Abstract: The present invention relates to the field of mass and/or ion mobility spectrometers. Provided is an ionization device and a mass spectrometer and an ion mobility spectrometer having same. Further provided is an ionization method. A sampling probe of the ionization device of the present invention is able to actively and rapidly collect samples, while a sampling device and a thermal desorption device are combined into one, simplifying and compacting the sampling device. An ionization part is provided downstream of the sampling and desorption part, ensuring that the sampling probe will not interfere with a flow field or an electric field between the ionization part and the analysis assembly inlet, thus ensuring repeatability of the device signal and flexibility of analysis.

Abstract: Devices and methods of generating resonance excitation for an ion manipulation apparatus are provided. The ion manipulation apparatus can be operated as an ion filtration apparatus used with particle mass spectrometry system. The devices and methods can be capable of generating a resonance excitation to effect an ion filtration in a multipole apparatus. The resonance excitation is generated by mixing a radio frequency signal with a plurality of alternative current voltage signals having different frequencies. The resonance excitation can be added to at least one electrode of the multipole apparatus. The generation of mixed alternative current voltage signal is performed in a time domain, therefore no time-consuming inverse Fourier transform procedure is needed, which significantly improves an analysis speed and a throughput of the particle mass spectrometry system.

Abstract: Systems and methods are provided for the analysis of single particles with inductively coupled plasma-time of flight mass spectrometry. An ion compression device is operated in combination with an image current detector to improve a duty cycle of particle analysis. The image current detection device is used to determine a start time and an end time of a separate ion cloud which is derived from a single particle. The ion compression device stores and compresses each ion cloud based on instructions from the image current detector. The duty cycle of the particle analysis can be improved up to nearly 100%. The ion compression device is additionally operated with an ion filtration device to achieve a lower detection limit and a higher signal-to-noise ratio.

Abstract: Systems and methods are provided for the analysis of single particles with inductively coupled plasma time of flight mass spectrometry. Single particles may be isolated from whole cells, microorganisms, viruses, etc. The systems may include curved ion guides including such elements as multipoles, angled or rounded surfaces, and an ion manipulation device including elements such as an ion tunnel, ion funnel, quadrupole, and variations of each element.

Abstract: Systems and methods are provided for high-efficiency transport of single particles for inductively coupled plasma mass spectrometry. Single particles may be delivered to the mass spectrometer for quantification of trace elements. The systems may include droplet generation, conveyance module, capillary tubing, and/or an integrated inductively coupled plasma (ICP) torch, which may allow for the sequential transportation of single particles.

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 ion guiding device comprises a first electrode assembly comprising two parallel electrode units arranged along a spatial axis; a second electrode assembly comprising at least two non-parallel electrode units arranged in a plane between the parallel electrode units along the spatial axis, wherein a space enclosed by the first electrode assembly and second electrode assembly forms an ion transmission channel along the spatial axis; and, a power supply device, which is configured to apply RF voltages with different polarities to the first electrode assembly and the second electrode assembly to generate a RF electric field in the directions perpendicular to the spatial axis to confine ions, and separately apply DC voltages to the first electrode assembly and the second electrode assembly to generate a certain DC voltage difference, to generate a DC electric field along the spatial axis to control the movement of ions.

Abstract: The present invention relates to the field of mass and/or ion mobility spectrometers. Provided is an ionization device and a mass spectrometer and an ion mobility spectrometer having same. Further provided is an ionization method. A sampling probe of the ionization device of the present invention is able to actively and rapidly collect samples, while a sampling device and a thermal desorption device are combined into one, simplifying and compacting the sampling device. An ionization part is provided downstream of the sampling and desorption part, ensuring that the sampling probe will not interfere with a flow field or an electric field between the ionization part and the analysis assembly inlet, thus ensuring repeatability of the device signal and flexibility of analysis.

Abstract: The ion guiding device comprises a first electrode assembly comprising two parallel electrode units arranged along a spatial axis; a second electrode assembly comprising at least two non-parallel electrode units arranged in a plane between the parallel electrode units along the spatial axis, wherein a space enclosed by the first electrode assembly and second electrode assembly forms an ion transmission channel along the spatial axis; and, a power supply device, which is configured to apply RF voltages with different polarities to the first electrode assembly and the second electrode assembly to generate a RF electric field in the directions perpendicular to the spatial axis to confine ions, and separately apply DC voltages to the first electrode assembly and the second electrode assembly to generate a certain DC voltage difference, to generate a DC electric field along the spatial axis to control the movement of ions.

Abstract: The present invention discloses an ion guide device and associated method as well as a mass spectrometer. A pair of parallel electrode assemblies, among the electrode assemblies surrounding a spatial axis to form an ion transmission channel, is segmented along a certain direction, so that a DC voltage can be separately applied to the segmented electrodes to form a DC potential gradient. In this way, not only one axial electric field component along the said spatial axis but also the other component in the direction perpendicular to the said spatial axis can be provided to control the motion of ions in the ion transmission channel. As a result, the previous problems of low analysis speed, limited ion incident energy, difficulty to balance the device structure simplification and the performance optimization and the like are solved.

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 thereof 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 disclosure relates to an ion guiding device, including 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 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: 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 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: An ion mobility analyzer, combination device thereof, and ion mobility analysis method. The ion mobility analyzer comprises an electrode system that surrounds the analytical space and a power device that attaches to the electrode system an ion mobility electric potential field that moves along one space axis. During the process of analyzing mobility of ions to be measured, by always placing the ions to be measured in the moving ion mobility electric potential field, and keeping the movement direction of the ion mobility electric potential field consistent with the direction of the electric field on the ions to be measured within the ion mobility electric potential field, theoretically a mobility path of an infinite length can be formed so as to distinguish ions having mobility or ion cross sections that have very small differences.

Abstract: An ion mobility analyzer, combination device thereof, and ion mobility analysis method. The ion mobility analyzer comprises an electrode system that surrounds the analytical space and a power device that attaches to the electrode system an ion mobility electric potential field that moves along one space axis. During the process of analyzing mobility of ions to be measured, by always placing the ions to be measured in the moving ion mobility electric potential field, and keeping the movement direction of the ion mobility electric potential field consistent with the direction of the electric field on the ions to be measured within the ion mobility electric potential field, theoretically a mobility path of an infinite length can be formed so as to distinguish ions having mobility or ion cross sections that have very small differences.