The invention discloses design of the open-type dynamically harmonized trap directly incorporated into the body of vacuum chamber of Fourier transform ion cyclotron resonance mass analyzer. The proposed trap provides ultra-high resolution of the mass spectrometer as well as improves performance of the instrument, increases pumping rate (accelerates evacuation), eliminates necessity in vacuum feed-through, and increases maximum trap resolution limit at a fixed magnetic field.

The mass spectrometer includes an ionization unit, an ion transport unit, and a mass separation unit that separates transported ions according to a mass-to-charge ratio. The ion transport unit includes a transport electrode member, a voltage generator that applies a voltage to the transport electrode member, and a voltage controller that changes a voltage applied to the transport electrode member while ionization is performed. The voltage controller switches between a first voltage state in which charged particles generated in the ionization unit can enter the mass separation unit, and a second voltage state in which the charged particles cannot enter the mass separation unit, and switches a voltage state of the transport electrode member between the first voltage state and the second voltage state.

A miniature electrode apparatus is disclosed for trapping charged particles, the apparatus includes, along a longitudinal direction, a first end cap electrode, a central electrode having an aperture, and a second end cap electrode. The aperture is elongated in the lateral plane and extends through the central electrode along the longitudinal direction and the central electrode surrounds the aperture in a lateral plane perpendicular to the longitudinal direction to define a transverse cavity for trapping charged particles. Electric fields can be applied in a y-direction of the lateral plane across one or more planes perpendicular to the longitudinal axis to translocate and/or manipulate ion trajectories.

A mass spectrometer includes an ion source that generates ions, an ion trap that captures the ions generated from the ion source, a detector that detects the ions ejected from the ion trap and a controller that controls a periodic voltage, which is added to form a capturing electric field in the ion trap and controls a time point at which the ions are generated from the ion source. The controller includes an ion generation time controller that allows the ions to be generated from the ion source at N (N is an integer equal to or larger than 2) phase time points while addition of the periodic voltage is continued, the N phase time points being set in one period of the periodic voltage and being respectively assigned to different periods of the periodic voltage.

A method includes parallel or serial ionization of a gas mixture by activating at least two ionization devices operating using different ionization procedures, and/or by ionizing the gas mixture in a detector to which the gas mixture and ions and/or metastable particles of an ionization gas are fed. The method also includes detecting the ionized gas mixture in the detector for the mass spectrometric examination thereof. A mass spectrometer for mass spectrometric examination of gas mixtures includes an ionization unit for ionizing a gas mixture and a detector for detecting the ionized gas mixture.

A method of carrying out mass spectrometry, comprising: using an electrostatic or electrodynamic ion trap to contain a plurality of ions, each ion having a mass to charge ratio, the ions having a first plurality of mass to charge ratios, each ion following a path within the electrostatic or electrodynamic ion trap having a radius; and for each of a second plurality of the mass to charge ratios: modulating the radii of the ions in a mass to charge ratio-dependent fashion dependent upon the mass to charge ratio; fragmenting the ions thus modulated in a radius-dependent fashion; and determining a mass spectrum of the ions.

Various embodiments provide ion traps or systems comprising ion traps that comprise a trapping portion and a radio frequency (RF) border electrode bounding the trapping portion. The RF border electrode comprises or is in electrical communication with a plurality of feed ports. In an example embodiment, the ion trap comprises a plurality of unit cells each comprising a respective trapping portion, a respective RF border electrode bounding the respective trapping portion, and a respective feed port of the plurality of feed ports.

Certain aspects of the present disclosure are generally directed to monitoring different decoding candidates assuming different encoding schemes. For example, certain aspects of the present disclosure are directed to a method for wireless communication. The method generally includes determining a first encoding scheme used to encode first downlink control information (DCI) and a second encoding scheme used to encode second DCI, and monitoring one or more first decoding candidates for the first DCI based on the first encoding scheme and one or more second decoding candidate for the second DCI based on the second encoding scheme.

An ion trap includes: an ion trap including a plurality of electrodes; a rectangular voltage generator including a voltage source for generating a direct voltage and a switching section, the rectangular voltage generator configured to operate the switching section to generate a rectangular voltage by switching the direct voltage generated by the voltage source and to apply the rectangular voltage to at least one of the plurality of electrodes; and a switching section temperature controller configured to control a temperature of the switching section so as to maintain the temperature of the switching section at a target temperature which is higher than a highest reaching temperature of the switching section.

Mass spectrometry systems or assemblies therefore include an ionizer that includes at least one planar conductor, a mass analyzer with a planar electrode assembly, and a detector comprising at least one planar conductor. The ionizer, the mass analyzer and the detector are attached together in a compact stack assembly. The stack assembly has a perimeter that bounds an area that is between about 0.01 mm.sup.2 to about 25 cm.sup.2 and the stack assembly has a thickness that is between about 0.1 mm to about 25 mm.