H. Atsumi scite author profile

Physical characterization of nanoparticles is required for a wide range of applications. Nanomechanical resonators can quantify the mass of individual particles with detection limits down to a single atom in vacuum. However, applications are limited because performance is severely degraded in solution. Suspended microand nanochannel resonators have opened up the possibility of achieving vacuum-level precision for samples in the aqueous environment and a noise equivalent mass resolution of 27 attograms in 1-kHz bandwidth was previously achieved by Lee et al. [(2010) Nano Lett 10(7):2537-2542]. Here, we report on a series of advancements that have improved the resolution by more than 30-fold, to 0.85 attograms in the same bandwidth, approaching the thermomechanical noise limit and enabling precise quantification of particles down to 10 nm with a throughput of more than 18,000 particles per hour. We demonstrate the potential of this capability by comparing the mass distributions of exosomes produced by different cell types and by characterizing the yield of self-assembled DNA nanoparticle structures.nanoparticle characterization | NEMS | microfluidics | mechanical oscillators

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Absorption and desorption of deuterium on graphite at elevated temperatures

Atsumi¹,

Tokura²,

Miyake³

1988

Journal of Nuclear Materials

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Neoclassical Growth and the Efficient Program of Capital Accumulation

Atsumi¹

1965

The Review of Economic Studies

126

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Hydrogen absorption and transport in graphite materials

Atsumi

Tauchi

2003

Journal of Alloys and Compounds

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H. Atsumi

Harnessing the hygroscopic and biofluorescent behaviors of genetically tractable microbial cells to design biohybrid wearables

Weighing nanoparticles in solution at the attogram scale

Absorption and desorption of deuterium on graphite at elevated temperatures

Neoclassical Growth and the Efficient Program of Capital Accumulation

Hydrogen absorption and transport in graphite materials

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