School of Physics - Theses

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Author: MURPHY, DENE × End date: 2017 × Type: PhD thesis × Subject: electron beam physics × Subject: ion beam physics ×

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    Measurement and modelling of intrabeam coulomb interactions in ultracold ion bunches
    MURPHY, DENE ( 2017)
    Control of Coulomb-induced emittance growth in charged particle beams is of critical importance for applications including electron and ion microscopy, injectors for particle accelerators and in ultrafast electron diffraction, where Coulomb effects constrain the temporal and spatial imaging resolution. The development of techniques to prevent space-charge and disorder-induced emittance growth has been limited by the masking effect of thermal diffusion in conventional beams. In this thesis it is shown that ion bunches from a cold-atom electron and ion source can be used to observe the effects of intrabeam Coulomb interactions with unprecedented detail. Experiments are performed using nanosecond-duration cold ion bunches, which provide data for analogous ultrafast electron systems where the dynamics occur on timescales too short for detailed observation. Cold ion bunches were produced by photoionising a laser-cooled gas. The intensity profile of the photoionising lasers was controlled using a spatial light modulator, which allowed for shaping of the spatial charge density distribution of the ion bunches. Nonlinear space-charge expansion dynamics were observed in the propagation of the ion bunches. Certain aspects of the observed dynamics were inconsistent with initial modelling attempts. In particular, high-density rings were formed in the transverse density distribution, which were not predicted in particle tracking simulations for the calculated initial ion distributions. Through detailed modelling, it was determined that the rings form in the interaction of the expanding ion beam with a diffuse ‘fluorescence halo’ of ions. The fluorescence halos were formed by reabsorption of fluoresced light from the sequential photoexcitation and ionisation process. Modelling of the photoexcitation process and particle-tracking simulations reproduced the experimentally observed beam dynamics, confirming the hypothesis of halo formation. The nonlinear transformation of the beam density profile leading to the formation of the fluorescence halo rings is indicative of loss of beam coherence. The fluorescence halo rings were suppressed by controlling the duration of laser overlap during photoionisation, where a shorter overlap reduces the time available for absorption of fluorescence. Fluorescence halo rings are an issue specific to atomic-gas based sources, but serve as an example of a nonlinear space-charge effect that is observable only because of the non-diffusive cold propagation of the ions. Efforts towards reconstruction of the beam dynamics leading to the ring formation were used to show that the cold ion bunches can be used as a platform to observe space-charge dominated beam dynamics in analogue of high-brightness and ultrafast electron beams. The cold ion beams were then used as a platform to investigate methods to overcome space-charge-induced beam-quality limitations. Modelling and experimental efforts were contributed to proof-of-principle experiments that demonstrated linearisation of the space-charge effects through beam-shaping. The ion bunches were shaped to uniform transverse distributions to linearise the internal electric field, suppressing the nonlinear space-charge effect. Improvements to the focusing properties of the shaped ion beams were measured, as compared to unshaped bunches, directly demonstrating improvement of beam quality through beam shaping for the first time in any charged particle beam. Beyond the linearisable space-charge effects are statistical disorder-induced heating (DIH) effects, which set lower-bound achievability limits on particle beam temperature. Models of the DIH process were used to predict the degree to which DIH can be suppressed in cold ion bunches by introducing interparticle spatial correlations in the cold atoms prior to ionisation. Two different methods of introducing correlations were modelled: first, by exploiting the Rydberg blockade effect in the photoexcitation process to excite and ionise atoms with hard-sphere type spatial correlations limited by close-packing effects; and second, by loading the atoms into optical lattices, which have crystalline structural correlations, limited by partial-filling effects. The models predicted that the heating can be significantly suppressed in the cold ion bunches for experimentally achievable degrees of spatial correlation using either of the two correlation methods. Excitation of Rydberg atoms was implemented in the cold-atom ion source, towards achieving the improvement of beam quality predicted by the DIH modelling. Spectroscopy based on electromagnetically-induced transparency was used to tune photoionising lasers to resonance with Rydberg states. A method was presented for suppressing the formation of fluorescence halos during Rydberg excitation, by using intermediate-state-decoupled stimulated Raman adiabatic passage to excite Rydberg atoms while bypassing population of the fluorescent intermediate state in sequential (ladder) photoexcitation. Measurements of the blockaded photoexcitation dynamics of the Rydberg ion bunches established the presence of spatial correlations, to a degree consistent with a sevenfold increase in beam brightness compared to a disordered distribution, according to the DIH models. The models, simulations, methods and measurements presented in this thesis guide the development of charged particle beams towards attaining the necessary coherence, focusability, and brightness to perform single-shot ultrafast electron diffraction of biological molecules. In a surprising twist, slow atoms may underpin progress in high energy and ultrafast physics.