional

Published

2017

42. AGIPD: a multi megapixel, multi megahertz X-ray camera for the European XFEL

Author

Trunk, Ulrich, additional, Allahgholi, A., additional, Becker, J., additional, Delfs, A., additional, Dinapoli, R., additional, Göttlicher, P., additional, Graafsma, H., additional, Greiffenberg, D., additional, Hirsemann, H., additional, Jack, S., additional, Klyuev, A., additional, Krueger, H., additional, Lange, S., additional, Laurus, T., additional, Marras, A., additional, Mezza, D., additional, Mozzanica, A., additional, Poehlsen, J., additional, Rah, S., additional, Schmitt, B., additional, Schwandt, J., additional, Sheviakov, I., additional, Shi, X., additional, Xia, Q., additional, Zhang, J., additional, and Zimmer, M., additional

Published

2017

43. AGIPD : A multi megapixel, multi megahertz X-ray camera for the European XFEL

Author

Trunk, Ulrich, Allahgholi, A., Becker, J., Delfs, A., Dinapoli, R., Göttlicher, P., Graafsma, Heinz, Greiffenberg, D., Hirsemann, H., Jack, S., Klyuev, A., Krueger, H., Lange, S., Laurus, T., Marras, A., Mezza, D., Mozzanica, A., Poehlsen, J., Rah, S., Schmitt, B., Schwandt, J., Sheviakov, I., Shi, X., Xia, Q., Zhang, J., Zimmer, M., Trunk, Ulrich, Allahgholi, A., Becker, J., Delfs, A., Dinapoli, R., Göttlicher, P., Graafsma, Heinz, Greiffenberg, D., Hirsemann, H., Jack, S., Klyuev, A., Krueger, H., Lange, S., Laurus, T., Marras, A., Mezza, D., Mozzanica, A., Poehlsen, J., Rah, S., Schmitt, B., Schwandt, J., Sheviakov, I., Shi, X., Xia, Q., Zhang, J., and Zimmer, M.

Abstract

AGIPD is a hybrid pixel detector developed by DESY, PSI, and the Universities of Bonn and Hamburg. It is targeted for use at the European XFEL, a source with unique properties: a train of up to 2700 pulses is repeated at 10 Hz rate. The pulses inside a train are ≤100fs long and separated by 220 ns, containing up to 1012 photons of 12.4 keV each. The readout ASICs with 64 x 64 pixels each have to cope with these properties: Single photon sensitivity and a dynamic range up to 104 photons/pixel in the same image as well as storage for as many as possible images of a pulse train for delayed readout, prior to the next train. The high impinging photon flux also requires a very radiation hard design of sensor and ASIC, which uses 130 nm CMOS technology and radiation tolerant techniques. The signal path inside a pixel of the ASIC consists of a charge sensitive preamplifier with 3 individual gains, adaptively selected by a subsequent discriminator. The preamp also feeds to a correlated double sampling stage, which writes to an analogue memory to record 352 frames. It is random-access, so it can be used most efficiently by overwriting bad or empty images. Encoded gain information is stored to a similar memory. Readout of these memories is via a common charge sensitive amplifier in each pixel, and multiplexers on four differential ports. Operation of the ASIC is controlled via a command interface, using 3 LVDS lines. It also serves to configure the chip's operational parameters and timings.

Published

2017

44. Study of the signal response of the MÖNCH 25μm pitch hybrid pixel detector at different photon absorption depths

Author

Cartier, S, Bergamaschi, A, Dinapoli, R, Greiffenberg, D, Johnson, I, Jungmann-Smith, J H, Mezza, D, Mozzanica, A, Shi, X, Tinti, G, Schmitt, B, Stampanoni, M, and University of Zurich

Subjects

170 Ethics, 3105 Instrumentation, 610 Medicine & health, 10237 Institute of Biomedical Engineering, 2610 Mathematical Physics

Published

2015

45. Measurements with MÖNCH, a 25 μm pixel pitch hybrid pixel detector

Author

Ramilli, M., primary, Bergamaschi, A., additional, Andrae, M., additional, Brückner, M., additional, Cartier, S., additional, Dinapoli, R., additional, Fröjdh, E., additional, Greiffenberg, D., additional, Hutwelker, T., additional, Lopez-Cuenca, C., additional, Mezza, D., additional, Mozzanica, A., additional, Ruat, M., additional, Redford, S., additional, Schmitt, B., additional, Shi, X., additional, Tinti, G., additional, and Zhang, J., additional

Published

2017

46. Detector developments at DESY

Author

Wunderer, C. B., Allahgholi, A., Bayer, M., Bianco, L., Correa, J., Delfs, A., Gottlicher, P., Hirsemann, H., Jack, S., Klyuev, A., Lange, S., Marras, A., Niemann, M., Pithan, F., Reza, Salim, Sheviakov, I., Smoljanin, S., Tennert, M., Trunk, U., Xia, Q., Zhang, J., Zimmer, M., Das, D., Guerrini, N., Marsh, B., Sedgwick, I., Turchetta, R., Cautero, G., Giuressi, D., Menk, R., Khromova, A., Pinaroli, G., Stebel, L., Marchal, J., Pedersen, U., Rees, N., Steadman, P., Sussmuth, M., Tartoni, N., Yousef, H., Hyun, H., Kim, K., Rah, S., Dinapoli, R., Greiffenberg, D., Mezza, D., Mozzanica, A., Schmitt, B., Shi, X., Krueger, H., Klanner, R., Schwandt, J., Graafsma, Heinz, Wunderer, C. B., Allahgholi, A., Bayer, M., Bianco, L., Correa, J., Delfs, A., Gottlicher, P., Hirsemann, H., Jack, S., Klyuev, A., Lange, S., Marras, A., Niemann, M., Pithan, F., Reza, Salim, Sheviakov, I., Smoljanin, S., Tennert, M., Trunk, U., Xia, Q., Zhang, J., Zimmer, M., Das, D., Guerrini, N., Marsh, B., Sedgwick, I., Turchetta, R., Cautero, G., Giuressi, D., Menk, R., Khromova, A., Pinaroli, G., Stebel, L., Marchal, J., Pedersen, U., Rees, N., Steadman, P., Sussmuth, M., Tartoni, N., Yousef, H., Hyun, H., Kim, K., Rah, S., Dinapoli, R., Greiffenberg, D., Mezza, D., Mozzanica, A., Schmitt, B., Shi, X., Krueger, H., Klanner, R., Schwandt, J., and Graafsma, Heinz

Abstract

With the increased brilliance of state-of-the-art synchrotron radiation sources and the advent of free-electron lasers (FELs) enabling revolutionary science with EUV to X-ray photons comes an urgent need for suitable photon imaging detectors. Requirements include high frame rates, very large dynamic range, single-photon sensitivity with low probability of false positives and (multi)-megapixels. At DESY, one ongoing development project-in collaboration with RAL/STFC, Elettra Sincrotrone Trieste, Diamond, and Pohang Accelerator Laboratory-is the CMOS-based soft X-ray imager PERCIVAL. PERCIVAL is a monolithic active-pixel sensor back-thinned to access its primary energy range of 250 eV to 1 keV with target efficiencies above 90%. According to preliminary specifications, the roughly 10 cm × 10 cm, 3.5k × 3.7k monolithic sensor will operate at frame rates up to 120 Hz (commensurate with most FELs) and use multiple gains within 27 μm pixels to measure 1 to ∼ 100000 (500 eV) simultaneously arriving photons. DESY is also leading the development of the AGIPD, a high-speed detector based on hybrid pixel technology intended for use at the European XFEL. This system is being developed in collaboration with PSI, University of Hamburg, and University of Bonn. The AGIPD allows singlepulse imaging at 4.5 MHz frame rate into a 352-frame buffer, with a dynamic range allowing single-photon detection and detection of more than 10000 photons at 12.4 keV in the same image. Modules of 65k pixels each are configured to make up (multi)megapixel cameras. This review describes the AGIPD and the PERCIVAL concepts and systems, including some recent results and a summary of their current status. It also gives a short overview over other FEL-relevant developments where the Photon Science Detector Group at DESY is involved. © 2016 International Union of Crystallography., Conference Paper

Published

2016

47. New calibration circuitry and concept for AGIPD

Author

Mezza, D., Allahgholi, A., Delfs, A., Dinapoli, R., Goettlicher, P., Graafsma, Heinz, Greiffenberg, D., Hirsemann, H., Klyuev, A., Laurus, T., Marras, A., Mozzanica, A., Perova, I., Poehlsen, J., Schmitt, B., Sheviakov, I., Shi, X., Trunk, U., Xia, Q., Zhang, J., Zimmer, M., Mezza, D., Allahgholi, A., Delfs, A., Dinapoli, R., Goettlicher, P., Graafsma, Heinz, Greiffenberg, D., Hirsemann, H., Klyuev, A., Laurus, T., Marras, A., Mozzanica, A., Perova, I., Poehlsen, J., Schmitt, B., Sheviakov, I., Shi, X., Trunk, U., Xia, Q., Zhang, J., and Zimmer, M.

Abstract

AGIPD (adaptive gain integrating pixel detector) is a detector system developed for the European XFEL (XFEL.EU), which is currently being constructed in Hamburg, Germany. The XFEL.EU will operate with bunch trains at a repetition rate of 10 Hz. Each train consists of 2700 bunches with a temporal separation of 220 ns corresponding to a rate of 4.5 MHz. Each photon pulse has a duration of < 100 fs (rms) and contains up to 1012 photons in an energy range between 0.25 and 25 keV . In order to cope with the large dynamic range, the first stage of each bump-bonded AGIPD ASIC is a charge sensitive preamplifier with three different gain settings that are dynamically switched during the charge integration. Dynamic gain switching allows single photon resolution in the high gain stage and can cover a dynamic range of 104 × 12.4 keV photons in the low gain stage. The burst structure of the bunch trains forces to have an intermediate in-pixel storage of the signals. The full scale chip has 352 in-pixel storage cells inside the pixel area of 200 × 200 μm2. This contribution will report on the measurements done with the new calibration circuitry of the AGIPD1.1 chip (without sensor). These results will be compared with the old version of the chip (AGIPD1.0). A new calibration method (that is not AGIPD specific) will also be shown.

Published

2016

48. The adaptive gain integrating pixel detector

Author

Allahgholi, A., Becker, J., Bianco, L., Bradford, R., Delfs, A., Dinapoli, R., Goettlicher, P., Gronewald, M., Graafsma, Heinz, Greiffenberg, D., Henrich, B. H., Hirsemann, H., Jack, S., Klanner, R., Klyuev, A., Krueger, H., Lange, S., Marras, A., Mezza, D., Mozzanica, A., Perova, I., Xia, Q., Schmitt, B., Schwandt, J., Sheviakov, I., Shi, X., Trunk, U., Zhang, J., Allahgholi, A., Becker, J., Bianco, L., Bradford, R., Delfs, A., Dinapoli, R., Goettlicher, P., Gronewald, M., Graafsma, Heinz, Greiffenberg, D., Henrich, B. H., Hirsemann, H., Jack, S., Klanner, R., Klyuev, A., Krueger, H., Lange, S., Marras, A., Mezza, D., Mozzanica, A., Perova, I., Xia, Q., Schmitt, B., Schwandt, J., Sheviakov, I., Shi, X., Trunk, U., and Zhang, J.

Abstract

The adaptive gain integrating pixel detector (AGIPD) is a development of a collaboration between Deustsches Elektronen-Synchrotron (DESY), the Paul-Scherrer-Institute (PSI), the University of Hamburg and the University of Bonn. The detector is designed to cope with the demanding challenges of the European XFEL. Therefore it comes along with an adaptive gain stage allowing a high dynamic range, spanning from single photon sensitivity to 10(4) x 12.4 keV photons and 352 analogue memory cells per pixel. The aim of this report is to briefly explain the concepts of the AGIPD electronics and mechanics and then present recent experiments demonstrating the functionality of its key features.

Published

2016

49. Front end ASIC for AGIPD, a high dynamic range fast detector for the European XFEL

Author

Allahgholi, A., Becker, J., Bianco, L., Delfs, A., Dinapoli, R., Arino-Estrada, G., Goettlicher, P., Graafsma, Heinz, Greiffenberg, D., Hirsemann, H., Jack, S., Klanner, R., Klyuev, A., Krueger, H., Lange, S., Marras, A., Mezza, D., Mozzanica, A., Poehlsen, J., Rah, S., Xia, Q., Schmitt, B., Schwandt, J., Sheviakov, I., Shi, X., Smoljanin, S., Trunk, U., Zhang, J., Zimmer, M., Allahgholi, A., Becker, J., Bianco, L., Delfs, A., Dinapoli, R., Arino-Estrada, G., Goettlicher, P., Graafsma, Heinz, Greiffenberg, D., Hirsemann, H., Jack, S., Klanner, R., Klyuev, A., Krueger, H., Lange, S., Marras, A., Mezza, D., Mozzanica, A., Poehlsen, J., Rah, S., Xia, Q., Schmitt, B., Schwandt, J., Sheviakov, I., Shi, X., Smoljanin, S., Trunk, U., Zhang, J., and Zimmer, M.

Abstract

The Adaptive Gain Integrating Pixel Detector (AGIPD) is a hybrid pixel X-ray detector for the European-XFEL. One of the detector's important parts is the radiation tolerant front end ASIC fulfilling the European-XFEL requirements: high dynamic range-from sensitivity to single 12.5keV-photons up to 104 photons. It is implemented using the dynamic gain switching technique with three possible gains of the charge sensitive preamplifier. Each pixel can store up to 352 images in memory operated in random-access mode at >= 4.5MHz frame rate. An external vetoing may be applied to overwrite unwanted frames.

Published

2016

50. New calibration circuitry and concept for AGIPD

Author

Mezza, D., primary, Allahgholi, A., additional, Delfs, A., additional, Dinapoli, R., additional, Goettlicher, P., additional, Graafsma, H., additional, Greiffenberg, D., additional, Hirsemann, H., additional, Klyuev, A., additional, Laurus, T., additional, Marras, A., additional, Mozzanica, A., additional, Perova, I., additional, Poehlsen, J., additional, Schmitt, B., additional, Sheviakov, I., additional, Shi, X., additional, Trunk, U., additional, Xia, Q., additional, Zhang, J., additional, and Zimmer, M., additional

Published

2016