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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.

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8963 results found.


Enhanced detection of early photons in time-domain optical tomography using dead-time characteristics of SPADs

Sinha L., Zhou W., Mehta R., Brankov J.G., Tichauer K.M.,
Biomedical Optics, paper OW4D.6 (2016)

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

Synthesis and photoluminescence of single-crystalline Fe(III)-doped CdS nanobelts

Kamran M.A., Zou B., Majid A., Saeed M.A.
Journal of Nanoscience and Nanotechnology, Vol.016, p.4086-4093 (2016)

Reference to: TimeHarp 100/200

Long-lived hot carriers in III-V nanowires

Tedeschi D., De Luca M., Fonseka H.A., Gao Q., Mura F., Tan H.H., Rubini S., Martelli F., Jagadish C., Capizzi M., Polimeni A.
Nano Letters, Vol.016, p.3085–3093 (2016)

Reference to: PicoHarp 300
Related to: TRPL

Spectral properties of 1H-pyrazolo[3,4-b]quinoline substituted with N,N-diethylamine moiety

Kolbus A., Grbka D., Danel A., Szary K.
Optical Materials, Vol.057, p.102-106 (2016)

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

Influence of the QD luminscence quantum yield on photocurrent in QD/graphene hybrid structures

Reznik I.A., Gromova Y.A., Zlatov A.S., Baranov M.A., Orlova A.O., Moshkalev S.A., Maslov V.G., Fedorov A.V., Baranov A.V.
Proceedings of SPIE, Nanophotonics VI, 98843A (2016)

Reference to: MicroTime 100
Related to: FLIM

Aggregation of quantum dots in hybrid structures based on TiO2 nanoparticles

Kolesova E., Orlova A.O., Maslov V.G., Gun´ko Y.K., Cleary O., Baranov A.V., Fedorov A.V.
Proceedings of SPIE, Nanophotonics VI, 988431 (2016)

Reference to: MicroTime 100

Silicon photomultipliers and front-end electronics performance for Cherenkov telescope array camera development

Ambrosi G., Bissaldi E., Giglietto N., Giordano F., Ionica M., Paoletti R., Rando R., Simone D., Vagelli V.
Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, In Press (2016)

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

New compact and flexible picosecond laser system for multi-wavelength time-resolved tissue spectroscopy

Erdmann R., Lauritsen K., Contini D., Pifferi A., Spinelli L., Torricelli A.
Biomedical Optics, paper JW3A.1 (2016)

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

Dead-time correction of fluorescence lifetime measurements and fluorescence lifetime imaging

Isbaner S., Karedla N., Ruhlandt D., Stein S.C., Chizhik A., Gregor I., Enderlein J.
Optics Express, Vol.024, p.9429-9445 (2016)

Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), HydraHarp 400, SymPhoTime

Fluorescence quanching of coumarin 153 by hydroxyl-functionalized room temperature ionic liquids

Li S., Yu A., Lu R.
Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, Vol.165, p.161-166 (2016)

Reference to: TimeHarp 100/200

Enhancing Fröster nonradiative energy transfer via plasmon interaction

Higgins L.J., Zhang X., Marocico C.A., Murphy G.P., Karanikolas V.K., Gun´ko Y.K., Lesnyak V., Gaponik N., Susha A.S., Rogach A.L., Parbrook P.J., Bradley A.L.
Conference Nanophotonics VI, Vol.9884 (2016)

Reference to: MicroTime 200
Related to: FRET

Luminescence kinetics of the radiative transitions in quantum dots CdSe/ZnS in the near field of plasmonic nanoparticles

Bakanov A.G., Toropov N.A., Vartanyan T.A.
Conference Nanophotonics VI, Vol.9884 (2016)

Reference to: MicroTime 100
Related to: FLIM

FRET efficiency in surface complexes od CdSe/ZnS quantum dots with azo-dyes

Annas K.I., Gromova Y.A., Orlova A.O., Maslov V.G., Fedorov A.V., Baranov A.V.
Conference Nanophotonics VI, Vol.9884 (2016)

Reference to: MicroTime 100
Related to: FLIM, FRET

A facile chemical synthesis of ZnO@multilayer graphene nanoparticles with fast charge seperation and enhanced performance for application in solar energy conversion

Shim J., Kim J.K., Lee K.S., Lee C.-L., Ma M., Choi W.K., Hwang J.Y., Yang H.Y., Angadi B., Park J.H., Yu K., Son D.I.
Nano Energy, Vol.025, p.9-17 (2016)

Reference to: FluoFit, PicoHarp 300
Related to: TRPL

Monitoring excimer formation of perylene dye molecules within PMMA-based nanofiber vial FLIM method

Inci M.N., Acikgoz S., Demir M.M.
Proceedings of SPIE, Vol.9884, 988413 (2016)

Reference to: TimeHarp 100/200, FluoFit
Related to: FLIM

Nanocommunication via FRET with dyelight dyes using multiple donors and acceptors

Solarczyk K., Wojcik K., Kulakowski P.
IEEE Transactions on NanoBioscience, Vol.PP, p.1-9 (2016)

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

Conformational mobility in cytochrome P450 3A4 explored by pressure-perturbation EPR spectroscopy

Davydov D.R., Yang Z., Davydova N., Halpert J.R., Hubbell W.L.
Biophysical Jouranl, Vol.110, p.1458-1498 (2016)

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

Bandwidth manipulation of quantum light by an electro-optic time lens

Karpinski M., Jachura M., Wright L.J., Smith B.J.
Quantum Physics (2016)

Reference to: PicoHarp 300, SPADs

Lipid vesicles loading aluminum phthalocyanine chloride: formulation properties and disaggregation upon intracellular delivery

Calori I.R., Tedesco A.C.
Journal of Photochemistry and Photobiology B: Biology, Vol.160, p.240-247 (2016)

Reference to: MicroTime 200, SymPhoTime

Computational multi-depth single-photon imaging

Shin D., Xu F., Wong F.N.C., Shapiro J.H., Goyal V.K.
Optics Express, Vol.024, p.1873-1888 (2016)

Reference to: Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), HydraHarp 400
Related to: LIDAR or ranging

Guanylate binding proteins directly attack Toxoplasma gondii via supramolecular complexes

Kravets E., Degrandi D., Ma Q., Peulen T.-O., Klümpers V., Felekyan S., Kühnemuth R., Weidtkamp-Peters S., Seidel C.A.M., Pfeffer K.
eLife, Vol.005, e11479 (2016)

Reference to: HydraHarp 400
Related to: FLIM, FRET

Quantum confined states and room temperature spin coherence in semiconductor nanocrystal quantum dots

Fumani A.K.
Dissertation Case Western Reserve University (2016)

Reference to: HydraHarp 400

A simple and versatile design concept for fluorophore derivatives with intramolecular photostabilization

van der Velde J.H.M., Oelrich J., Huang J., Smit J.H., Jazi A.A., Galiani S., Kolmakov K., Guoridis G., Eggeling C., Herrmann A., Roelfes G., Cordes T.
Nature Communications, Vol.007, 10144 (2016)

Reference to: HydraHarp 400

Coherent absorption of NooN states

Roger T., Restuccia S., Lyons A., Giovannini D., Romero J., Jeffers J., Padgett M., Faccio D.
Optics (2016)

Reference to: HydraHarp 400
Related to: Quantum Information Processing

Large-scale self-assembled plasmonic templates for enhanced spectroscopy

Chekini M.
Dissertation Université de Genève (2016)

Reference to: PicoHarp 300, PMA Series