{"id":2520,"date":"2013-06-29T15:38:50","date_gmt":"2013-06-29T15:38:50","guid":{"rendered":"https:\/\/mtlsites.mit.edu\/annual_reports\/2013\/?p=2520"},"modified":"2013-08-29T18:03:46","modified_gmt":"2013-08-29T18:03:46","slug":"next-generation-ultrafast-photo-triggered-cathodes","status":"publish","type":"post","link":"https:\/\/mtlsites.mit.edu\/annual_reports\/2013\/next-generation-ultrafast-photo-triggered-cathodes\/","title":{"rendered":"Next-Generation Ultrafast Photo-Triggered Cathodes"},"content":{"rendered":"

State-of-the-art ultrafast cathodes are based on the photoelectric effect, where electrons are emitted from a flat surface using ultraviolet (UV) pulses; however, these cathodes have a number of shortcomings including difficult manufacture, need for ultra-high vacuum to operate, and short lifetime[1<\/a>]<\/sup>.\u00a0 Photon-triggered field emission cathodes are an attractive alternative to circumvent these issues.\u00a0 Strong-field electron tunneling from solids without damage occurs when the electric field of high-intensity optical pulses interacts with field enhancing structures to lower the incident flux necessary for barrier suppression. In this project we are using wafer-level semiconductor batch fabrication techniques to create massively multiplexed arrays of nano-sharp high-aspect-ratio silicon pillars with high uniformity (4.6-million tips.cm-2<\/sup>), resulting in greatly enhanced array electron emission.\u00a0 A high-aspect-ratio silicon column topped by a nano-sharp tip achieves electron emission at low power by greatly enhancing the incident electric field, and the massive multiplexing of the pillars drastically increases the total current emission. We developed a fabrication process that attains small tip variation across the array due to the diffusion-limited oxidation step that sharpens the tips, resulting in large array utilization. \u00a0As shown in Fig. 1, the high field of the ultra-short laser pulses combined with the field enhancement of the nano-sharp high-aspect-ratio silicon tip array resulted in large current emission using small laser energies. Between 25 nJ and 0.1 \u00b5J laser pulse energy, the data follow a multi-photon absorption process; the high power dependence of the emitted current on the laser pulse energy comes from the electrons oscillating back into the tip.\u00a0 For larger laser pulse energies the curve bends over, evidencing operation of the cathode in the tunneling regime[2<\/a>]<\/sup>; this transition occurs because the electric field becomes so strong that the electrons tunnel faster than they can oscillate back into the tips. We have also demonstrated long-term operation without degradation for 3.6 nA average current from an array of about 2,220 tips[3<\/a>]<\/sup>.<\/p>\n\n\t\t