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10.1063/1.4947098 http://scihub22266oqcxt.onion/10.1063/1.4947098 C4841798!4841798!27158637     free     free     free Deprecated: Implicit conversion from float 211.6 to int loses precision in C:\Inetpub\vhosts\kidney.de\httpdocs\pget.php on line 534 Deprecated: Implicit conversion from float 211.6 to int loses precision in C:\Inetpub\vhosts\kidney.de\httpdocs\pget.php on line 534 Deprecated: Implicit conversion from float 211.6 to int loses precision in C:\Inetpub\vhosts\kidney.de\httpdocs\pget.php on line 534 Deprecated: Implicit conversion from float 211.6 to int loses precision in C:\Inetpub\vhosts\kidney.de\httpdocs\pget.php on line 534 Deprecated: Implicit conversion from float 211.6 to int loses precision in C:\Inetpub\vhosts\kidney.de\httpdocs\pget.php on line 534       Struct+Dyn 2016 ; 3 (2): ä Nephropedia Template TP {{tp|p=27158637|t=2016. Femtosecond few- to single-electron point-projection microscopy for nanoscale dynamic imaging |pdf=|usr=}}{{27158637}} gab.com Text Femtosecond few- to single-electron point-projection microscopy for nanoscale dynamic imaging JO: Struct Dyn http://www.kidney.de/pget.php?&tw=1&pmid=27158637 #FOAvip Femtosecond electron microscopy produces real-space images of matter in a series of ultrafast snapshots. Pulses of electrons self-disperse under space-charge broadening, so without compression, the ideal operation mode is a single electron per pulse. Here, we demonstrate femtosecond single-electron point projection microscopy (fs-ePPM) in a laser-pump fs-e-probe configuration. The electrons have an energy of only 150?eV and take tens of picoseconds to propagate to the object under study. Nonetheless, we achieve a temporal resolution with a standard deviation of 114?fs (equivalent to a full-width at half-maximum of 269?±?40?fs) combined with a spatial resolution of 100?nm, applied to a localized region of charge at the apex of a nanoscale metal tip induced by 30?fs 800?nm laser pulses at 50?kHz. These observations demonstrate real-space imaging of reversible processes, such as tracking charge distributions, is feasible whilst maintaining femtosecond resolution. Our findings could find application as a characterization method, which, depending on geometry, could resolve tens of femtoseconds and tens of nanometres. Dynamically imaging electric and magnetic fields and charge distributions on sub-micron length scales opens new avenues of ultrafast dynamics. Furthermore, through the use of active compression, such pulses are an ideal seed for few-femtosecond to attosecond imaging applications which will access sub-optical cycle processes in nanoplasmonics. Twit Text FOAVip Femtosecond few- to single-electron point-projection microscopy for nanoscale dynamic imaging ????Struct Dyn http://www.kidney.de/pget.php?&tw=1&pmid=27158637 #FOAvip Twit Text # Free Paper on # # # # # LINK http://www.kidney.de/pget.php?&tw=1&pmid=27158637 #FOAvip English Wikipedia <ref>{{Cite pmid|27158637}}</ref> Femtosecond few- to single-electron point-projection microscopy for nanoscale dynamic imaging #MMPMID27158637 Bainbridge AR; Barlow Myers CW; Bryan WA Struct Dyn 2016[Mar]; 3 (2): ä PMID27158637show ga Femtosecond electron microscopy produces real-space images of matter in a series of ultrafast snapshots. Pulses of electrons self-disperse under space-charge broadening, so without compression, the ideal operation mode is a single electron per pulse. Here, we demonstrate femtosecond single-electron point projection microscopy (fs-ePPM) in a laser-pump fs-e-probe configuration. The electrons have an energy of only 150?eV and take tens of picoseconds to propagate to the object under study. Nonetheless, we achieve a temporal resolution with a standard deviation of 114?fs (equivalent to a full-width at half-maximum of 269?±?40?fs) combined with a spatial resolution of 100?nm, applied to a localized region of charge at the apex of a nanoscale metal tip induced by 30?fs 800?nm laser pulses at 50?kHz. These observations demonstrate real-space imaging of reversible processes, such as tracking charge distributions, is feasible whilst maintaining femtosecond resolution. Our findings could find application as a characterization method, which, depending on geometry, could resolve tens of femtoseconds and tens of nanometres. Dynamically imaging electric and magnetic fields and charge distributions on sub-micron length scales opens new avenues of ultrafast dynamics. Furthermore, through the use of active compression, such pulses are an ideal seed for few-femtosecond to attosecond imaging applications which will access sub-optical cycle processes in nanoplasmonics. äFemtosecond few- to single-electron point-projection microscopy for na(epmc).pdf DeepDyve Pubget Overpricing