Abstract: The invention provides signal processing method and system and an electronic apparatus for analysis of time-of-flight mass spectra. The method includes digitalizing an analog signal output from an ion detector to acquire complete raw time-of-flight spectra or each effective part in the raw time-of-flight spectra for a plurality of times; if the complete raw time-of-flight spectra are acquired, extracting the effective parts of each raw time-of-flight spectrum; applying a one-dimensional wavelet transform to each effective part to map to each frequency band or scale; determining positions and intensities of each spectral peak in each raw time-of-flight spectrum by detecting the maxima of an obtained wavelet coefficient distribution, and saving said peak position and intensity as characteristic data of each spectral peak; accumulating the characteristic data obtained by processing each raw time-of-flight spectrum and stacking the data to form spectral peak intensity/time-of-flight histogram.

Abstract: The invention provides an ion mobility analyzer apparatus and analysis method. The analyzer apparatus includes an ion source, two groups of parallel electrodes, a power supply unit and a detector. The drift region is formed between the two groups of parallel electrodes, and has an ion entrance connected to the ion source and an ion exit. Each group of parallel electrodes is located in a plane respectively, and the two planes are parallel to each other. The power supply unit is configured to apply direct current potentials on the two groups of parallel electrodes to form a direct current electric field that applies an opposing force on ions against the gas flow so that ions with different mobilities are trapped under the combined effect of the gas flow and the direct current electric field. The detector is connected to the ion exit to detect ions.

Abstract: The invention provides ion mobility analyzer and analysis method. The analyzer includes an ion source, a first drift/analyzer region provided with an ions entrance, a second drift/analyzer region provided with an ions exit, a connection region connecting the first drift/analyzer region and the second drift/analyzer region, and a detector connected to the ion exit. Direct current electric fields and gas flows in the first drift/analyzer region and the second drift/analyzer region apply opposing forces on ions, and first and second gas flows have the same gas flow direction. The connection region includes a third direct current electric field that causes ions to transfer from the first drift/analyzer region to the second drift/analyzer region. Because the first and second regions have the same gas flow direction, the invention achieves stable resolution and sensitivity as a high-resolution ion mobility analyzer and/or an ion mobility filter for a continuous ion beam.

Abstract: An ion optical device includes one or more pairs of confinement electrode units arranged at two sides of a first direction; a power supply device for applying opposite radio-frequency voltages to the paired confinement electrode units respectively and forming thereon DC potentials distributed in a second direction orthogonal to the first direction to form a potential barrier herein over a length portion of the first direction; one first area and one second area positioned at two sides of the potential barrier in the second direction; and a control device connected with the power supply device for controlling an output to change the potential barrier to manipulate the ions transported/stored in the first area being transferred to the second area through the potential barrier in ways based on the mass to charge ratio or mobility of the ions and continue being transported along the first direction.

Abstract: The invention provides a mass spectrometer, an ion optical device, and a method for ion manipulation in a mass spectrometer. The mass spectrometer includes a mass analyzer; and an ion guiding device, including two electrode arrays positioned in parallel with each other, each electrode array including at least two ring electrodes concentrically disposed or at least three linear electrode assemblies having a radial distribution; and a power supply means, configured to apply a voltage on at least a part of the ring electrodes, to form a radio-frequency electric field and a DC electric field. By means of the radio-frequency electric field and the DC electric field, ions are allowed to be stored in a region between the two arrays, and controlled to be sequentially released along a radial direction according to a preset mass-to-charge ratio requirement, then exit the ion guiding device and enter the mass analyzer for mass analysis.

Abstract: An ion mobility spectrometry apparatus and method are provided. The ion mobility spectrometry apparatus includes an ion source for providing ions; an ion guiding device having: at least three ends internally communicated: first, second and third guiding ends, wherein ions can enter or exit from the ion guiding device from any ends thereof, the first guiding end is used for entrance of ions provided by the ion source, and the third guiding end is communicated with a downstream device; at least one drift cell in correspondence to the second guiding end, for transmitting ions and/or performing ion mobility analysis, each drift cell having a first and second ends which are internally communicated, wherein the second end of drift cell is communicated with said second guiding end; an ion storage device communicated with said first end of the drift cell, for storing ions or ejecting ions.

Abstract: The disclosure relates to a mass spectrometer and a method applied thereby for reducing ion loss and succeeding stage vacuum load. The mass spectrometer includes an ion source connected via vacuum interfaces, a vacuum chamber and a succeeding stage device; wherein a tubular lens is arranged above a Mach disc formed by a gas flow carrying ions at the vacuum interfaces, so that an ion transfer path is restrained and the ions scattering with the gas flow is reduced. In comparison to a sole reliance on a radio-frequency voltage for focusing ions, the efficiency of ion capture in a jet region is improved by using an aerodynamic lens; and the desolvation efficiency of electrically charged droplets is also improved, thereby further improving the sensitivity of the mass spectrometer. Meanwhile the tubular aerodynamic lens is simple in structure and small in size.

Abstract: A mass spectrometer includes an ion source configured to generate reagent ions; a drift tube configured to cause sample molecules to react with the reagent ions to generate sample ions, the drift tube comprising two sets of electrodes which are identical in structure and symmetrically distributed in a direction perpendicular to a direction of ion drift, each set of electrodes comprising a plurality of curved cell electrodes which are distributed in a same plane and arranged in the direction of ion drift so that the sample ions are generated and drifted within a region between the two sets of electrodes and focused in the direction perpendicular to the direction of ion drift; a power supply device configured to apply, to each of the cell electrodes, a DC voltage changing in the direction of ion drift; and, a mass analyzer configured to perform mass analysis for the sample ions.

Abstract: A focusing ion guiding apparatus includes: at least one ion guiding inlet and ion guiding outlet connected to each other via a transport axial line; at least one group of focusing electrode structures comprising at least one smooth and non-concave focusing electrode or focusing electrode array to which a focusing voltage is applied, the focusing electrode structure causing the ions transported in the apparatus to be radially focused for many times under the action of a focusing electric field formed by the focusing electrode structure; and a neutral gas flow transported in the axial direction, a diffusion path of the gas flow in an at least partially radial direction relative to the axial direction being blocked by the focusing electrode or its bearing substrate to increase a transport velocity of the gas flow in the axial direction and reduce retention or turbulence of the transported ions.

Abstract: A method for parallel analysis in mass spectrometry and ion mobility spectrometry includes enabling a sample to be subjected to a chromatography separation; ionizing the chromatography separated sample and then feeding the sample into a succeeding stage device for analysis, comprising: analyzing at least part of the ionized sample through an ion mobility spectrometer to obtain an ion mobility spectrum, and analyzing at least other parts of the sample through a mass spectrometer to obtain a mass spectrum, wherein the period for obtaining each ion mobility spectrum and each mass spectrum being not longer than 5 s; and performing data post-processing, comprising: correlating the peaks in said ion mobility spectrum and the peaks in said mass spectrum with a deconvolution algorithm according to the consistency in retention time or elution profile for the same analyte in said chromatography.

Abstract: An ion guiding device (3) and method, the ion guiding device (3) having: a group of electrode arrays distributed along an axis in space, and a power supply providing an asymmetric alternating current (AC) electric field substantially along the axis; the AC field asymmetrically alternates between positive and negative along the axis to drive the ions move in the direction corresponding to said AC electric field such that ions are guided into said ion guiding device (3) in a continuous or quasi-continuous flow manner while being guided out in a pulsed manner along the axis.

Abstract: An ion optical apparatus and a mass spectrometer are provided. The ion optical apparatus includes at least one planar insulating substrate which is covered with metal patterns to form an electrode array including a plurality of cell electrodes, wherein each of the cell electrodes is arrayed according to a first direction to form a geometric pattern distribution of the electrode array, wherein cell electrodes are applied with radio frequency (RF) voltages having different phases to confine ions, a direct current (DC) voltage gradient is applied along at least part of the cell electrodes in the electrode array to drive ions to move in the first direction along the electrode array, and a corresponding electric field distribution is formed by the geometric pattern distribution to drive ions to move in a second direction substantially orthogonal to the first direction, thereby realizing ion deflection, focusing or defocusing.

Abstract: The disclosure relates to an ion guiding device, including which comprises two sets of electrodes extending along a certain space axis, a first power supply device and a second power supply device. The electrodes are expandably arranged along a direction perpendicular to the space axis, at least one surface of each electrode in each set of electrodes is substantially on the same space plane, and the space planes for each set of electrodes are not same and not parallel, thereby forming an ion transmission channel having the cross sectional area gradually reduced in a direction perpendicular to the space axis; the first power supply device is used for applying radio-frequency voltages on at least a part of electrodes in the two sets of electrodes; and the second power supply device is used for applying voltage signals on at least a part of electrodes in the two sets of electrodes.

Abstract: The disclosure relates to a mass spectrometer and a method applied thereby for reducing ion loss and succeeding stage vacuum load. The mass spectrometer includes an ion source connected via vacuum interfaces, a vacuum chamber and a succeeding stage device; wherein a tubular lens is arranged above a Mach disc formed by a gas flow carrying ions at the vacuum interfaces, so that an ion transfer path is restrained and the ions scattering with the gas flow is reduced. In comparison to a sole reliance on a radio-frequency voltage for focusing ions, the efficiency of ion capture in a jet region is improved by using an aerodynamic lens; and the desolvation efficiency of electrically charged droplets is also improved, thereby further improving the sensitivity of the mass spectrometer. Meanwhile, the tubular aerodynamic lens is simple in structure and small in size.

Abstract: The disclosure relates to an ionization and ion introduction device for a mass spectrometer. The device includes an ionization source chamber at a pressure below atmospheric pressure; at least one ionization source, which is arranged in the ionization source chamber; at least one ion focusing guide chamber, which is arranged to guide ions into a mass analysis device chamber connected therewith; at least one transfer chamber at pressure below atmospheric pressure, which is located between the ionization source chamber and the ion focusing guide chamber, comprising an inlet interconnected to the ionization source chamber and an outlet interconnected to the ion focusing guide chamber, wherein the air pressure of the transfer chamber is lower than that of the ionization source chamber but higher than that of the ion focusing guide chamber.

Abstract: A method for parallel analysis in mass spectrometry and ion mobility spectrometry includes enabling a sample to be subjected to a chromatography separation; ionizing the chromatography separated sample and then feeding the sample into a succeeding stage device for analysis, comprising: analyzing at least part of the ionized sample through an ion mobility spectrometer to obtain an ion mobility spectrum, and analyzing at least other parts of the sample through a mass spectrometer to obtain a mass spectrum, wherein the period for obtaining each ion mobility spectrum and each mass spectrum being not longer than 5 s; and performing data post-processing, comprising: correlating the peaks in said ion mobility spectrum and the peaks in said mass spectrum with a deconvolution algorithm according to the consistency in retention time or elution profile for the same analyte in said chromatography.

Abstract: A focusing ion guiding apparatus includes at least one ion guiding inlet and ion guiding outlet connected to each other via a transport axial line; at least one group of focusing electrode structures comprising at least one smooth and non-concave focusing electrode or focusing electrode array to which a focusing voltage is applied, the focusing electrode structure causing the ions transported in the apparatus to be radially focused for many times under the action of a focusing electric field formed by the focusing electrode structure; and a neutral gas flow transported in the axial direction, a diffusion path of the gas flow in an at least partially radial direction relative to the axial direction being blocked by the focusing electrode or its bearing substrate to increase a transport velocity of the gas flow in the axial direction and reduce retention or turbulence of the transported ions.

Abstract: An ion optical apparatus and a mass spectrometer are provided. The ion optical apparatus includes at least one planar insulating substrate which is covered with metal patterns to form an electrode array including a plurality of cell electrodes, wherein each of the cell electrodes is arrayed according to a first direction to form a geometric pattern distribution of the electrode array, wherein cell electrodes are applied with radio frequency (RF) voltages having different phases to confine ions, a direct current (DC) voltage gradient is applied along at least part of the cell electrodes in the electrode array to drive ions to move in the first direction along the electrode array, and a corresponding electric field distribution is formed by the geometric pattern distribution to drive ions to move in a second direction substantially orthogonal to the first direction, thereby realizing ion deflection, focusing or defocusing.

Abstract: The present invention relates to an ion guide device and an ion guiding method. The ion guide device comprises: a plurality of electrode sets distributed along a central axis longitudinally, wherein each electrode set has a ring shape and consists of at least 2 segmented electrodes (for example, 1, 2 and 3, 4 for 2 sets respectively); the power supply system which provides radio-frequency with different phases applied to the adjacent electrode sets (for example, between 1,3 and 2,4) along the central axis, and provides DC Voltages on each segmented electrode (1,2,3,4), wherein, distribution of DC potential drives ions to move in the radial direction while driving said ions to move along the central axis. The ion guide can be used to guide and focus ions under relatively high gas pressure; especially it can be used for off-axis transmission of ions with the purpose to reduce the neutral noise.

Abstract: The invention relates to an ion generation device and an ion generation method, and more particularly to a device and a method which generates ions at the low pressure and then said ions can be transferred into the next stage in an off-axis manner. In the invention, ions from electrospray or other types of ion source are generated in the pressure which is lower than atmosphere pressure. A followed ion guide device can then transfer most of said generated ions into next stage in an off-axis manner, while most of neutral noise can be eliminated in this process.