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'''Photothermal optical microscopy''' / "photothermal single particle microscopy" is a technique that is based on detection of non-[[fluorescence|fluorescent]] labels. It relays on absorption properties of labels ([[gold]] [[nanoparticle]]s, [[semiconductor]] [[nanocrystal]]s, etc.) Can be realized on conventional microscope using resonant modulated heating beam, non-resonant probe beam and [[lock-in]] detection of photothermal signals from a single nanoparticle. It is the extension of the macroscopic photothermal spectroscopy to the nanoscopic domain. The high sensitivity and selectivity of photothermal microscopy allows even the detection of single molecules by their absorption. Similar [[Fluorescence correlation spectroscopy|Fluorescence Correlation Spectroscopy]] (FCS) with the fluorescence signal, the photothermal signal may be recorded time-resolved to study the diffusion and advection characteristics of absorbing nanoparticles in a solution. This technique is called photothermal correlation spectroscopy (PhoCS).
 
== Forward detection scheme ==
In this detection scheme a conventional scanning sample or laser-scanning transmission microscope is employed. Both, the heating and the probing laser beam are coaxially aligned and
superimposed using a [[Dichroic filter|dichroic mirror]]. Both beams are focused onto a sample, typically via a high-NA illumination microscope objective, and recollected using a detection microscope objective. The thereby collimated transmitted beam is then imaged onto a photodiode after filtering out the heating beam. The photothermal signal is then the change <math>\Delta</math> in the transmitted probe beam power <math>P_d</math> due to the heating laser. To increase the signal-to-noise ratio a lock-in technique may be used. To this end, the heating laser beam is modulated at a high frequency of the order of MHz and the detected probe beam power is then demodulated on the same frequency. For quantitative measurements, the photothermal signal may be normalized to the background detected power <math>P_{d,0}</math> (which is typically much larger than the change <math>\Delta P_d</math>), thereby defining the relative photothermal signal <math>\Phi</math>
 
<math>
\Phi=\frac{\Delta P_d}{P_{d,0}}=\frac{P_d\left(\text{heating beam on}\right)-P_d\left(\text{heating beam off}\right)}{P_d\left(\text{background, no particle}\right)}
</math>
 
=== Detection mechanism ===
The physical basis for the photothermal signal in the transmission detection scheme is the lensing action of the refractive index profile that is created upon the absorption of the heating laser power by the nanoparticle. The signal is homodyne in the sense that a steady state difference signal accounts for the mechanism and the forward scattered field's self-interference with the transmitted beam corresponds to an energy redistribution as expected for a simple lens. The lens is a Gadient Refractive INdex (GRIN) particle determined by the 1/r refractive index profile established due to the point-source temperature profile around the nanoparticle. For a nanoparticle of radius <math>R</math> embedded in a homogeneous medium of refractive index <math>n_0</math> with a thermorefractive coefficient <math>\mathrm{d}n/\mathrm{d}T</math> the refractive index profile reads:
 
<math>n\left(\mathbf{r}\right)=n_0 + \frac{\mathrm{d}n}{\mathrm{d}T}\Delta T\left(\mathbf{r}\right)=n_0+\Delta n \frac{R}{r}</math>
 
in which the contrast of the thermal lens is determined by the nanoparticle [[Absorption (electromagnetic radiation)|absorption]] cross-section <math>\sigma_{\rm abs}</math> at the heating beam wavelength, the heating beam intensity <math>I_h</math> at the point of the particle and the embedding medium's [[thermal conductivity]] <math>\kappa</math> via <math>\Delta n=\left(\mathrm{d}n/\mathrm{d}T\right)\sigma_{\rm abs} I_h/4\pi\kappa R</math>.
Although the signal can be well-explained in a scattering framework, the most intuitive description can be found by an intuitive analogy to the Coulomb scattering of wave packets in particle physics.
 
== Backwards detection scheme ==
In this detection scheme a conventional scanning sample or laser-scanning transmission microscope is employed. Both, the heating and the probing laser beam are coaxially aligned and
superimposed using a [[Dichroic filter|dichroic mirror]]. Both beams are focused onto a sample, typically via a high-NA illumination microscope objective. Alternatively, the probe-beam may be laterally displaced with respect to the heating beam. The retroreflected probe-beam power is then imaged onto a photodiode and the change as induced by the heating beam provides the photothermal signal
 
=== Detection mechanism ===
The detection is heterodyne in the sense that the scattered field of the probe beam by the thermal lens interferes in the backwards direction with a well-defined retroreflected part of the incidence probing beam.
 
==References==
{{reflist}}
{{col-begin}}
{{col-3}}
* D. Boyer, P. Tamarat, A. Maali, B. Lounis and M. Orrit, "Photothermal Imaging of Nanometer-Sized Metal Particles Among Scatterers", Science, Vol 297, 1160-1163, 2002
* L. Cognet, C. Tardin, D. Boyer, D. Choquet, P. Tamarat and B. Lounis, "Single metallic nanoparticle imaging for protein detection in cells", PNAS, Vol. 100, No. 20, 11350–11355, 2003
* A. Gaiduk, P. V. Ruijgrok, M. Yorulmaz and M. Orrit, "Detection limits in photothermal microscopy", Chem. Sci., 1, 343–350, 2010
* M. Selmke and F. Cichos, "Photonic Rutherford Scattering: A Classical and Quantum mechanical analogy in Ray- and Wave-optics", American Journal of Physics, 2013
* M. Selmke, F. Cichos, "Photothermal single particle Rutherford scattering microscopy", Physical Review Letters, 2013
* M. Selmke, M. Braun and F. Cichos, "[http://pubs.acs.org/doi/abs/10.1021/nn300181h Photothermal single particle microscopy: Detection of a nanolens]", ACS Nano, 6 (3), pp 2741–2749, 2012
* M. Selmke, M. Braun and F. Cichos, "[http://www.opticsinfobase.org/oe/abstract.cfm?uri=oe-20-7-8055 Nano-lens diffraction around a single heated nano particle]", Optics Express, Vol. 20, No. 7, pp.&nbsp;8055–8070, 2012
* M. Selmke, M. Braun, F. Cichos, "[http://www.opticsinfobase.org/josaa/abstract.cfm?URI=josaa-29-10-2237 Gaussian Beam Photothermal Single Particle Microscopy]", Journal of the Optical Society of America A, Vol. 29, No.10, 2012
* M. Selmke, R. Schachoff, M. Braun, F. Cichos, "[http://pubs.rsc.org/en/Content/ArticleLanding/2013/RA/C2RA22061J Twin-Focus Photothermal Correlation Spectroscopy]", [[RSC Advances]], Vol. 3, pp.&nbsp;394–400, 2012
* M. Selmke, R. Schachoff, M. Braun, F. Cichos, "[http://pubs.rsc.org/en/content/articlelanding/2013/cp/c3cp44092c Photothermal Signal Distribution Analysis (PhoSDA)]", Physical Chemistry Chemical Physics, 2013
* S. E. Bialkowski ''Photothermal Spectroscopy Methods for Chemical Analysis'' John Wiley, New York '''1996'''
* [http://www.uni-leipzig.de/~physik/mona_photothermal_microscopy.html Photothermal Microscopy]
{{col-end}}
 
[[Category:Microscopy]]

Revision as of 20:52, 12 November 2013

Photothermal optical microscopy / "photothermal single particle microscopy" is a technique that is based on detection of non-fluorescent labels. It relays on absorption properties of labels (gold nanoparticles, semiconductor nanocrystals, etc.) Can be realized on conventional microscope using resonant modulated heating beam, non-resonant probe beam and lock-in detection of photothermal signals from a single nanoparticle. It is the extension of the macroscopic photothermal spectroscopy to the nanoscopic domain. The high sensitivity and selectivity of photothermal microscopy allows even the detection of single molecules by their absorption. Similar Fluorescence Correlation Spectroscopy (FCS) with the fluorescence signal, the photothermal signal may be recorded time-resolved to study the diffusion and advection characteristics of absorbing nanoparticles in a solution. This technique is called photothermal correlation spectroscopy (PhoCS).

Forward detection scheme

In this detection scheme a conventional scanning sample or laser-scanning transmission microscope is employed. Both, the heating and the probing laser beam are coaxially aligned and superimposed using a dichroic mirror. Both beams are focused onto a sample, typically via a high-NA illumination microscope objective, and recollected using a detection microscope objective. The thereby collimated transmitted beam is then imaged onto a photodiode after filtering out the heating beam. The photothermal signal is then the change Δ in the transmitted probe beam power Pd due to the heating laser. To increase the signal-to-noise ratio a lock-in technique may be used. To this end, the heating laser beam is modulated at a high frequency of the order of MHz and the detected probe beam power is then demodulated on the same frequency. For quantitative measurements, the photothermal signal may be normalized to the background detected power Pd,0 (which is typically much larger than the change ΔPd), thereby defining the relative photothermal signal Φ

Φ=ΔPdPd,0=Pd(heating beam on)Pd(heating beam off)Pd(background, no particle)

Detection mechanism

The physical basis for the photothermal signal in the transmission detection scheme is the lensing action of the refractive index profile that is created upon the absorption of the heating laser power by the nanoparticle. The signal is homodyne in the sense that a steady state difference signal accounts for the mechanism and the forward scattered field's self-interference with the transmitted beam corresponds to an energy redistribution as expected for a simple lens. The lens is a Gadient Refractive INdex (GRIN) particle determined by the 1/r refractive index profile established due to the point-source temperature profile around the nanoparticle. For a nanoparticle of radius R embedded in a homogeneous medium of refractive index n0 with a thermorefractive coefficient dn/dT the refractive index profile reads:

n(r)=n0+dndTΔT(r)=n0+ΔnRr

in which the contrast of the thermal lens is determined by the nanoparticle absorption cross-section σabs at the heating beam wavelength, the heating beam intensity Ih at the point of the particle and the embedding medium's thermal conductivity κ via Δn=(dn/dT)σabsIh/4πκR. Although the signal can be well-explained in a scattering framework, the most intuitive description can be found by an intuitive analogy to the Coulomb scattering of wave packets in particle physics.

Backwards detection scheme

In this detection scheme a conventional scanning sample or laser-scanning transmission microscope is employed. Both, the heating and the probing laser beam are coaxially aligned and superimposed using a dichroic mirror. Both beams are focused onto a sample, typically via a high-NA illumination microscope objective. Alternatively, the probe-beam may be laterally displaced with respect to the heating beam. The retroreflected probe-beam power is then imaged onto a photodiode and the change as induced by the heating beam provides the photothermal signal

Detection mechanism

The detection is heterodyne in the sense that the scattered field of the probe beam by the thermal lens interferes in the backwards direction with a well-defined retroreflected part of the incidence probing beam.

References

43 year old Petroleum Engineer Harry from Deep River, usually spends time with hobbies and interests like renting movies, property developers in singapore new condominium and vehicle racing. Constantly enjoys going to destinations like Camino Real de Tierra Adentro. Template:Col-begin Template:Col-3

  • D. Boyer, P. Tamarat, A. Maali, B. Lounis and M. Orrit, "Photothermal Imaging of Nanometer-Sized Metal Particles Among Scatterers", Science, Vol 297, 1160-1163, 2002
  • L. Cognet, C. Tardin, D. Boyer, D. Choquet, P. Tamarat and B. Lounis, "Single metallic nanoparticle imaging for protein detection in cells", PNAS, Vol. 100, No. 20, 11350–11355, 2003
  • A. Gaiduk, P. V. Ruijgrok, M. Yorulmaz and M. Orrit, "Detection limits in photothermal microscopy", Chem. Sci., 1, 343–350, 2010
  • M. Selmke and F. Cichos, "Photonic Rutherford Scattering: A Classical and Quantum mechanical analogy in Ray- and Wave-optics", American Journal of Physics, 2013
  • M. Selmke, F. Cichos, "Photothermal single particle Rutherford scattering microscopy", Physical Review Letters, 2013
  • M. Selmke, M. Braun and F. Cichos, "Photothermal single particle microscopy: Detection of a nanolens", ACS Nano, 6 (3), pp 2741–2749, 2012
  • M. Selmke, M. Braun and F. Cichos, "Nano-lens diffraction around a single heated nano particle", Optics Express, Vol. 20, No. 7, pp. 8055–8070, 2012
  • M. Selmke, M. Braun, F. Cichos, "Gaussian Beam Photothermal Single Particle Microscopy", Journal of the Optical Society of America A, Vol. 29, No.10, 2012
  • M. Selmke, R. Schachoff, M. Braun, F. Cichos, "Twin-Focus Photothermal Correlation Spectroscopy", RSC Advances, Vol. 3, pp. 394–400, 2012
  • M. Selmke, R. Schachoff, M. Braun, F. Cichos, "Photothermal Signal Distribution Analysis (PhoSDA)", Physical Chemistry Chemical Physics, 2013
  • S. E. Bialkowski Photothermal Spectroscopy Methods for Chemical Analysis John Wiley, New York 1996
  • Photothermal Microscopy

Template:Col-end

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