A benchtop miniature mass spectrometer
system, Mini 12, with ambient
ionization source and tandem mass spectrometry capabilities has been
developed and characterized. This instrument was developed as a self-contained
system to produce quantitative results for unprocessed samples of
small volumes including nonvolatile analytes. The ion processing system,
vacuum system, and control system are detailed. An integrated sample
loading system facilitates automated operation. A user interface has
been developed to acquire and to interpret analytical results for
personnel who have limited mass spectrometry knowledge. Peak widths
of Δm/z 0.6 Th (full width
at half-maximum) and a mass range of up to m/z 900 are demonstrated with the rectilinear ion trap mass
analyzer. Multistage experiments up to MS5 are accomplished.
Consumable cartridges have been designed for use in ambient paper
spray ionization, and the recently developed extraction spray ionization
method has been employed to improve the quantitative performance.
Monitoring of trace-levels of chemicals in therapeutic drugs, as well
as in food safety and environmental protection operations is demonstrated.
Dual MS/MS scans are implemented to obtain the intensities of the
fragment ions from the analyte and its internal standard, and the
ratio is used in quantitative analysis of complex samples. Limits
of quantitation (LOQ) of 7.5 ng/mL, with relative standard deviations
below 10%, have been obtained for selected therapeutic drugs in whole
blood throughout their individual therapeutic ranges.
A major design objective of portable mass spectrometers is the ability to perform in situ chemical analysis on target samples in their native states in the undisturbed environment. The miniature instrument described here is fully contained in a wearable backpack (10 kg) with a geometry-independent low-temperature plasma (LTP) ion source integrated into a hand-held head unit (2 kg) to allow direct surface sampling and analysis. Detection of chemical warfare agent (CWA) simulants, illicit drugs, and explosives is demonstrated at nanogram levels directly from surfaces in near real time including those that have complex geometries, those that are heat-sensitive, and those bearing complex sample matrices. The instrument consumes an average of 65 W of power and can be operated autonomously under battery power for ca. 1.5 h, including the initial pump-down of the manifold. The maximum mass-to-charge ratio is 925 Th with mass resolution of 1-2 amu full width at half-maximun (fwhm) across the mass range. Multiple stages of tandem analysis can be performed to identify individual compounds in complex mixtures. Both positive and negative ion modes are available. A graphical user interface (GUI) is available for novice users to facilitate data acquisition and real-time spectral matching.
Herein, we report a facile approach to decorate graphene oxide (GO) sheets with poly(vinyl acetate) (PVAc) by γ-ray irradiation-induced graft polymerization. The content of PVAc in the obtained sample, i.e., PVAc grafted GO (GO-g-PVAc) is calculated by the loss weight in thermogravimetric analysis (TGA) curves. A GO-g-PVAc sample with a degree of grafting (DG) of 28.5% was well dispersed in common organic solvents and the dispersions obtained were extremely stable at room temperature without any aggregation, even after standing for 2 months. The excellent dispersibility and stability of GO-g-PVAc in common organic solvents are readily rationalized in terms of the full coverage of PVAc chains and solvated layer formation on graphene oxide sheets surface, which weakens the interlaminar attraction of GO sheets. This approach presents a facile route for the preparation of dispersible GO and shows great potential in the preparation of graphene-based composites by solution-processes.
A novel amidoxime (AO)-based adsorbent, integrating the high affinity of AO groups and size effect of nanomaterials in nanofibrous composite mats, has been prepared by a two-nozzle electrospinning process for uranium extraction from seawater.
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