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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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8790 results found.


Efficient way to assemble CdS nanorose-decorated CdSe-tetrakaidecahedron heterojunction photoanodes for high-photoelectrochemical performance

Mahadik M.A., Chung H.-S., Ryu H.I., Chae W.-S., Cho M., Jang J.S.
ACS Sustainable Chemistry & Engineering, Vol.007, p.19708-19719 (2019)

Reference to: MicroTime 200

Photostimulated control of luminescence quantum yield for colloidal Ag2S/2-MPA quantum dots

Ovchinnikov O.V., Aslanov S.V., Smirnov M.S., Grevtseva I.G., Perepelitsa A.S.
RSC Advances, Vol.009, p.37312-37320 (2019)

Reference to: TimeHarp 260

Experimental demonstration of switching entangled photons based on the Rydberg blockade effect

Ding D.-S., Yu Y.-C., Dong M.-X., Ye Y.-H., Guo G.-C., Shi B.-S.
Quantum Physics (2019)

Reference to: TimeHarp 260

Comparative study of photoluminescence for type-I InAs/GaAs0. 89Sb0. 11 and type-II InAs/GaAs0. 85Sb0. 15 quantum dots

Zhou C., Liang B., Liu J., Wang Y., Guo Y., Wang S., Fu G., Mazur Y.I., Ware M.E., Salamo G.J.
Optical Materials, Vol.098, 109479 (2019)

Reference to: PicoHarp 300

Cetyltrimethyl ammonium mediated enhancement of the red emission of carbon dots and an advanced method for fluorometric determination of iron (III)

Li T., Xie L., Long R., Tong C., Guo Y., Tong X., Shi S., Lin Q.
Microchimica Acta, Vol186, 791 (2019)

Reference to: FluoTime 100

Optical coding of SPAD array and its application in compressive depth and transient imaging

Sun Q., Dun X., Peng Y., Heidrich W.
Proceedings of SPIE, Optoelectronic Imaging and Multimedia Technology VI; 111870D (2019)

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

Strain engineering of quantum eimitters in hexagonal boron nitride

Mendelson N., Doherty M., Toth M., Aharonovich I., Tran T.T.
Materials Science (2019)

Reference to: PicoHarp 300

Reduced binding energy and layer-dependent exciton dynamics in monolayer and multilayer WS2

Liu Y., Hu X., Wang T., Liu D.
ACS Nano, Vol.013, p.14416-14425 (2019)

Reference to: PicoHarp 300

Preserving the emission lifetime and efficiency of a monolayer semiconductor upon transfer

Barker S.E., Wang S., Godiksen R.H., Castellanos G.W., Berghuis M., Raziman T.V., Curton A.G., Rivas J.G.
Advanced Optical Materials, Vol.007, 1900351 (2019)

Reference to: PicoHarp 300
Related to: FLIM

Deterministic placement of ultra-bright near-infrared color centers in arrays of silicon carbide micropillars

Castelletto S., Al Atem A.S., Inam F.A., von Bardeleben H.J., Hameau S., Almutairi A.F., Guillot G., Sato S.-i., Boretti A., bluet J.M.
Beilstein Journal of Nanotechnology, Vol.010, p.2383–2395 (2019)

Reference to: TimeHarp 260

Loss compensation of surface plasmon polaritons in organic/metal nanowire heterostructures toward photonic logic processing

Lv Y., Xu F.F., Wang K., Li Y.J., Zhao Y.S.
Science China Materials (2019)

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

New targeted gold nanorods for the treatment of Glioblastoma by photodynamic therapy

Youssef Z., Yesmurzayeva N., Larue L., Jouan-Hureaux V., Colombeau L., Arnoux P., Acherar S., Vanderesse R., Frochot C.
Journal of Clinical Medicine, Vol.008, 2205 (2019)

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

The role of avalanche ionization in generation of defects in lithium fluoride crystals under the action of femtosecond laser pulses

Dresvyanskiy V.P., Kuznetsov A.V., Enkhbat S., Bukhtsooj O., Bobina N.S., Alekseev S.V., Losev V.F., Martynovich E.F.
Proceedings of SPIE, XIV International Conference on Pulsed Lasers and Laser Applications, 113222A (2019)

Reference to: MicroTime 200

Histones and histone modifying proteins in a biophysical aspect

Hetey S.
Dissertation University of Debrecen (2019)

Reference to: FluoTime 200

Photon counting LIDAR at 2.3μm wavelength with superconducting nanowires

Taylor G.G., Morozov D., Gemmell N.R, Erotokritou K., Miki S., Terai H., Hadfield R.H.
Optics Express, Vol.027, p. 38147-38158 (2019)

Reference to: HydraHarp 400
Related to: LIDAR or ranging

Disordered RNA chaperones can enhance nucleic acid folding via local charge screening

Holmstrom E.D., Liu Z., Nettels D., Best R.B., Schuler B.
Nature Communications, Vol.010, 2543 (2019)

Reference to: MicroTime 200

Cremophor EL nano-emulsion monomerizes chlorophyll a in water medium

Janik-Zabrotowicz E., Arczewska M., Zubik M., Terpilowski K., Skrzypek T.H., Swietlicka I., Gagos M.
Biomolecules, Vol.009, p.881 (2019)

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

Three-dimensional imaging of stationary and moving targets in turbid underwater environments using a single-photon detector array

Maccarone A., Della Rocca F.M., McCarthy A., Henderson R., Buller G.S.
Optics Express, Vol.027, p.28437-28456 (2019)

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

A quantum dot-based FLIM glucose nanosensor

Ripoll C., Orte A., Paniza L., Ruedas-Rama M.J.
Sensors, Vol.019, 4992 (2019)

Reference to: MicroTime 200, FluoTime 200
Related to: FLIM

Proteoliposomes as energy transferring nanomaterials: enhancing the spectral range of light-harvesting proteins using lipid-linked chromophores

Hancock A.M., Meredith S.A., Connell S.D., Jeuken L.J.C., Adams P.G.
Nanoscale, Vol.011, p.16284-16292 (2019)

Reference to: MicroTime 200
Related to: FLIM, FRET

Large area SiPM and high throughput timing electronics: toward new generation time-domain instruments

Behera A., Di Sieno L., Rohilla S., Pifferi A., Torricelli A., Contini D., Krämer B., Koberling F., Dalla Mora A.
Proceedings of SPIE, Clinical and Preclinical Optical Diagnostics II, 11074, 1107402 (2019)

Reference to: TimeHarp 260

Vinculin force sensor detects tumor-osteocyte interactions

Li F., Chen A., Reeser A., Wang Y., Fan Y., Liu S., Zhao X., Prakash R., Kota S., Li B.-Y., Yokota H., Liu J.
Sciebtific Reports, Vol.009, 5615 (2019)

Reference to: TimeHarp 260

Quantum entangled single photons with partial distinguishability

Wstra G.
Dissertation Leiden University (2019)

Reference to: TimeHarp 260

How fluorescent tags modify oligomer size distributions of the Alzheimer peptide

Wägele J., De Sio S., Voigt B., Balbach J., Ott M.
Biophysical Journal, Vol.116, p.227-238 (2019)

Reference to: TimeHarp 260

Photoluminescence quantum yield of fluorescent silicon carbide determined by an integrating sphere setup

Wie Y., Ou H.
ACS Omega, Vol.004, p.15488-15495 (2019)

Reference to: TimeHarp 260