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M. R. Otto , L. P. René de Cotret , M. J. Stern , B. J. Siwick; Solving the jitter problem in microwave compressed ultrafast electron diffraction instruments: Robust sub-50 fs cavity-laser phase stabilization. Struct. Dyn. 1 September 2017; 4 (5): 051101. https://doi.org/10.1063/1.4989960

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  • We demonstrate the compression of electron pulses in a high-brightness ultrafast electron diffraction instrument using phase-locked microwave signals directly generated from a mode-locked femtosecond oscillator. Additionally, a continuous-wave phase stabilization system that accurately corrects for phase fluctuations arising in the compression cavity from both power amplification and thermal drift induced detuning was designed and implemented. An improvement in the microwave timing stability from 100 fs to 5 fs RMS is measured electronically, and the long-term arrival time stability ( > 10 h) of the electron pulses improves to below our measurement resolution of 50 fs. These results demonstrate sub-relativistic ultrafast electron diffraction with compressed pulses that is no longer limited by laser-microwave synchronization.

    Ultrashort electron pulses are finding diverse applications in research aimed at imaging the dynamic structure of matter. 1–4 Generation of these pulses normally starts with photoemission driven by a femtosecond laser pulse at a photocathode, after which Coulomb repulsion internal to the photo-generated bunch takes hold (space-charge) broadening both the temporal duration and energy distribution. 5 Unmodified by external fields, these space-charge dynamics result in a trade-off between pulse fluence and time resolution that is detrimental to ultrafast electron diffraction (UED) and imaging experiments. As a result, there have been a number of efforts to correct such broadening through the addition of electron pulse compression strategies that employ microwave, 6–11 terahertz 12 and DC electric fields. 13–15 These approaches work by inverting the space-charge driven expansion that occurs naturally in the pulse, leading to a temporal focus downstream from the pulse-field interaction. Microwave compression, in particular, has been demonstrated to be very effective in the single shot limit, yielding electron pulses below 100 fs at 100 keV (Ref. 9 ) and very recently sub-10 fs at 7 MeV (Ref. 16 ) that contain more than 10 5 electrons. Unfortunately, the stability of the cavity-laser synchronization systems that have been employed to date has been insufficient to provide pulse duration limited time-resolution in ultrafast electron diffraction instruments over longer data acquisition times (several hours). Published reports have all concluded that time-resolution in microwave compressed instruments has been closer to 400 fs due to “time-zero” drift that results from various cavity-laser phase synchronization instabilities 7,8,11 that are evident in the frequency range from kHz to μ Hz. As a result of these drifts, the primary benefit of microwave pulse compression has been an increase in bunch charge rather than a dramatic improvement in time-resolution.

    For UED pump-probe experiments, synchronizing the laser system with a microwave signal has been previously achieved by phase-locking loops (PLL) using external voltage-controlled oscillators 7,8,17 or repetition rate multiplication techniques, 18 which involve optical enhancement cavities. Both approaches involve the derivation of a locked harmonic in the GHz range with sufficient spectral power and sufficiently low phase noise. Timing and frequency stability is fundamentally limited by amplitude-phase conversion inherent to the photodetection process 19–21 and depends on the pulse energy stability of the laser. For the case of the phase-locked loop, the amplitude-phase conversion also manifests in microwave mixers when comparing two signals, yielding phase errors produced by power fluctuations. For UED synchronization systems to date, the focus has been primarily on the frequency range above 1 Hz, with minimal consideration of drift on timescales up to several hours, which are of particular relevance for experiments. Such drifts cause t = 0 to change over the course of many pump-probe delay scans and arise most significantly in sensitive elements such as the compression cavity and power amplification which are typically omitted from the synchronization configuration. 22 In this work, we demonstrate stable, passive generation of a 3 GHz signal by direct photodetection of the laser pulse train and its use for compression of electron pulses in a 100 keV in a high-brightness ( 10 6 e / pulse) ultrafast electron diffraction instrument. We also present an all-microwave active synchronization enhancement system which measures and compensates for phase fluctuations arising in the compression system. We measure greater than a ten-fold improvement in the laser-microwave synchronization quality by directly measuring phase changes of the cavity field using an integrated antenna. We further demonstrate, using a streak camera, that the phase stabilization system improves the long-term stability of the pulse arrival time and the temporal impulse response function (IRF) of the UED instrument by correcting for phase over a very broad low-frequency band. This improved performance is due to the elimination of several sources of phase instability inherent in previous approaches: (i) amplitude phase errors in PLL generation of microwave signal, (ii) phase instability in power amplification, and (iii) phase drift in the cavity response due to thermal induced frequency detuning.

    The master clock of the instrument used in this work is a mode-locked Ti:Sapphire oscillator with a fundamental repetition rate of f rep 74.98 MHz. A synchronized microwave signal is generated by sampling a portion of the oscillator laser output using a fast photo-diode (Newport 818-BB-45) with a bandwidth of 12.5 GHz (Fig. 1 ). This signal is filtered by a coarse band-pass filter (Mini-Circuits VBF-2900+) to select the relevant harmonic ( f d = 40 × f rep ) and sent to an ultra-low phase noise narrow band amplifier (Miteq AMF-2F-LPN) providing roughly 30 dB of gain. The amplified output filtered by a cavity band-pass filter centered at 2.9985 GHz with a bandwidth of 50 MHz to further isolate the desired harmonic signal. Reflected signals from harmonics outside the pass-band are isolated and dumped to a 50 Ω load to maintain the directivity of the signal generation circuit. The signal is amplified by a low phase noise amplifier (Holzworth HX2400) and then a saturated low noise amplifier (Fairview SLNA-060-40-09) in order to achieve the optimal power stability. The signal is then split into two paths. The first path is continuous-wave amplified to high-power (typically 46–48 dBm) and used to drive the microwave electron pulse compression cavity (see Fig. 1 ), which has a TM 010 resonant mode of f 0 = 2.9985 GHz at 19 °C, an unloaded quality factor of Q 1.2 × 10 4 , and a bandwidth of δ 250 kHz. In order to improve the synchronization quality of the instrument, we must account for phase changes produced by elements in this first signal path relative to those in the second, which we will consider to be our stable phase reference.

    FIG. 1.

    Direct generation of synchronized microwaves and active phase stabilization for electron pulse compression. A portion of the output of a mode-locked Ti:Sapphire oscillator ( f rep 74.98 MHz) is incident on a high-bandwidth (12.5 GHz) GaAs photodiode. The 40th harmonic is generated by filtering using narrow bandpass filters and ultra-low phase noise microwave amplifiers. The power of the synchronized drive signal f d = 40 × f rep 2.9985 GHz is roughly + 16 dBm after passing through the final amplifier operated in saturation. The signal is split and the first serves as a reference signal carrying a phase ϕ ref and is fed to the local oscillator (LO) port of a phase detector. The second signal is amplified by a CW solid-state power amplifier and drives the resonant cavity for electron pulse compression. An antenna integrated into the cavity retrieves the phase ϕ cav + Δ ϕ 0 by coupling directly to the electric field and produces an output signal, which is attenuated and amplified to reach a power identical to that of the reference signal before coupling to the second input (RF) of the phase detector. The feedback system maintains a constant value of ϕ ref ϕ cav by shifting the phase of ϕ cav in order to eliminate fluctuations Δ ϕ 0 .

    FIG. 1.

    Direct generation of synchronized microwaves and active phase stabilization for electron pulse compression. A portion of the output of a mode-locked Ti:Sapphire oscillator ( f rep 74.98 MHz) is incident on a high-bandwidth (12.5 GHz) GaAs photodiode. The 40th harmonic is generated by filtering using narrow bandpass filters and ultra-low phase noise microwave amplifiers. The power of the synchronized drive signal f d = 40 × f rep 2.9985 GHz is roughly + 16 dBm after passing through the final amplifier operated in saturation. The signal is split and the first serves as a reference signal carrying a phase ϕ ref and is fed to the local oscillator (LO) port of a phase detector. The second signal is amplified by a CW solid-state power amplifier and drives the resonant cavity for electron pulse compression. An antenna integrated into the cavity retrieves the phase ϕ cav + Δ ϕ 0 by coupling directly to the electric field and produces an output signal, which is attenuated and amplified to reach a power identical to that of the reference signal before coupling to the second input (RF) of the phase detector. The feedback system maintains a constant value of ϕ ref ϕ cav by shifting the phase of ϕ cav in order to eliminate fluctuations Δ ϕ 0 .

    Close modal

    We will now discuss more precisely the nature of the phase instabilities we address in this work. At optimal pulse compression timing, the phase of the drive signal ϕ 0 is such that electrons at the center of the dispersed pulse arrive during when the electric field oscillation in the cavity is E ( t ) = 0. This is achieved by varying the phase of the signal before high-power amplification. The momentum transferred to an electron pulse by an electric field E ( t ) = E 0 z exp ( i ω d t + ϕ 0 ) is given by

    p z = e E 0 z exp ( i ω d t + ϕ 0 ) d t ,
    (1)

    where E 0 z is the cavity field along the propagation axis of the electron pulse, ω d = 2 π f d , and the integral spans the time during which an electron pulse interacts the cavity field. By Eq. (1) , phase fluctuations, which we denote as Δ ϕ 0 , cause variations in the average momentum transferred to electrons in the pulse Δ p z [see Fig. 2(a) ] and consequently yield a change in the arrival time at the temporal focus of the cavity given by Δ t = Δ ϕ 0 / ω d . 23 External phase fluctuations arise primarily from two sources. The first is phase instabilities caused by high-power amplification which we write as Δ ϕ 0 A . The second source of phase drift arises from frequency detuning between the cavity resonance and the drive signal, ω d ω 0 . This leads to changes in the microwave transmission properties of the cavity [see Fig. 1(b) ]. In the vicinity of resonance ( Δ ω < δ ), detuning produces a corresponding phase change in the cavity 23 given by

    Δ ϕ 0 d = 2 Q ω d ω 0 ω 0 .
    (2)

    Clearly, both ω d and ω 0 impact Eq. (2) and can vary independently. ω d is determined by the value of the oscillator repetition rate and thus variations on the order of 0.1 1 kHz are expected on timescales on the order of days. The cavity resonance is sensitively a function of temperature, 23 for which changes in the range of a few mK yield variations in ω 0 also on the order of 0.1 1 kHz. These sources of detuning yield timing changes in excess of Δ t = Δ ϕ 0 d / ω d > 100 fs. We write the total arrival time drift due to both sources of phase fluctuations as Δ t = 1 ω d ( Δ ϕ 0 A + Δ ϕ 0 d ) , which has the effect of shifting the pump-probe delay (time-zero) during the course of an experiment, thus degrading the temporal resolution of the instrument. It is therefore critical to accurately sample the electric field and phase changes occurring in the resonant cavity to determine the relevant timing fluctuations impacting electron pulses in an UED instrument.

    FIG. 2.

    (a) Illustration of the effect of phase instabilities. Changes in phase Δ ϕ 0 of the electric field oscillation in the compression cavity relative to the arrival of an electron pulse cause a change in momentum transfer to the compressed pulse Δ p z . (b) Simulation of the amplitude and phase of the S 21 ( f ) transmission function for our 3 GHz microwave compression cavity. Detuning between the drive frequency f 0 and cavity resonance f d lead to a phase shift Δ ϕ 0 of the cavity field.

    FIG. 2.

    (a) Illustration of the effect of phase instabilities. Changes in phase Δ ϕ 0 of the electric field oscillation in the compression cavity relative to the arrival of an electron pulse cause a change in momentum transfer to the compressed pulse Δ p z . (b) Simulation of the amplitude and phase of the S 21 ( f ) transmission function for our 3 GHz microwave compression cavity. Detuning between the drive frequency f 0 and cavity resonance f d lead to a phase shift Δ ϕ 0 of the cavity field.

    Close modal

    Detection of phase changes is achieved by measuring the signal transmitted through the cavity using an integrated pick-up antenna (see Fig. 1 ), which retrieves the electric field inside the cavity. The collected signal is attenuated and passed through a saturated low-phase noise amplifier (Holzworth HX2400) to maintain a stable power of +12.0 dBm. This signal is then sent to a phase detector (Holzworth HX3400). The detector compares the phase of this signal (RF), ϕ cav , with the phase of the pre-compression reference signal (LO), ϕ ref . Since both signals have the same frequency f d , the detector produces a DC voltage proportional to the phase difference between the two signals V ϕ 0 = κ det ( ϕ ref ϕ cav ) . κ det = 320 mV/rad is the phase detector constant determined via calibration. Due to the character of the phase response shown in Fig. 2(b) , we assume that Δ ϕ 0 arises dominantly from the compression cavity with secondary high-frequency components from the solid-state power amplifier, therefore, ϕ cav ϕ cav + Δ ϕ 0 and V ϕ = V ϕ 0 + Δ V . The changes in the detector output voltage Δ V allow for a phase drift to be monitored with respect to the initial starting value V ϕ 0 (i.e., optimal compression settings). Information from the phase detector signal may also be used to correct for phase drifts by precisely shifting the phase of the microwave drive signal. This ensures that phase changes relative to the initial set-point value are minimized. We implement this using a low-noise fully analog microwave phase shifter (Analog Devices HMC928LP5E). The phase detector output voltage is amplified by a factor of 10 to optimize the detection resolution of a fully analog proportional integral derivative (PID) controller (Stanford Research Systems SIM 960), which has an operating bandwidth of 1 kHz. A schematic of the active phase feedback system is illustrated in Fig. 1 . We characterize the improvement of the instrument by measuring the detector output voltage over the duration of a typical experiment (several hours). The output voltage is converted to phase and timing drift using κ det and the drive frequency ω d . A comparison with the feedback and control on and off is presented in Fig. 3(a) . Without feedback, detuning instabilities produce synchronization drift on the order of hundreds of fs [see Fig. 3(a) ]. With feedback, we see a significant improvement for which the synchronization drift below is 5 fs RMS. The phase stabilization system reduces the power spectral density of the timing noise (relative to the signal pre-amplification) by over an order of magnitude across 5 low-frequency decades, as seen in Fig. 3(b) . Both low-frequency thermal detuning drifts in the cavity and mid-frequency jitter are continuously corrected over long timescales.

    FIG. 3.

    (a) Electronic phase timing measurement of the detection system in Fig. 1 . Data for feedback off (red) and on (blue) are compared over the course of several hours and histograms of the phase distribution are shown in the inset. (b) Additive timing noise power spectral density of the data shown in (a).

    FIG. 3.

    (a) Electronic phase timing measurement of the detection system in Fig. 1 . Data for feedback off (red) and on (blue) are compared over the course of several hours and histograms of the phase distribution are shown in the inset. (b) Additive timing noise power spectral density of the data shown in (a).

    Close modal

    We also directly measure the change in the arrival time of the electron pulses with respect to a femtosecond optical pump pulse using an optically triggered 10 GHz streak camera similar to that presented in Ref. 24 . By tracking the center of the streaked electron pulse on a CCD camera, we may quantify timing drifts in a manner which replicates a typical pump-probe UED experiment up to the limits imposed by the streak camera itself. We operate at a laser amplifier repetition rate of 1 kHz and a CCD exposure time of 1 s. The streaked electron pulse is fit to a 2D Gaussian function to accurately determine the center position. A relationship between the streaked pulse position and time depends on the geometry of instrument and also the circuit properties of the streak camera. A calibration measurement was performed, and a streak velocity of v s = 84 μ m/ps was determined. The streak camera itself has a finite temporal resolution which we determine to be τ s 50 fs RMS using the statistics of an unstreaked electron pulse and the pulse spot size. 24,25 A comparison of the electron pulse arrival time stability with and without feedback control is shown in Figs. 4(a) and 4(c) . We find a significant improvement in the arrival time stability to better than Δ t = 50 fs over the duration of many hours. This result is a significant improvement for high-brightness multi-shot ultrafast electron diffraction systems implementing microwave pulse compression. 7,8,25 The remaining temporal drift may be explained in terms of feedback over-correction due to amplitude-phase conversion arising in the phase detector. Amplitude fluctuations lead to changes in DC voltage which cannot be differentiated by the analog feedback control system. We determine an amplitude coefficient 54 mV/dBm by varying the power of the RF (compression cavity) signal. When converted to phase using the phase detector constant, κ det , we have a phase error coefficient of 0.17 rad/dBm. An amplifier drift on the order of ± 0.02 dBm will yield a phase timing changes of roughly 180 fs, which explains the correlation between arrival time drift and cavity power depicted in Fig. 4(b) . This effect could potentially be minimized by using limiters and/or microwave power stabilization hardware. For the case where sufficient power amplifier stability may not be achieved, the phase detection system may be used passively (no feedback control) to log phase drift, the amplitude converted portion of the detector signal may be easily removed by measuring power, and a time-stamping procedure can be performed. 25,26 Finally, we characterize the temporal impulse response function (IRF) of the instrument. The temporal RMS pulse duration τ e of the electron pulse is given by the deconvolution of a reference (unstreaked) electron spot and streaked spot. This is written as τ e = v s 1 σ ref 2 σ s 2 , where σ ref and σ s are determined from fitting the unstreaked and streaked electron spot, respectively, to a 2D Gaussian function. The streak velocity v s = 84 μ m/ps was determined by a measurement of the streak field ring-down. Pulse images are taken as a function of cavity phase, and σ ref and σ s are determined for each acquisition. The impulse response function is determined for a pulse charge of 0.2 pC and a forward power of 44.7 W. At each phase value, 30 pictures at 1 s exposure and 1 kHz repetition rate time are collected and the average values σ ref and σ s are determined. The averages reflect 3 × 10 4 individual electron pulses, which are limited by jitter faster than the 1 s CCD integration time. The IRF as a function of phase is shown in Fig. 4(d) . We find that the IRF approaches 50 fs for optimal power and phase, at which point the measurement is limited by the temporal resolution of the streak camera. We measure an upper limit IRF of τ e = 45 ± 2 fs (106 fs full-width at half-maximum). We note that this is an improvement by over a factor of 3 when compared to previously reported instrument performance. 7,8,11 We attribute this enhancement in performance to the direct generation of phase-locked microwaves, and the use of stable continuous-wave high-power microwave amplification in conjunction with active phase stabilization. The total temporal impulse response function τ is given by τ = τ e 2 + Δ t 2 . Including the contribution from long-term drift shown in Fig. 4(c) of Δ t = 50 fs we determine τ 68 fs RMS. To the best of our knowledge, this is the lowest measured temporal impulse response function for a high-brightness, multi-shot, sub-relativistic ultrafast electron diffraction instrument.

    FIG. 4.

    (a) Electron pulse arrival time measured with phase feedback control both off (red) and on (blue). (b) Correlation between arrival time and cavity power arising from amplitude-phase error in the feedback system. (c) Histograms of the traces shown in (a) depicting the long-term stability of time-zero. (d) The temporal impulse response function of the UED instrument as a function of phase for a bunch charge of 0.2 pC and a cavity power of 44.7 W. The dashed red line represents the time-resolution of the streak camera.

    FIG. 4.

    (a) Electron pulse arrival time measured with phase feedback control both off (red) and on (blue). (b) Correlation between arrival time and cavity power arising from amplitude-phase error in the feedback system. (c) Histograms of the traces shown in (a) depicting the long-term stability of time-zero. (d) The temporal impulse response function of the UED instrument as a function of phase for a bunch charge of 0.2 pC and a cavity power of 44.7 W. The dashed red line represents the time-resolution of the streak camera.

    Close modal

    In conclusion, we have achieved ultrafast electron diffraction with pulse compression using phase-locked microwaves synthesized directly from a mode-locked oscillator. Furthermore, we have designed and characterized a high-performance integrated microwave phase feedback system which compensates for detuning induced phase fluctuations in compression cavities improving the laser-microwave synchronization level by a factor of 10 to below 5 fs RMS. The long-term arrival time stability of the electron pulse is also improved from > 200 fs to < 50 fs RMS with phase stabilization. The impulse response function of the instrument is measured to be less than 70 fs RMS over many hours. Our results illustrate that high-brightness UED instruments can be realized in a simpler approach and pushed to a regime where time-resolution is limited by the duration of the compressed electron pulse, not synchronization quality.

    This work was supported by the Natural Sciences and Engineering Research Council of Canada (NSERC), the Fonds de Recherche du Québec—Nature et Technologies (FRQNT), the Canada Foundation for Innovation (CFI), and Canada Research Chairs (CRC) program.

    1.
    G.
    Sciaini
    and
    R. J.
    Dwayne Miller
    , “
    Femtosecond electron diffraction: Heralding the era of atomically resolved dynamics
    ,”
    Rep. Prog. Phys.
    74
    (
    9
    ),
    096101
    (
    2011
    ).
    2.
    V. R.
    Morrison
    ,
    R. P.
    Chatelain
    ,
    K. L.
    Tiwari
    ,
    A.
    Hendaoui
    ,
    A.
    Bruhács
    ,
    M.
    Chaker
    , and
    B. J.
    Siwick
    , “
    A photoinduced metal-like phase of monoclinic VO 2 revealed by ultrafast electron diffraction
    ,”
    Science
    346
    (
    6208
    ),
    445
    448
    (
    2014
    ).
    3.
    R. J.
    Dwayne Miller
    , “
    Femtosecond crystallography with ultrabright electrons and x-rays: Capturing chemistry in action
    ,”
    Science
    343
    (
    6175
    ),
    1108
    1116
    (
    2014
    ).
    4.
    H.
    Schwoerer
    ,
    H. N.
    Chapman
    ,
    B. J.
    Siwick
    , and
    R. J.
    Dwayne Miller
    , “
    Special issue on imaging the dynamic structure of matter
    ,”
    J. Phys. B: At., Mol. Opt. Phys.
    49
    (
    15
    ),
    150201
    (
    2016
    ), and references therein.
    5.
    B. J.
    Siwick
    ,
    J. R.
    Dwyer
    ,
    R. E.
    Jordan
    , and
    R. J.
    Dwayne Miller
    , “
    Ultrafast electron optics: Propagation dynamics of femtosecond electron packets
    ,”
    J. Appl. Phys.
    92
    (
    3
    ),
    1643
    1648
    (
    2002
    ).
    6.
    T.
    van Oudheusden
    ,
    E. F.
    de Jong
    ,
    S. B.
    van der Geer
    ,
    W. P. E. M.
    Op't Root
    ,
    O. J.
    Luiten
    , and
    B. J.
    Siwick
    , “
    Electron source concept for single-shot sub-100 fs electron diffraction in the 100 keV range
    ,”
    J. Appl. Phys.
    102
    (
    9
    ),
    093501
    (
    2007
    ).
    7.
    R. P.
    Chatelain
    ,
    V. R.
    Morrison
    ,
    C.
    Godbout
    , and
    B. J.
    Siwick
    , “
    Ultrafast electron diffraction with radio-frequency compressed electron pulses
    ,”
    Appl. Phys. Lett.
    101
    (
    8
    ),
    081901
    (
    2012
    ).
    8.
    M.
    Gao
    ,
    H.
    Jean-Ruel
    ,
    R. R.
    Cooney
    ,
    J.
    Stampe
    ,
    M.
    de Jong
    ,
    M.
    Harb
    ,
    G.
    Sciaini
    ,
    G.
    Moriena
    , and
    R. J.
    Dwayne Miller
    , “
    Full characterization of rf compressed femtosecond electron pulses using ponderomotive scattering
    ,”
    Opt. Express
    20
    (
    11
    ),
    12048
    12058
    (
    2012
    ).
    9.
    T.
    van Oudheusden
    ,
    P. L. E. M.
    Pasmans
    ,
    S. B.
    van der Geer
    ,
    M. J.
    de Loos
    ,
    M. J.
    van der Wiel
    , and
    O. J.
    Luiten
    , “
    Compression of subrelativistic space-charge-dominated electron bunches for single-shot femtosecond electron diffraction
    ,”
    Phys. Rev. Lett.
    105
    ,
    264801
    (
    2010
    ).
    10.
    A.
    Gliserin
    ,
    A.
    Apolonski
    ,
    F.
    Krausz
    , and
    P.
    Baum
    , “
    Compression of single-electron pulses with a microwave cavity
    ,”
    New J. Phys.
    14
    (
    7
    ),
    073055
    (
    2012
    ).
    11.
    O.
    Zandi
    ,
    K. J.
    Wilkin
    ,
    Y.
    Xiong
    , and
    M.
    Centurion
    , “
    High current table-top setup for femtosecond gas electron diffraction
    ,”
    Struct. Dyn.
    4
    (
    4
    ),
    044022
    (
    2017
    ).
    12.
    C.
    Kealhofer
    ,
    W.
    Schneider
    ,
    D.
    Ehberger
    ,
    A.
    Ryabov
    ,
    F.
    Krausz
    , and
    P.
    Baum
    , “
    All-optical control and metrology of electron pulses
    ,”
    Science
    352
    (
    6284
    ),
    429
    433
    (
    2016
    ).
    13.
    M.
    Mankos
    ,
    K.
    Shadman
    , and
    B. J.
    Siwick
    , “
    A novel electron mirror pulse compressor
    ,”
    Ultramicroscopy
    (published online) .
    14.
    Y.
    Wang
    and
    N.
    Gedik
    , “
    Electron pulse compression with a practical reflectron design for ultrafast electron diffraction
    ,”
    IEEE J. Select. Top. Quantum Electron.
    18
    (
    1
    ),
    140
    147
    (
    2012
    ).
    https://doi.org/10.1109/JSTQE.2011.2112339
    15.
    G. H.
    Kassier
    ,
    K.
    Haupt
    ,
    N.
    Erasmus
    ,
    E. G.
    Rohwer
    , and
    H.
    Schwoerer
    , “
    Achromatic reflectron compressor design for bright pulses in femtosecond electron diffraction
    ,”
    J. Appl. Phys.
    105
    (
    11
    ),
    113111
    (
    2009
    ).
    16.
    J.
    Maxson
    ,
    D.
    Cesar
    ,
    G.
    Calmasini
    ,
    A.
    Ody
    ,
    P.
    Musumeci
    , and
    D.
    Alesini
    , “
    Direct measurement of sub-10 fs relativistic electron beams with ultralow emittance
    ,”
    Phys. Rev. Lett.
    118
    ,
    154802
    (
    2017
    ).
    17.
    F. B.
    Kiewiet
    ,
    A. H.
    Kemper
    ,
    O. J.
    Luiten
    ,
    G. J. H.
    Brussaard
    , and
    M. J.
    van der Wiel
    , “
    Femtosecond synchronization of a 3 GHz rf oscillator to a mode-locked Ti:Sapphire laser
    ,”
    Nucl. Instrum. Methods Phys. Res., Sect. A
    484
    (
    13
    ),
    619
    624
    (
    2002
    ).
    18.
    A.
    Gliserin
    ,
    M.
    Walbran
    , and
    P.
    Baum
    , “
    Passive optical enhancement of laser-microwave synchronization
    ,”
    Appl. Phys. Lett.
    103
    (
    3
    ),
    031113
    (
    2013
    ).
    19.
    E. N.
    Ivanov
    ,
    S. A.
    Diddams
    , and
    L.
    Hollberg
    , “
    Analysis of noise mechanisms limiting the frequency stability of microwave signals generated with a femtosecond laser
    ,”
    IEEE J. Sel. Top. Quantum Electron.
    9
    (
    4
    ),
    1059
    1065
    (
    2003
    ).
    20.
    J.
    Taylor
    ,
    S.
    Datta
    ,
    A.
    Hati
    ,
    C.
    Nelson
    ,
    F.
    Quinlan
    ,
    A.
    Joshi
    , and
    S.
    Diddams
    , “
    Characterization of power-to-phase conversion in high-speed p-i-n photodiodes
    ,”
    IEEE Photonics J.
    3
    (
    1
    ),
    140
    151
    (
    2011
    ).
    21.
    W.
    Zhang
    ,
    T.
    Li
    ,
    M.
    Lours
    ,
    S.
    Seidelin
    ,
    G.
    Santarelli
    , and
    Y.
    Le Coq
    , “
    Amplitude to phase conversion of InGaAs pin photo-diodes for femtosecond lasers microwave signal generation
    ,”
    Appl. Phys. B
    106
    (
    2
    ),
    301
    308
    (
    2012
    ).
    22.
    M.
    Walbran
    ,
    A.
    Gliserin
    ,
    K.
    Jung
    ,
    J.
    Kim
    , and
    P.
    Baum
    , “
    5-femtosecond laser-electron synchronization for pump-probe crystallography and diffraction
    ,”
    Phys. Rev. Appl.
    4
    ,
    044013
    (
    2015
    ).
    23.
    P. L. E. M.
    Pasmans
    ,
    G. B.
    van den Ham
    ,
    S. F. P.
    Dal Conte
    ,
    S. B.
    van der Geer
    , and
    O. J.
    Luiten
    , “
    Microwave TM010 cavities as versatile 4D electron optical elements
    ,”
    Ultramicroscopy
    127
    ,
    19
    24
    (
    2013
    ).
    24.
    G. H.
    Kassier
    ,
    K.
    Haupt
    ,
    N.
    Erasmus
    ,
    E. G.
    Rohwer
    ,
    H. M.
    von Bergmann
    ,
    H.
    Schwoerer
    ,
    S. M. M.
    Coelho
    , and
    F. D.
    Auret
    , “
    A compact streak camera for 150 fs time resolved measurement of bright pulses in ultrafast electron diffraction
    ,”
    Rev. Sci. Instrum.
    81
    (
    10
    ),
    105103
    (
    2010
    ).
    25.
    M.
    Gao
    ,
    Y.
    Jiang
    ,
    G. H.
    Kassier
    , and
    R. J.
    Dwayne Miller
    , “
    Single shot time stamping of ultrabright radio frequency compressed electron pulses
    ,”
    Appl. Phys. Lett.
    103
    (
    3
    ),
    033503
    (
    2013
    ).
    26.
    C. M.
    Scoby
    ,
    P.
    Musumeci
    ,
    J. T.
    Moody
    , and
    M. S.
    Gutierrez
    , “
    Electro-optic sampling at 90 degree interaction geometry for time-of-arrival stamping of ultrafast relativistic electron diffraction
    ,”
    Phys. Rev. ST Accel. Beams
    13
    ,
    022801
    (
    2010
    ).
    Kilohertz droplet-on-demand serial femtosecond crystallography at the European XFEL station FXE