Time-Resolved Fluorescence Wiki

calibrate_the_confocal_volume_for_fcs_using_the_fcs_calibration_script

Anonymous (anonymous@undisclosed.example.com) — 2019-02-07T12:16:52+00:00

2019/02/07 13:13		current
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	Note: Calibration is a necessary task for FCS measurements. In a calibration procedure, the confocal volume VEff as well as the structural parameter κ (the ratio of z to xy extension) is determined using a reference dye. This is the prerequisite to determine correct diffusion coefficients and concentrations for the sample of interest.\\		Note: Calibration is a necessary task for FCS measurements. In a calibration procedure, the confocal volume VEff as well as the structural parameter κ (the ratio of z to xy extension) is determined using a reference dye. This is the prerequisite to determine correct diffusion coefficients and concentrations for the sample of interest.\\
	ATTO488 (ATTO-Tec, Germany) is a suited dye to calibrate the confocal microscope at ~470 – 490 nm excitation and detection around 500 – 540 nm.\\		ATTO488 (ATTO-Tec, Germany) is a suited dye to calibrate the confocal microscope at ~470 – 490 nm excitation and detection around 500 – 540 nm.\\
-	The diffusion coefficient of ATTO488 carboxilic acid has been measured to be 400 µm²/s at 25°C. Published diffusion coefficients of various fluorophores are summarized in the Technical Note "Absolute Diffusion Coefficients: Compilation of Reference Data for FCS Calibration" available from PicoQuant [see [[https://www.picoquant.com/images/uploads/page/files/7353/appnote_diffusioncoefficients.pdf]]]. This list is extensive, but does not claim to be complete.\\	+	The diffusion coefficient of ATTO488 carboxilic acid has been measured to be 400 µm²/s at 25°C. Published diffusion coefficients of various fluorophores are summarized in the Technical Note "Absolute Diffusion Coefficients: Compilation of Reference Data for FCS Calibration" available from PicoQuant (see [[https://www.picoquant.com/images/uploads/page/files/7353/appnote_diffusioncoefficients.pdf]]). This list is extensive, but does not claim to be complete.\\
	Note that the diffusion coefficients of all dyes are temperature dependent.\\		Note that the diffusion coefficients of all dyes are temperature dependent.\\
	FCS measurements are usually point measurements acquired with very sensitive detectors ([[glossary:spad\|SPAD]] or [[glossary:Hybrid PMT]] detectors).\\		FCS measurements are usually point measurements acquired with very sensitive detectors ([[glossary:spad\|SPAD]] or [[glossary:Hybrid PMT]] detectors).\\

burst_duration_and_fcs_diffusion_time

Anonymous (anonymous@undisclosed.example.com) — 2026-01-12T14:58:02+00:00

2026/01/12 15:56		current
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	Gopich, I. V.; Szabo, A. Journal of Chemical Physics 2005, 122, 014707.		Gopich, I. V.; Szabo, A. Journal of Chemical Physics 2005, 122, 014707.

-	Ruttinger, S. Dissertation, 2006.	+	Ruettinger, S. Dissertation, 2006.

-	Dorr, D. Dissertation, 2014.	+	Doerr, D. Dissertation, 2014.

how_to_measure_the_instrument_response_function_irf

Anonymous (anonymous@undisclosed.example.com) — 2023-09-07T22:55:03+00:00

2023/09/08 00:54		current
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	===== Using samples with ultrafast decay =====		===== Using samples with ultrafast decay =====

-	Some detectors (particularly SPADs) have wavelength dependent timing response. In this case an IRF recorded at the excitation wavelength may not be useful for precise reconvolution. The solution is to acquire the IRF at the fluorescence wavelength, or at least spectrally closer to the fluorescence emission.	+	Some detectors (particularly MPD SPADs) have a wavelength dependent timing response. In this case an IRF recorded at the excitation wavelength may not be useful for precise reconvolution. The solution is to acquire the IRF at the fluorescence wavelength, or at least spectrally closer to the fluorescence emission wavelength.

	==== General recipe ====		==== General recipe ====

calculate_and_fit_fcs_traces_with_the_fcs_script

Anonymous (anonymous@undisclosed.example.com) — 2015-11-03T14:11:17+00:00

2014/06/18 11:22		current
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	* The diffusion coefficient of ATTO488 carboxilic acid has been measured to be 400 µm²/s at 25°C. Published diffusion coefficients of various fluorophores are summarized in the Technical Note "Absolute Diffusion Coefficients: Compilation of Reference Data for FCS Calibration" available from PicoQuant [see http://www.picoquant.com/images/uploads/page/files/7353/appnote_diffusioncoefficients.pdf ]. This list is extensive, but does not claim to be complete.		* The diffusion coefficient of ATTO488 carboxilic acid has been measured to be 400 µm²/s at 25°C. Published diffusion coefficients of various fluorophores are summarized in the Technical Note "Absolute Diffusion Coefficients: Compilation of Reference Data for FCS Calibration" available from PicoQuant [see http://www.picoquant.com/images/uploads/page/files/7353/appnote_diffusioncoefficients.pdf ]. This list is extensive, but does not claim to be complete.
	* Note that the diffusion coefficients of all dyes are temperature dependent.		* Note that the diffusion coefficients of all dyes are temperature dependent.
-	* FCS measurements are usually point measurements acquired with very sensitive detectors (typically SPAD or Hybrid PMT detectors).	+	* FCS measurements are usually point measurements acquired with very sensitive detectors (typically [[glossary:SPAD]] or [[glossary:Hybrid PMT]] detectors).
	* FCS is a technique that can be used over a wide range of concentrations, but ideal FCS concentrations are usually between 1 nM and 20 nM.		* FCS is a technique that can be used over a wide range of concentrations, but ideal FCS concentrations are usually between 1 nM and 20 nM.

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	{{ calculate_and_fit_fcs_traces_with_the_fcs_script_Image_7.png?600 }}		{{ calculate_and_fit_fcs_traces_with_the_fcs_script_Image_7.png?600 }}

-	Note: A possibility to remove the afterpulsing when working with cw excitation is splitting the light onto two detectors and calculate a cross correlation. Some detectors (mainly Hybrid PMTs) also have so low afterpulsing that the problem does not occur.	+	Note: A possibility to remove the afterpulsing when working with cw excitation is splitting the light onto two detectors and calculate a cross correlation. Some detectors (mainly [[glossary:Hybrid PMT]]s) also have so low afterpulsing that the problem does not occur.

	* If the sample has beenexcited with cw light, we would now save the data by clicking "Save Result" and press afterwards "Transfer to Fit" (both in the "File" dropdown panel). As our sample has been excited with a pulsed laser, we can apply one additional step to increase data quality.		* If the sample has beenexcited with cw light, we would now save the data by clicking "Save Result" and press afterwards "Transfer to Fit" (both in the "File" dropdown panel). As our sample has been excited with a pulsed laser, we can apply one additional step to increase data quality.

pattern_matching

Anonymous (anonymous@undisclosed.example.com) — 2014-06-18T13:26:07+00:00

2014/05/23 09:39		current
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	Pattern Matching Analysis by decomposing a recorded image into different user-defined patterns. Display of the calculated data using an RGB false color model. The calculated amplitudes of the first three defined patterns are depicted in three different colors for each pixel.		Pattern Matching Analysis by decomposing a recorded image into different user-defined patterns. Display of the calculated data using an RGB false color model. The calculated amplitudes of the first three defined patterns are depicted in three different colors for each pixel.
		+
		+	{{ youtube>L68IgRbNSLE?large }}

	==== Open an Image ====		==== Open an Image ====

diamond_nv_centers

Anonymous (anonymous@undisclosed.example.com) — 2018-04-19T12:11:55+00:00

2018/04/19 14:11		current
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	see also [[wp>Nitrogen-vacancy center]]		see also [[wp>Nitrogen-vacancy center]]

-	{{ howto:model_nv-centers.png\|Figure1: Model of the nitrogene vacancy in the diamond lattice}}	+	[{{ howto:model_nv-centers.png\|Figure1: Model of the nitrogene vacancy in the diamond lattice}}]

	==== Excitation ====		==== Excitation ====

using_the_antibunching_script

Anonymous (anonymous@undisclosed.example.com) — 2014-06-19T07:40:32+00:00

2014/06/19 09:36		current
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	{{tag> antibunching howto tutorial correlation analysis SymPhoTime}}		{{tag> antibunching howto tutorial correlation analysis SymPhoTime}}
-	~~TOC~~	+	~~NOTOC~~

	====== Antibunching Analysis ======		====== Antibunching Analysis ======
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	This tutorial shows step-by-step, how to calculate an antibunching curve from a fluorescence time trace of a single emitter, in this example a nanodiamond NV center, excited with a pulsed 530 nm laser.		This tutorial shows step-by-step, how to calculate an antibunching curve from a fluorescence time trace of a single emitter, in this example a nanodiamond NV center, excited with a pulsed 530 nm laser.
		+
		+	{{ youtube>bEyhuWnmFC4?large }}

	===== Background Information =====		===== Background Information =====
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	* Here it is impossible to determine the number of emitters. In this measurement the luminescence stems from several emitters.		* Here it is impossible to determine the number of emitters. In this measurement the luminescence stems from several emitters.
-