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On the path to Bose-Einstein condensate (BEC) Basic concepts for achieving temperatures below 1 μK Author: Peter Ferjančič Mentors: Denis Arčon and Peter.

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Presentation on theme: "On the path to Bose-Einstein condensate (BEC) Basic concepts for achieving temperatures below 1 μK Author: Peter Ferjančič Mentors: Denis Arčon and Peter."— Presentation transcript:

1 On the path to Bose-Einstein condensate (BEC) Basic concepts for achieving temperatures below 1 μK Author: Peter Ferjančič Mentors: Denis Arčon and Peter Jeglič

2 Introduction Bose-Einstein condensate – Atomic gasses cooled to VERY low temperatures (<μK) Predicted in 1925 by Bose and Einstein produced by Eric Cornell and Carl Wieman in 1995 – Nobel prize in 2001 T c ≈ 3.3 (ħ 2 n 2/3 )/ (m k b ) For alkali atoms at n=10 14 /cm 3 T c ≈ 0.1 μK 2

3 What is Bose-Einstein condensate 10 7 condensed gas atoms large fraction of the bosons occupy the lowest quantum state – atoms become indistinguishable Basically we have one single “super atom” Potential uses: – Simulation of solid state physics systems – Precision measurement – Quantum computing 3

4 Used techniques Slowing an atomic beam Optical molasses technique The magneto-optical trap Dipole / Magnetic trapping Evaporative cooling 4

5 Slowing an atomic beam Photon momentum: p=ħk Absorbed photon – fixed direction Emitted photon – random direction For λ=589 nm and Na atom, recoil velocity Δv=3 cm/s 5

6 Slowing an atomic beam Need to compensate for Doppler effect – Frequency shift ~1.7 GHz (Natural width ~10 MHz) – Zeeman cooling – Chirp cooling Laser cooling –Nobel 1997 6

7 Optical molasses techique 3 pairs of counter-propagating laser beams When moving towards beam, absorption increases → slowing force Force proportional to velocity Doppler cooling limit: ~3 cm/s 7

8 Magneto-optical trap (MOT) Atoms diffuse from molasses in seconds for 1 cm wide beam – we should stop them! Magnetic quadrupole – B=0 in the center, increases as we move away If photons move from center zeeman eff. causes resonance atoms are pushed back by laser beams → F(x) 8

9 MOT – how to cancel reppeling? Circularly polarized lasers: ΔM = +1 for right handed or ΔM = -1 for left handed Add polarized laser beams -> F(x) Change only in rate of photon absorption These are OPTICAL forces!!! 9

10 First stage cooling experiment First MOT then molasses Prediction: ~240 μK Result: an order of magnitude LOWER temperature But why? 10

11 Sisyphus cooling A sort of optical pumping mechanism 11

12 Dipole light force Refracted light excerts force on object (photon momentum: p=ħk) Particles are attracted to areas of high light intensity = Optical tweezers Wavelength is far from resonance! 12

13 Evaporative cooling Atoms with high enough energy escape the potential – taking above average energy with them Lowering borders speeds up the process 13

14 The experiment Laser slowing of an atomic beam 900 K-> ~5 K Magneto-optical trap ~300 mK Optical molasses ~240 μK Sisyphus cooling ~ 10-100 μK Evaporative cooling in dipole trap <100 nK Bose-Einstein condensate!!! (note: temperatures are informative and highly dependant on the experiment) 14

15 De jure 1 slowing beam 3 pairs of counter propagating beams 1 pair of coils 2 dipole force lasers 15

16 De facto 16

17 Conclusion & future What are other potential uses for BEC? – Bikes vs. Light races (c=25 km/h) – Light-> matter -> light transitions- 2007 – Single spin addressing – Excellent tool for quantum mechanics 2010 – first photon BEC Cold atoms today under 500 pK 17

18 Sources Atomic Physics; Foot http://www.colorado.edu/physics/2000/bec/ http://electron9.phys.utk.edu/optics507/modules/m10/saturation.htm http://webphysics.davidson.edu/Alumni/JoCowan/honors/section1/THEORY.htm http://en.wikipedia.org/wiki/Bose-Einstein_condensate http://theory.physics.helsinki.fi/~quantumgas/Lecture4.pdf http://www.nobelprize.org/nobel_prizes/physics/laureates/1997/illpres/doppler.h tml http://www.nobelprize.org/nobel_prizes/physics/laureates/1997/illpres/doppler.h tml http://physicsworld.com/cws/article/news/41246 http://arstechnica.com/science/news/2011/01/pqe-2011-small-atoms-big-ideas- in-gravity-detection.ars http://arstechnica.com/science/news/2011/01/pqe-2011-small-atoms-big-ideas- in-gravity-detection.ars http://www.deas.harvard.edu/haulab/slow_light_project/remote_revival/remote_ revival.htm http://www.deas.harvard.edu/haulab/slow_light_project/remote_revival/remote_ revival.htm http://prl.aps.org/files/RevModPhys.70.721.pdf http://www.phys.ens.fr/~dalibard/publi2/EuroPhysNews_98.pdf http://www.asu.edu/courses/phs208/patternsbb/PiN/rdg/polarize/polarize.shtml 18

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