An electron microscope includes: a laser light source configured to generate a CW laser; an irradiation lens system configured to irradiate a measurement sample with the CW laser; an energy analyzer configured to disperse, depending on energy, photoelectrons emitted from the measurement sample by irradiation with the CW laser; an energy slit configured to allow a photoelectron with a specified energy to pass, among the photoelectrons; an electron beam detector configured to detect the photoelectron passed through the energy slit; a first electron lens system configured to focus the photoelectrons emitted from the measurement sample onto the energy analyzer; and a second electron lens system configured to project the photoelectron passed through the energy slit onto the electron beam detector.

A method for measuring the chirality of molecules in a sample of chiral molecules, the sample including at least one chemical species, the method including the steps of: introducing the sample of chiral molecules into an ionisation area; ionising the molecules by electromagnetic radiation in the ionisation area; and detecting a distribution of electrons produced by ionisation and emitted at the front and back of the ionisation area relative to the axis, z, of propagation of the electromagnetic radiation; wherein the electromagnetic radiation is elliptically polarised, the ellipticity varying continuously and periodically as a function of time, the method further including a step of: determining the chirality of the molecules from the electron distribution detected continuously as a function of time. A system is also provided for measuring the chirality of molecules using such a method.

Provided is a compact two-dimensional electron spectrometer that is capable of variably adjusting the deceleration ratio over a wide range, and performing simultaneous measurement of the two-dimensional emission angle distribution with a high energy resolution over a wide solid angle of acquisition. The two-dimensional electron spectrometer is configured from: a variable deceleration ratio spherical aberration correction electrostatic lens; a cylindrical mirror type energy analyzer or a wide angle energy analyzer; and a projection lens. The variable deceleration ratio spherical aberration correction electrostatic lens is configured from: an electrostatic lens that consists of an axially symmetric spherical mesh having a concave shape with respect to a point source, and one or a plurality of axially symmetrical electrodes, and that adjusts the spherical aberration of charged particles generated from the point source; and an axially symmetric deceleration field generating electrode that is placed coaxially with the electrostatic lens.

A time-resolved photoemission electron microscopy including: a laser light source that outputs a pulse having less than or equal to a femtosecond level pulse width and variable repetition frequency; a pump light pulse generator configured to generate pump light pulse that excites photo-carriers of a sample by converting wavelength of light output from the laser light source; and a probe light pulse generator configured to generate probe light pulse that photo-emits photo-carriers excited by the pump light pulse from the sample by photoelectric effect by converting wavelength of light output from the laser light source. The energy of at least one of the pump light pulse and the probe light pulse is configured to continuously vary in a range not less than 0.1 eV and not more than 8 eV.

A time-resolved photoemission electron microscopy including: a laser light source that outputs a pulse having less than or equal to a femtosecond level pulse width and variable repetition frequency; a pump light pulse generator configured to generate pump light pulse that excites photo-carriers of a sample by converting wavelength of light output from the laser light source; and a probe light pulse generator configured to generate probe light pulse that photo-emits photo-carriers excited by the pump light pulse from the sample by photoelectric effect by converting wavelength of light output from the laser light source. The energy of at least one of the pump light pulse and the probe light pulse is configured to continuously vary in a range not less than 0.1 eV and not more than 8 eV.

An electron microscope includes: a laser light source configured to generate a CW laser; an irradiation lens system configured to irradiate a measurement sample with the CW laser; an energy analyzer configured to disperse, depending on energy, photoelectrons emitted from the measurement sample by irradiation with the CW laser; an energy slit configured to allow a photoelectron with a specified energy to pass, among the photoelectrons; an electron beam detector configured to detect the photoelectron passed through the energy slit; a first electron lens system configured to focus the photoelectrons emitted from the measurement sample onto the energy analyzer; and a second electron lens system configured to project the photoelectron passed through the energy slit onto the electron beam detector.

An electron microscope includes: a laser light source configured to generate a CW laser; an irradiation lens system configured to irradiate a measurement sample with the CW laser; an energy analyzer configured to disperse, depending on energy, photoelectrons emitted from the measurement sample by irradiation with the CW laser; an energy slit configured to allow a photoelectron with a specified energy to pass, among the photoelectrons; an electron beam detector configured to detect the photoelectron passed through the energy slit; a first electron lens system configured to focus the photoelectrons emitted from the measurement sample onto the energy analyzer; and a second electron lens system configured to project the photoelectron passed through the energy slit onto the electron beam detector.

An analysis method includes: obtaining nm pieces of map data by repeating, m times, a map measurement in which n pieces of map data are obtained by scanning a specimen with a primary probe to detect electrons emitted from the specimen with an electron spectrometer, while measurement energy ranges of an analyzer are varied; and generating a spectral map in which a position on the specimen is associated with a spectrum based on the nm pieces of map data, the measurement energy ranges of m times of the map measurement not overlapping each other.

An input lens is provided which has a large acceptance solid angle for electrons. The input lens is for use in an electron spectrometer and disposed between an electron source producing electrons and an electron analyzer in the electron spectrometer. The input lens has a reference electrode at a reference potential, a slit, first through nth electrodes, where n is an integer equal to or greater than three, arranged between the reference electrode and the slit, and a second mesh attached to the first electrode. The first through nth electrodes are arranged in this order along an optical axis. The second mesh is at a potential higher than the reference potential.

A system and method for redistributing photoexcited electrons and generate local currents within an optical spot on ultrafast timescales achieving in high-speed, high-resolution control of opto-electronic phenomena is disclosed. Selectively addressing sub-populations of photoexcited electrons within the distribution is necessary. By exploiting the spatial intensity variations in an ultrafast light pulse, local surface fields are generated within the photoexcitation spot of a doped semiconductor, which pull apart the photoexcited electrons into two separate distributions. This redistribution process can be controlled via the spatial profile and intensity of the photoexciting pulse.