Electron gun for diffraction experiments off controlled molecules

Abstract: A dc electron gun, generating picosecond pulses with up to 8 × 10 6 electrons per pulse, was developed. Its applicability for future time-resolved-diffraction experiments on state-and conformer-selected laser-aligned or oriented gaseous samples was characterized. The focusing electrodes were arranged in a velocity-map imaging spectrometer configuration. This allowed to directly measure the spatial and velocity distributions of the electron pulses emitted from the cathode. The coherence length and pulse duratio… Show more

“…To calibrate and optimize the spectrometer field configuration for both SMI and VMI, a fixed potential of -6 kV was applied to both the repeller plate and the sample holder while the ground plate was grounded. While scanning the extractor voltage from -5.8 kV to -4.3 kV, we observed the focusing of the electron bunch depending on the extractor voltage [285]. This behavior is explored based on the RMS of the electron bunch size in the x and y directions on the detector.…”

Terahertz Acceleration Technology Towards Compact Light Sources

“…To calibrate and optimize the spectrometer field configuration for both SMI and VMI, a fixed potential of -6 kV was applied to both the repeller plate and the sample holder while the ground plate was grounded. While scanning the extractor voltage from -5.8 kV to -4.3 kV, we observed the focusing of the electron bunch depending on the extractor voltage [285]. This behavior is explored based on the RMS of the electron bunch size in the x and y directions on the detector.…”

Terahertz Acceleration Technology Towards Compact Light Sources

“…The simulations of the diffraction pattern of 2,5diiodothiophene were carried out using the CMIdiffract code, which was developed within the CMI group to simulate the diffraction of x-rays or electrons of gas-phase molecules based on the independent atom model. 12,14,15,[28][29][30] The structure of 2,5-diiodothiophene, which was used to calculate the diffraction pattern, was calculated with GAMESS-US 31 at the MP2/6-311G** level of theory. Parameters such as molecular beam density, molecular beam width, and the degree of alignment were extracted from the experiment 22 and appropriately considered in the simulations, as were geometric con- strains such as the distance from the interaction zone to the CSPAD camera, the size of the detector, photon energy, and number of photons.…”

“…[6][7][8] Time resolved diffraction studies of small gas-phase molecules in the picosecond range were first employed by electron diffraction at the beginning of the 21st century 9,10 and have been used ever since with laboratory-based electron sources. 11,12 Recently, much higher time resolution of ∼100 fs was achieved by an accelerator-facility based relativistic electron gun. 13 The development of ultrashort and intense hard x-ray laser pulses generated by x-ray freeelectron lasers (XFELs) has also provided the possibility to image structure as well as structural changes of small gas-phase molecules via x-ray diffraction [14][15][16] on ultrafast (femtosecond) timescales.…”

X-ray diffractive imaging of controlled gas-phase molecules: Toward imaging of dynamics in the molecular frame

“…17 Additionally, the deflector enables the separation of polar molecules from the seed gas, which is relevant, for instance, for gas-phase diffraction experiments. [18][19][20][21] Alternatively, eigenstates of small polar neutral molecules can be separated using switched electric or magnetic fields. 12,[22][23][24][25][26][27][28] Large molecular ions were separated according to their shape using ion-mobility techniques.…”

Improved spatial separation of neutral molecules