header image scientific

Bibliography

Our instruments are used by top reserchers world wide, including recent nobel prize winners, such as W.E. Moerner and S.W. Hell. Our bibliography is a collection of papers that mention explicitly PicoQuant or at least one of our product's name. Searching or browsing through the bibliography allows to find out which laboratories use PicoQuant devices and what type of applications have been reported so far.

The bibliography contains articles mentioning explicitly PicoQuant or at least one of our product's name (e.g. MicroTime). Most of the references can be found easily by full-text searches on the internet. However, some papers cite us only indirectly, sometimes not at all. Such publications are included only if the use of a PicoQuant product is known, for example, based on communication with the author(s). There are certainly many more articles reporting results obtained using PicoQuant devices. Unfortunately, such papers are often hidden for us. Please help completing this list.
Do you miss your publication? If yes, we will be happy to include it in our bibliography. Please send an e-mail to info@picoquant.com containing the appropriate citation. Thank you very much in advance for your kind co-operation.

more..

Searching for

8963 results found.


The efficient design of time-to-digital converters

Tancock S.
Dissertation University of Bristol (2021)

Reference to: PicoHarp 300, HydraHarp 400

Quantum correlations using classical detectors

Adikarige C.
Dissertation Rochester Institute of Technology (2021)

Reference to: PicoHarp 300

Onsite non-line-of-sight imaging via online calibrations

Pan Z., Li R., Gao T., Wang Z., Liu P., Shen S., Wu T., Yu J., Li S.
Image and Video Processing (2021)

Reference to: Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), PicoHarp 300, SPADs

Fluorescence lifetime imaging as an in situ and label-free readout for the chemical composition of lignin

Escamez S., Terryn C., Gandla M.L., Yassin Z., Scheepers G., Näsholm T., Sundman O., Jönsson L.J., Lundberg-Felten J., Tuominen H., Niittylä T., Paës G.
ACS Sustainable Chemistry & Engineering, Vol.009, p.17381-17392 (2021)

Reference to: LSM Upgrade Kit
Related to: FLIM

Charge carrier lifetime fluctuations and performance evaluation of Cu(In,Ga)Se2 absorbers via time-resolved-photoluminescence microscopy

Ochoa M., Yang S.-C., Nishiwaki S., Tiwari A.N., Carron R.
Advanced Energy Materials, Vol.012, 2102800 (2021)

Reference to: FluoTime 300, MicroTime 100

A low cost, short range quantum key distribution system

Lowndes D., Frick S., Hart A., Rarity J.
EPJ Quantum Technology, Vol.008, 15 (2021)

Reference to: PicoHarp 300

Barley RIC157 is involved in RACB-1 mediated susceptibility to powdery mildew

Engelhardt S., Trutzenberg A., Probst K., Hofer J., McCollum C., Kopischke M., Hückelhoven R.
bioRxiv, preprint (2021)

Reference to: LSM Upgrade Kit
Related to: FLIM, FRET

LORE homomerization is required for 3-OH-C10:0 induced immune signaling

Eschrig S., Schäffer M., Illig T., Eibel S., Shu L.-J., Fernandez A., Ranf S.
bioRxiv, preprint (2021)

Reference to: LSM Upgrade Kit
Related to: FLIM, FRET

Rapid fluorescence lifetime imaging reveals that TRPV4 channels promote dysregulation of neuronal Na+ in ischemia

Meyer J., Gerkau N.J., Kafitz K.W., Patting M., Jolmes F., Henneberger C., Rose C.R.
Journal of Neuroscience, preprint (2021)

Reference to: MultiHarp 150, LSM Upgrade Kit, PMA Series, SymPhoTime
Related to: FLIM

Laser spectroscopy of the y7P∘J states of Cr I

Norrgard E.B., Barker D.S., Eckel S.P., Porsev S.G., Cheung C., Kozlov M.G., Tupitsyn I.I., Safronova M.S.
Atomic Physics (2021)

Reference to: MultiHarp 150, PMA Series

Osh6 revisited: control of PS transport by the concerted actions of PI4P and Sac1 phosphatase

Eisenreichova A., Różycki B., Boura E., Humpolickova J.
Frontiers in Molecular Biosciences, Vol.008, 747601 (2021)

Reference to: HydraHarp 400
Related to: FLIM

MethodsJ2: a software tool to capture metadata and generate comprehensive microscopy methods text

Ryan J., Pengo T., Rigano A., Llopis P.M., Itano M.S., Cameron L.A., Marqués G., Strambio-De-Castillia C., Sanders M.A., Brown C.M.
Nature Methods (2021)

Reference to: MicroTime 200, LSM Upgrade Kit

MDEmic: a metadata annotation tool to facilitate management of FAIR image data in the bioimaging community

Kunis S., Hänsch S., Schmidt C., Wong F., Strambio-De-Castillia C., Weidtkamp-Peters S.
Nature Methods (2021)

Reference to: MicroTime 200, LSM Upgrade Kit

The BrightEyes-TTM: an open-source time-tagging module for single-photon microscopy

Rossetta A., Slenders E., Donato M., Perego E., Diotalevi F., Lanzanó L., Koho S., Tortarolo G., Crepaldi M., Vicidomini G.
bioRxiv, preprint (2021)

Reference to: SPADs

Combining rapid microfluidic mixing and three-color singlemolecule FRET for probing the kinetics of protein conformational changes

Benke S., Holla A., Wunderlich B., Sorrano A., Nettels D., Schuler B.
The Journal of Physical Chemistry B, Vol.125, p.6617-6628 (2021)

Reference to: Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), SPADs
Related to: FRET

Recent advances in FRET-based biosensors for biomedical applications

Imani M., Mohajeri N., Rastegar M., Zarghami N.
Analytical Biochemistry, Vol.630, 114323 (2021)

Reference to: MicroTime 200, LSM Upgrade Kit
Related to: FRET

Time-magnified photon counting with 550-fs resolution

Li B., Bartos J., Xie Y., Huang S.-W.
Optica, Vol.008, p.1109-11112 (2021)

Reference to: HydraHarp 400, SPADs
Related to: LIDAR or ranging

Epitaxial thin films of a chalcogenide perovskite

Surendran M., Orvis T., Chen H., Zhao B., Singh S., Thind A.S., Mishra R., Zhao H., Htoon H., Han J.-K., Kawasaki M., Ravichandran J.
Materials Science (2021)

Reference to: HydraHarp 400

Dynamic-quenching of a single-photon avalanche photodetector using an adaptive resistive switch

Zheng J., Xue X., Yuan Y., Sun K., Ji C., Rosenmann D., Campbell J., Guha S.
Proceedings of SPIE, Advanced Photon Counting Techniques XV, 117210E (2021)

Reference to: PicoHarp 300, SPADs

Enhanced multiexciton formation by an electron-hole plasma in 2D semiconductors

Strasbourg M., Johns C., Noble Z., Yanev E., Darlington T.P., Hone J.C., Schuck P.J., Borys N.J.
Materials Science (2021)

Reference to: HydraHarp 400

Time-resolved high energy ionoluminescence of Al2O3

Seitbayev A., Skuratov V.A., Dauletbekova A., Teterev Y.G., Krylov A.N., Mamatova M., Koloberdin M., Zdorovets M.
Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms Vol.500–501, p.46-51 (2021)

Reference to: TimeHarp 260

Automatic calibration of time of flight based non-line-of-sight reconstruction

Sadhu S.C., Singh A., Maeda T., Swedish T. Kim R., Sinha L., Raskar R.
Image and Video Processing (2021)

Reference to: HydraHarp 400, SPADs

Amphiphilicity-adaptable graphene quantum dots to stabilize pH-responsive pickering emulsions at a very low concentration

Ma R., Zeng M., Huang D., Wang J., Cheng Z., Wang Q.
Journal of Colloid and Interface Science, Vol.601, p.106-113 (2021)

Reference to: FluoTime 100

Dengue fusion peptides in interaction with model membranes - a fluorescence study

da Silva Olivier D., Cespedes G.F., Pazin W.M., Cilli E.M., Ito A.S.
Eclética Química Journal, Vol.046, p.30-40 (2021)

Reference to: MicroTime 200, SymPhoTime
Related to: FCS

Incorporating early and late-arriving photons to improve the reconstruction of cerebral hemodynamic responses acquired by time-resolved near-infrared spectroscopy

Milej D., Abdalmalak A., Rajaram A. Jhajj A., Owen A.M., St. Lawrence K.
Journal of Biomedical Optics, Vol.026, 056003 (2021)

Reference to: HydraHarp 400, PMA Series