1 / 31

p = h/ λ

p = h/ λ. Slides from Yann Chemla— blame him if anything is wrong!. Optical Traps. Key points. Light generates 2 types of optical forces: scattering , gradient. Trap strength depends on light intensity, gradient. Trap is harmonic: k ~ 0.1pN/nm. Δ P. P i.

arden-carney
Download Presentation

p = h/ λ

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. p = h/λ Slides from Yann Chemla— blame him if anything is wrong!

  2. Optical Traps

  3. Key points Light generates 2 types of optical forces: scattering, gradient Trap strength depends on light intensity, gradient Trap is harmonic: k ~ 0.1pN/nm

  4. ΔP Pi Optical scattering forces – reflection Pf Pi = h/λ θ F = ΔP/Δt = (Pf-Pi)/Δt Newton’s third law – for every action there is an equal and opposite reaction

  5. Pi ΔP Optical forces – Refraction Pi Pf

  6. Bright ray Dim ray Lateral gradient force Object feels a force toward brighter light

  7. ΔP Pi Axial gradient force Focused light Pf Pi Object feels a force toward focus Force ~ gradient intensity

  8. IR traps and biomolecules are compatible Neuman et al. Biophys J. 1999

  9. Biological scales Force: 1-100 picoNewton (pN) Distance: <1–10 nanometer (nm) www.scripps.edu/cb/milligan/projects.html www.cnr.berkeley.edu/~hongwang/Project www.alice.berkeley.edu

  10. Requirements for a quantitative optical trap: 1) Manipulation – intense light (laser), large gradient (high NA objective), moveable stage (piezo stage) or trap (piezo mirror, AOD, …) 2) Measurement – collection and detection optics (BFP interferometry) 3) Calibration – convert raw data into forces (pN), displacements (nm)

  11. Laser Beam expander Photodetector Condenser Objective

  12. 1) Manipulation Want to apply forces – need ability to move stage or trap (piezo stage, steerable mirror, AOD…) DNA

  13. 2) Measurement Want to measure forces, displacements – need to detect deflection of bead from trap center 1) Video microscopy 2) Laser-based method – Back-focal plane interferometry

  14. BFP imaged onto detector Trap laser ∑ specimen Relay lens PSD BFP Conjugate image planes

  15. Out1 P In1 N N In2 P Out2 Position sensitive detector (PSD) Plate resistors separated by reverse-biased PIN photodiode Opposite electrodes at same potential – no conduction with no light

  16. Out1 P In1 N N In2 P Out2 Multiple rays add their currents linearly to the electrodes, where each ray’s power adds Wicurrent to the total sum. SIGNAL POSITION ΔX ~ (In1-In2) / (In1 + In2) ΔY ~ (Out1-Out2) /(Out1+Out2)

  17. Calibration Want to measure forces, displaces – measure voltages from PSD – need calibration Δx = α ΔV F = kΔx = α kΔV

  18. Calibrate with a known displacement Calibrate with a known force Glass water Glass Glass Move bead relative to trap Stokes law: F = γv

  19. Drag force γ = 3πηd Brownian motion as test force kBT Langevin equation: Trap force Fluctuating Brownian force <F(t)> = 0 <F(t)F(t’)> = 2kBTγδ (t-t’) kBT= 4.14pN-nm

  20. Δt Δt Δt Autocorrelation function

  21. Δt Δt Δt Autocorrelation function

  22. Brownian motion as test force Langevin equation: Exponential autocorrelation f’n FT → Lorentzian power spectrum Corner frequency fc = k/2πg

  23. Power (V2/Hz) Frequency (Hz)

  24. Reducing bandwidth reduces noise. The noise in position using equipartition theorem  you calculate for noise at all frequencies (infinite bandwidth). For a typical value of stiffness (k) = 0.1 pN/nm. <x2>1/2 = (kBT/k)1/2 = (4.14/0.1)1/2 = (41.4)1/2 ~ 6.4 nm 6.4 nm is a pretty large number. [ Kinesin moves every 8.3 nm; 1 base-pair = 3.4 Å ] If instead you collect data out to a lower bandwidth BW (100 Hz), you get a much smaller noise. (Ex: typical value of g (10-6 for ~1 mm bead in water). But (<x2>BW)1/2 = [∫const*(BW)dk]1/2= [(4kBTg100)/k]1/2 = [4*4.14*10-6*100/0.1]1/2 ~ 0.4 nm = 4 Angstrom!!

  25. 1 2 3 1 2 4 3 5 4 5 6 6 7 7 8 9 9 8 Basepair Resolution—Yann Chemla @ UIUC unpublished 1bp = 3.4Å UIUC - 02/11/08 3.4 kb DNA F ~ 20 pN f = 100Hz, 10Hz

  26. Observing individual steps Motors move in discrete steps Detailed statistics on kinetics of stepping & coordination Kinesin Step size: 8nm Asbury, et al. Science (2003)

  27. Class evaluation • What was the most interesting thing you learned in class today? • 2. What are you confused about? • 3. Related to today’s subject, what would you like to know more about? • 4. Any helpful comments. Answer, and turn in at the end of class.

More Related