Bibliography
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
8875 results found.
Nanocomposite liposomes for pH-controlled porphyrin release into human prostate cancer cells
Fuentes G.C., Doucet E.N., Abraham A., Rodgers N.K., Alonso F., Euceda N., Quinones M.H., Riascos P.A., Pierre K., Sarker N.H., Dhar-Mascareno M., Cotlet M., Kisslinger K., Camino F., Li M., Lu F., Gao R.
RSC Advances, Vol.010, p.17094-17100 (2020)
Reference to: FluoTime 200, FluoFit
Hybrid frequency-time spectrograph for the spectral measurement of the two-photon state
Xiang X., Dong R., Quan R., Jin Y., Yang Y., Li M., Liu T., Zhang S.
Optics Letters Vol.045, p.2993-2996 (2020)
Reference to: PicoHarp 300
Visible light communication with efficient far-red/near-infrared polymer light-emitting diodes
Minotto A., Haigh P.A., Łukasiewicz L.G., Lunedei E., Gryko D.T., Darwazeh I., Cacialli F.
Light: Science & Applications, Vol.009, 70 (2020)
Reference to: TimeHarp 100/200, NanoHarp 250
Understanding the potential band position and e–/h+ separation lifetime for Z-scheme and type-II heterojunction mechanisms for effective micropollutant mineralization: Comparative experimental and DFT studies
Wong K.T., Kim S.C., Yun K., Choong C.E., Nah I.W., Jeon B.-H., Yoon Y., Jang M.
Applied Catalysis B: Environmental, Vol.273, 119034 (2020)
Reference to: MicroTime 200, SymPhoTime
Enhancement of photodynamic antimicrobialtherapy through the use of cationic indium porphyrin conjugated to Ag/CuFe2O4 nanoparticles
Makola L.C., Managa M., Nyokong T.
Photodiagnosis and Photodynamic Therapy, Vol.030, 101736 (2020)
Reference to: FluoTime 300, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), FluoFit
Quantum light sources based on deterministic microlenses structures with (111) In(Ga)As and AlInAs QDs.
Derebezov I.A., Haisler V.A., Haisler A.V., Dmitriev D.V., Toropov A.I., Rodt S., von Helversen M., de la Haye C., Bounouar S., Reitzenstein S.
Journal of Physics, Conference Series, Vol.1461, 012028 (2020)
Reference to: PicoHarp 300
Vapor‐deposited Cs2AgBiCl6 double perovskite films toward highly selective and stable ultraviolet photodetector
Wang M., Zeng P., Wang Z., Liu M.
Advanced Science, Vol.007, 1903662 (2020)
Reference to: FluoTime 300
Wurtzite InP microdisks: from epitaxy to room-temperature lasing
Staudinger P., Mauthe S., Triviño N.V., Reidt S., Moselund K.E., Schmid H.
Nanotechnology, Vol.032, 075605 (2020)
Reference to: PicoHarp 300
A sensitive near infrared to near-infrared luminescence nanothermometer based on triple doped Ln -Y2O3
Porosnicu I., Colbea C., Baiasu F., Lungu M., Istrate M.C., Avram D., Tiseanu C.
Methods and Applications in Fluorescence, Vol.008, 035005 (2020)
Reference to: TimeHarp 260
Influence of heteroatoms on optical properties and photoluminescence kinetics of carbon dots
Arefina I.A., Khavlyuk P.D., Stepanidenko E.A., Dubavik A., Cherevkov S.A., Baranov A.V., Fedorov A.V., Ushakova E.V., Rogach A.L.
Journal of Physics: Conference Series, Vol.1461, 012008 (2020)
Reference to: MicroTime 100
Boosting the conversio efficiency over 20% in MAPbI3 perovskite planar solar cells by employing a solution-processed Aluminium-doped Nickel oxide hole collector
Parida B., Yoon S., Ryu J., Hayase S., Jeong S.M., Kang D.-W.
ACS Applied Materials & Interfaces, Vol.012, p.22958-22970 (2020)
Reference to: FluoTime 300
Quasi-vertically-orientated antimony sulfide inorganic thin-film solar cells achieved by vapor transport deposition
Zeng Y., Sun K., Huang J., Nielsen M.P., Ji F., Sha C., Yuan S., Zhang X., Yan C., Liu X., Deng H., Lai Y., Seidel J., Ekins-Daukes N., Liu F., Song H., Green M., Hao X.
ACS Applied Materials & Interfaces, Vol.012, p.22825-22834 (2020)
Reference to:
MicroTime 200
Related to:
TRPL
Electronic structure and trap states of two-dimensional Ruddlesden-Popper perovskites with the relaxed Goldschmidt tolerance factor
Liang M., Lin W., Lan Z., Meng J., Zhao Q., Zou X., Castelli I.E., Pullerits T., Canton S.E., Zheng K.
ACS Applied Electronic Materials, Vol.002, p.1402-1412 (2020)
Reference to:
PicoHarp 300
Related to:
TRPL
A spectroscopic marker for structural transitions associated with Amyloid-β aggregation
Das A., Gupta A., Hong Y., Carver J.A., Maiti S.
Biochemistry, Vol.059, p.1813-1822 (2020)
Reference to: FluoFit
Dual CdS nanoparticle-deposoted vertically aligned titanate nanotube heterostructure photoanode
Dhandole L.K., Bae H.-S., Chung H.-S., Chae W.-S., Cho M., Jang J.S.
Industrial & Engineering Chemistry Research, Vol.059, p.9488-9499 (2020)
Reference to: MicroTime 200
Annexin V drives stabilization of damaged asymmetric phospholipid bilayers
Robinson J., Berselli G.B., Ryadnov M.G., Keyes T.E.
Langmuir, Vol.036, p.5454-5465 (2020)
Reference to: MicroTime 200, SymPhoTime
Computational single photon counting for non-line-of-sight, light in flight, and photon flux imaging
Laurenzis M.
Proceedings of SPIE, Advanced Photon Counting Techniques XIV, 113860B (2020)
Reference to: HydraHarp 400
Improving energy level alignment by adenine for efficient and stable perovskite solar cells
Xie L., Cao Z., Wang J., Wang A., Wang S., Cui Y., Xiang Y., Niu X., Hao F., Ding L.
Nano Energy, Vol.074, 104846 (2020)
Reference to: FluoTime 300
Fabrication of metal-dielectric nanocomposites using a table-top ion implanter
Shipilova O.I., Gorbunov S.P., Paperny V.L., Chernykh A.A., Dresvyansky V.P., Martynovich E.F., Rakevich A.L.
Surface and Coatings Technology, Vol.393, 125742 (2020)
Reference to: MicroTime 200
Influence of photoactivation on luminescent properties of colloidal InP@ZnS quantum dots
Spirin M.G., Brichkin S.B., Gak V.Y., Razumov V.F.
Journal of Luminescence, Vol.226, 117297 (2020)
Reference to: FluoTime 200
Measuring steady-state and time-resolved photoluminescence from a positionable, micrometer-sized observation volume with the FluoMic add-on
Oelsner C., Birke F., Ermilov E., Gerber D., Buschmann V., Devaux A., Erdmann R.
PicoQuant Technical and Applications Notes, Spectroscopy (2020)
Reference to: FluoTime 300, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), VisUV
Type-II GaSb quantum dots grown on InAlAs/InP (001) by droplet epitaxy
Yuan Q., Liang B., Luo S., Wang Y., Yan Q., Wang S., Fu G., Mazur Y.I., Maidaniuk Y., Ware M.E.
Nanotechnology, Vol.031, 315701 (2020)
Reference to: PicoHarp 300
Dramatic change of morphological, photophysical, and photocatalytic H₂ evolution properties of C₃N₄ materials by the removal of carbon impurities
Kim H., Lim D.G., Kwon N.H., Son S., Kim J., Hwang S.-J., Park S.
ACS Applied Energy Materials, Vol.003, p.4812-4820 (2020)
Reference to: FluoTime 200
Effect of impregnation by silver nanoparticles on the efficiency of plasma-treated ZnO-based photocatalysts
savastenko N.A., Filatova I.I., Lyushkevich V.A., Chubrik N.I., Brüser V., Shcherbovich A.A., Maskevich S.A.
High Temperature Material Processes, Vol.024, p.21-45 (2020)
Reference to:
TimeHarp 100/200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series)
Related to:
TRPL
Core-shell silica-rhodamine B nanosphere for synthetic opals: from fluorescence spectral redistribution to sensing
Lova P., Congiu S., Sparnacci K., Angelini A., Boarino L., Laus M., Di Stasio F., Comoretto D.
RSC Advances, Vol.010, p.14958-14964 (2020)
Reference to: TimeHarp 260, PMA Series