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.
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Searching for MicroTime 200
1293 results found.
Unfolding and refolding of a protein by cholesterol and cyclodextrin: a single molecule study
Ghosh S., Ghosh C., Nandi S., Bhattacharyya K.
Physical Chemistry Chemical Physics, Vol.017, p.8017-8027 (2015)
Reference to: MicroTime 200
The lateral diffusion and fibrinogen induced clustering of platelet integrin αIIbβ3 reconstituted into physiologically mimetic GUVs
Gaul V., Lopez S.G., Lentz B.R., Moran N., Forster R.J., Keyes T.E.
Integrative Biology, Vol.007, p.402-411 (2015)
Reference to: MicroTime 200, SymPhoTime
Features of propagation of the high-intensity femtosecond laser pulses in magnesium and sodium fluoride crystals
Bryukvina L.
Journal of Luminescence, Vol.162, p.145-148 (2015)
Reference to: MicroTime 200
Intermittent fluorescence oscillations in lipid droplets in a live normal and lung cancer cell: time-resolved confocal microscopy
Chowdhury R., Amin M.A., Bhattacharyya K.
The Journal of Physical Chemistry B, Vol.119, p.10868-10875 (2015)
Reference to: MicroTime 200
The assembly dynamics of the cytolytic pore tocin ClyA
Benke S., Roderer D., Wunderlich B., Nettels D., Glockshuber R., Schuler B.
Nature Communications, Vol.006, 6198 (2015)
Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), HydraHarp 400, SPADs
Enzyme degradable polymersomes from hyaluronic acid-block-poly(ε-caprolactone) copolymers for the detection of enzymes of pathogenic bacteria
Haas S., Hain N., Raoufi M., Handschuh-Wang S., Wang T., Jiang X., Schönherr H.
Biomacromolecules, Vol.016, p.832-841 (2015)
Reference to: MicroTime 200
Radio frequency magnetron sputtered highly textured Cu2ZnSnS4 thin films on sapphire (0 0 0 1) substrates
Song N., Wen X., Hao X.
Journal of Alloys and Compounds, Vol.632, p.53-58 (2015)
Reference to: MicroTime 200
Methylammonium lead bromide perovskite-based solar cells by vapor-assisted deposition
Sheng R., Ho-Baillie A., Huang S., Chen S., Wen X., Hao X., Green M.A.
The Journal of Physical Chemistry C, Vol.119, p.3545-3549 (2015)
Reference to: MicroTime 200
Improving efficiency of evaported Cu2ZnSnS4 thin film solar cells by a thin Ag intermediate layer between absorber and back contact
Cui H., Lee C.-Y., Li W., Liu X., Wen X., Hao X.
International Journal of Photoenergy, Vol.2015, article IS 170507-170516 (2015)
Reference to: MicroTime 200
Carrier density dependence of plasmon-enhanced nonradiative energy transfer in a hybrid quantum well-quantum dot structure
Higgins L.J., Karanikolas V.D., Marocico C.A., Bell A.P., Sadler T.C., Parbrook P.J., Bradley A.L.
Optics Express, Vol.023, p.1377-1387 (2015)
Reference to: MicroTime 200
Multiple growth events in diamonds with cloudy microinclusions from the Mir kimberlite pipe: evidence from the systematics of optically active defects
Skuzovatov S.Y., Zedgenizov D.A., Rakevich A.L., Shatsky V.S., Martynovich E.F.
Russian Geology and Geophysics, Vol.056, p.330-343 (2015)
Reference to: MicroTime 200
Chapter Ten - Monitoring mRNA and protein levels in bulk and in model vesicle-based artificial cells
van Nies P., Canton A.S., Nourian Z., Danelon C.
Methods in Enzymology, Vol.550, p.187-214 (2015)
Reference to: MicroTime 200
Plasmon-enhanced formic acid dehydrogenation using anisotropic Pd-Au nanorods studied at the single-particle level
Zheng Z., Tachikawa T., Majima T.
The Journal of the American Chemical Society, Vol.137, p.948-957 (2015)
Reference to: MicroTime 200
Evaluation of electrostatic binding of PAMAM dendrimers and charged phthalocyanines by fluorescence correlation spectroscopy
Garcia-Fernandez E., Paulo P.M.R., Costa S.M.B.
Physical Chemistry Chemical Physics, Vol.017, p.4319-4327 (2015)
Reference to:
MicroTime 200, SymPhoTime
Related to:
FCS
Surface-enhanced spectroscopy on plasmonic oligomers assembled by AFM nanoxerography
Moutet P., Sangeetha N.M., Ressier L., Vilar-Vidal N., Comesaña-Hermo M., Ravaine S., Vallée R.A.L., Gabudean A.M., Astilean S., Farcau C.
Nanoscale, Vol.007, p.2009-2022 (2015)
Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), PicoHarp 300
Thermodynamics of membrane insertion and refolding of the diphtheria toxin t-domain
Vargas-Uribe M., Rodnin M.V., Öjemalm K., Holgado A., Kyrychenko A., Nilsson I., Posokhov Y.O., Makhatadze G., von Heijne G., Ladokhin A.S.
The Journal of Membrane Biology, Vol.248, p.383-394 (2015)
Reference to: MicroTime 200, TimeHarp 100/200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), SPADs
Effect of blend composition on binary organic solar cells using a low band gap polymer
Wright M., Lin T., Tayebjee M.J.Y., Yang X., Veettil B., Wen X., Uddin A.
Journal of Nanoscience and Nanotechnology, Vol.015, p.2204-2211 (2015)
Reference to: MicroTime 200
Enhancement of photoresponsive electrical characteristics of multi-layer MoS2 transistors using rubrene patches
Cho E.H., Song W.G., Park C.J., Kim J., Kim S., Joo J.
Nano Research, Vol.008, p.790-800 (2015)
Reference to: MicroTime 200
Single molecule laser spectroscopy
Atta D., Okasha A.
Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, Vol.135, p.1173-1179 (2015)
Reference to: MicroTime 200
Refractive index mismatch can misindicate anomalous diffusion in single-focus fluorescence correlation spectroscopy
Lehmann S., Seiffert S., Richtering W.
Macromolecular Chemistry, Vol.216, p.156-163 (2015)
Reference to:
MicroTime 200
Related to:
FCS
Simultaneous fluorescence and phosphorescence lifetime imaging microscopy in living cells
Jahn K., Buschmann V., Hille C.
Scientific Reports, Vol.005, 14334 (2015)
Reference to:
MicroTime 200, TimeHarp 260
Related to:
FLIM
Self-calibrated line-scan STED-FCS to quantify lipid dynamics in model and cell membranes
Benda A., Ma Y., Gaus K.
Biophysical Journal, Vol.108, p.596-609 (2015)
Reference to:
MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), PicoHarp 300, SPADs
Related to:
FCS, STED
Fluorescent protein based FRET pairs with improved dynamic range for fluorescence lifetime measurements
Abraham B.G., Sarkisyan K.S., Mishin A.S., Santala V., Tkachenko N.V., Karp M.
PLoS ONE, Vol.010, e0134436 (2015)
Reference to:
MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), PicoHarp 300
Related to:
FLIM, FRET
Green fluorescent protein with anionic tryptophan-based chromophore and long fluorescence lifetime
Sarkisyan K.S., Goryashchenko A.S., Lidsky P.V., Gorbachev D.A., Bozhanova N.G., Gorokhovatsky A.Y., Pereverzeva A.R., Ryumina A.P., Zherdeva V.V., Savitsky A.P., Solntsev K.M., Bommarius A.S., Sharonov G.V., Lindquist J.R., Drobizhev M., Hughes T.E., Rebane A., Lukyanov K.A., Mishin A.S.
Biophysical Journal, Vol.109, p.380-389 (2015)
Reference to: MicroTime 200, FluoTime 200, FluoFit
Accurate diffusion coefficients of organosoluble reference dyes in organic media measured by dual-focus fluorescence correlation spectroscopy
Goossens K., Prior M., Pacheco V., Willbold D., Müllen K., Enderlein J., Hofkens J., Gregor I.
ACS Nano, Vol.009, p.7360-7373 (2015)
Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), HydraHarp 400, SPADs