2. z n + a n-1 z +... +a 0 = (z – z n ) (z – z n-1 )... (z – z 1 ) and the Measurement of the Shortest Rick Trebino School of Physics Georgia Institute of Technology Atlanta, GA 30332 The Musical Score, the Fundamental Theorem of Algebra, Events Ever Created The Musical Score

3. In order to measure an event in time, you need a shorter one. To study this event, you need a strobe light pulse that’s shorter. But then, to measure the strobe light pulse, you need a detector whose response time is even shorter. And so on… So, now, how do you measure the shortest event? Photograph taken by Harold Edgerton, MIT The Dilemma

4. Ultrashort laser pulses are the shortest technological events ever created by humans. It’s routine to generate pulses shorter than 10 -13 seconds in duration, and researchers have generated pulses only a few fs (10 -15 s) long. Such a pulse is to one second as 5 cents is to the US national debt. Such pulses have many applications in physics, chemistry, biology, and engineering. You can measure any event—as long as you’ve got a pulse that’s shorter. So how do you measure the pulse itself? You must use the pulse to measure itself. But that isn’t good enough. It’s only as short as the pulse. It’s not shorter. Techniques based on using the pulse to measure itself have not sufficed.

5. A laser pulse has the time-domain electric field: E I(t) 1/ 2 exp [ i   t – i  (t) ] } IntensityPhase (t) = Re { Equivalently, vs. frequency: exp[ -i  (  –  0 ) ] } Spectral Phase (neglecting the negative-frequency component) E(  ) = Re { ~ S(   ) 1/ 2 We must measure an ultrashort laser pulse’s intensity and phase vs. time or frequency. Spectrum Knowledge of the intensity and phase or the spectrum and spectral phase is sufficient to determine the pulse.

6.  t    d  dt The instantaneous frequency: Example: “Linear chirp” Phase,  (t) time Frequency,  (t) time We’d like to be able to measure, not only linearly chirped pulses, but also pulses with arbitrarily complex phases and frequencies vs. time. The phase determines the pulse’s frequency (i.e., color) vs. time.

7. Autocorr 2

8. Perhaps it’s time to ask how researchers in other fields deal with their waveforms… Consider, for example, acoustic waveforms. Autocorrelation and related techniques yield little information about the pulse.

9. It’s a plot of frequency vs. time, with information on top about the intensity. The musical score lives in the “time-frequency domain.” Most people think of acoustic waves in terms of a musical score.

10. If E(t) is the waveform of interest, its spectrogram is: where g ( t -  ) is a variable-delay gate function and  is the delay. Without g ( t -  ), Sp E ( ,  ) would simply be the spectrum. Spectrogram

12. Frequency Time Delay Spectrograms for Linearly Chirped Pulses

13. Properties of the Spectrogram The spectrogram resolves the dilemma! It doesn’t need the shorter event! It temporally resolves the slow components and spectrally resolves the fast components. Algorithms exist to retrieve E(t) from its spectrogram. The spectrogram essentially uniquely determines the waveform intensity, I(t), and phase,  (t). There are a few ambiguities, but they are “trivial.” The gate need not be—and should not be—significantly shorter than E(t). Suppose we use a delta-function gate pulse: = The Intensity. No phase information!

14. “Polarization-Gate” Geometry Spectro- meter Frequency-Resolved Optical Gating (FROG) Trebino, et al., Rev. Sci. Instr., 68, 3277 (1997). Kane and Trebino, Opt. Lett., 18, 823 (1993).

15. FROG

16. Frequency Time Delay FROG Traces for Linearly Chirped Pulses

17. Frequency Intensity Time Delay FROG Traces for More Complex Pulses Frequency Delay

18. Unfortunately, spectrogram inversion algorithms require that we know the gate function. Substituting for E sig (t,  ) in the expression for the FROG trace: yields: E sig (t,  )  E(t) |E(t–  )| 2 where: g(t–  )  |E(t–  )| 2 The FROG trace is a spectrogram of E(t).

19. If E sig (t,  ), is the 1D Fourier transform with respect to delay  of some new signal field, E sig (t,  ), then: So we must invert this integral equation and solve for E sig (t,  ). This integral-inversion problem is the 2D phase-retrieval problem, for which the solution exists and is unique. And simple algorithms exist for finding it. and  The input pulse, E(t), is easily obtained from E sig (t,  ) : E(t)  E sig (t,  )  Instead, consider FROG as a two- dimensional phase-retrieval problem.  Stark, Image Recovery, Academic Press, 1987.

20. 1D Phase Retrieval: Suppose we measure S (  ) and desire E(t), where: Given S(k x,k y ), there is essentially one solution for E(x,y) !!! It turns out that it’s possible to retrieve the 2D spectral phase!. Given S (  ), there are infinitely many solutions for E(t). We lack the spectral phase. 2D Phase Retrieval: Suppose we measure S(k x,k y ) and desire E(x,y) : These results are related to the Fundamental Theorem of Algebra. We assume that E(t) and E(x,y) are of finite extent. 1D vs. 2D Phase Retrieval Stark, Image Recovery, Academic Press, 1987.

21. The Fundamental Theorem of Algebra states that all polynomials can be factored: f N-1 z N-1 + f N-2 z N-2 + … + f 1 z + f 0 = f N-1 (z–z 1 ) (z–z 2 ) … (z–z N–1 ) The Fundamental Theorem of Algebra fails for polynomials of two variables. Only a set of measure zero can be factored. f N-1,M-1 y N-1 z M-1 + f N-1,M-2 y N-1 z M-2 + … + f 0,0 = ? Why does this matter? The existence of the 1D Fundamental Theorem of Algebra implies that 1D phase retrieval is impossible. The non-existence of the 2D Fundamental Theorem of Algebra implies that 2D phase retrieval is possible. Phase Retrieval and the Fundamental Theorem of Algebra

22. 1D Phase Retrieval and the Fundamental Theorem of Algebra The Fourier transform {F 0, …, F N-1 } of a discrete 1D data set, { f 0, …, f N-1 }, is: where z = e –ik The Fundamental Theorem of Algebra states that any polynomial, f N-1 z N-1 + … + f 0, can be factored to yield: f N-1 (z–z 1 ) (z–z 2 ) … (z–z N–1 ) So the magnitude of the Fourier transform of our data can be written: |F k | = | f N-1 (z–z 1 ) (z–z 2 ) … (z–z N–1 ) | where z = e –ik Complex conjugation of any factor(s) leaves the magnitude unchanged, but changes the phase, yielding an ambiguity! So 1D phase retrieval is impossible! Phase Retrieval & the Fund Thm of Algebra 2 polynomial!

23. 2D Phase Retrieval and the Fundamental Theorem of Algebra The Fourier transform {F 0,0, …, F N-1,N-1 } of a discrete 2D data set, { f 0.0, …, f N-1,N-1 }, is: where y = e –ik and z = e –iq But we cannot factor polynomials of two variables. So we can only complex conjugate the entire expression (yielding a trivial ambiguity). Only a set of polynomials of measure zero can be factored. So 2D phase retrieval is possible! And the ambiguities are very sparse. Phase Retrieval & the Fund Thm of Algebra 2 Polynomial of 2 variables!

24. E sig (t,  )  E(t) |E(t–  )| 2 E sig (t,  ) Generalized Projections

25. Kohler traces

26. Single-shot FROG gives real-time feedback on laser performance. A grating pulse compressor requires the precise grating spacing, or the pulse will be chirped (positively or negatively). This can be a difficult alignment problem. Note that the trace is rotated by 90˚. Data taken by Toth and coworkers

27. Shortest pulse length Year Shortest pulse vs. year Plot prepared in 1994, reflecting the state of affairs at that time.

28. The measured pulse spectrum had two humps, and the measured autocorrelation had wings. 10-fs spectra and autocorrs Data courtesy of Kapteyn and Murnane, WSU Despite different predictions for the pulse shape, both theories were consistent with the data. Two different theories emerged, and both agreed with the data. From Harvey et. al, Opt. Lett., v. 19, p. 972 (1994) From Christov et. al, Opt. Lett., v. 19, p. 1465 (1994)

29. FROG distinguishes between the theories. Taft, et al., J. Special Topics in Quant. Electron., 3, 575 (1996).

30. SHG FROG Measurements of a 4.5-fs Pulse! Baltuska, Pshenichnikov, and Weirsma, J. Quant. Electron., 35, 459 (1999).

31. Measurement of Ultrabroadband Continuum Ultrabroadband continuum was created by propagating 1-nJ, 800- nm, 30-fs pulses through 16 cm of Lucent microstructure fiber. The 800-nm pulse was measured with FROG, so it made an ideal known gate pulse. This pulse has a time-bandwidth product of > 1000, and is the most complex ultrashort pulse ever measured. XFROG trace Retrieved intensity and phase Kimmel, Lin, Trebino, Ranka, Windeler, and Stentz, CLEO 2000.

32. Sensitivity of FROG

33. Because ultraweak ultrashort pulses are almost always created by much stronger pulses, a stronger reference pulse is always available. Use Spectral Interferometry This involves no nonlinearity!... and only one delay! E unk E ref  Spectrometer Camera  frequency FROG + SI = TADPOLE (Temporal Analysis by Dispersing a Pair Of Light E-fields) Froehly, et al., J. Opt. (Paris) 4, 183 (1973) Lepetit, et al., JOSA B, 12, 2467 (1995) C. Dorrer, JOSA B, 16, 1160 (1999) Fittinghoff, et al., Opt. Lett., 21, 884 (1996). Measuring Ultraweak Ultrashort Light Pulses

34. 1 microjoule = 10 – 6 J1 nanojoule = 10 – 9 J1 picojoule = 10 –12 J1 femtojoule = 10 –15 J1 attojoule = 10 –18 J with as little energy as: 10 TADPOLE can measure pulses 1 zeptojoule = –21 J A pulse train containing only 42 zepto- joules (42 x 10 -21 J) per pulse has been measured. That’s one photon every five pulses! Fittinghoff, et al., Opt. Lett. 21, 884 (1996). Sensitivity of Spectral Interferometry (TADPOLE)

35. POLLIWOG (POLarization-Labeled Interference vs. Wavelength for Only a Glint*) * Glint = “a very weak, very short pulse of light” Unpolarized light doesn’t exist…

36. Measurement of the variation of the polarization state of the emission from a GaAs-AlGaAs multiple quantum well when heavy-hole and light-hole excitons are excited elucidates the physics of these devices. Evolution of the polarization of the emission: A. L. Smirl, et al., Optics Letters, Vol. 23, No. 14 (1998) Application of POLLIWOG Excitation-laser spectrum and hh and lh exciton spectra time (fs)

37. 2 alignment  parameters  (  )  Can we simplify FROG? SHG crystal Pulse to be measured Variable delay Camera Spec- trom- eter FROG has 3 sensitive alignment degrees of freedom (  of a mirror and also delay). The thin crystal is also a pain. 1 alignment  parameter  (delay)  Crystal must be very thin, which hurts sensitivity. SHG crystal Pulse to be measured Remarkably, we can design a FROG without these components! Camera

38. Very thin crystal creates broad SH spectrum in all directions. Standard autocorrelators and FROGs use such crystals. Very Thin SHG crystal Thin crystal creates narrower SH spectrum in a given direction and so can’t be used for autocorrelators or FROGs. Thin SHG crystal Thick crystal begins to separate colors. Thick SHG crystal Very thick crystal acts like a spectrometer! Why not replace the spectrometer in FROG with a very thick crystal? Very thick crystal Suppose white light with a large divergence angle impinges on an SHG crystal. The SH generated depends on the angle. And the angular width of the SH beam created varies inversely with the crystal thickness. The angular width of second harmonic varies inversely with the crystal thickness.

39. GRating-Eliminated No-nonsense Observation of Ultrafast Incident Laser Light E-fields (GRENOUILLE) Patrick O’Shea, Mark Kimmel, Xun Gu and Rick Trebino, Optics Letters, 2001; Trebino, et al., OPN, June 2001.

40. GRENOUILLE Beam Geometry

41. Really Testing GRENOUILLE Even for highly structured pulses, GRENOUILLE allows for accurate reconstruction of the intensity and phase. GRENOUILLEFROG Measured: Retrieved: Retrieved pulse in the time and frequency domains

42. FROG has a few advantages!

43. www.physics.gatech.edu/frog To learn more, see the FROG web site! Or read the cover story in the June 2001 issue of OPN Or read the book!