Ying Tang scite author profile

Optical trapping of (sub)micron-sized particles is broadly employed in nanoscience and engineering. The materials commonly employed for these particles, however, have physical properties that limit the transfer of linear or angular momentum (or both). This reduces the magnitude of forces and torques, and the spatiotemporal resolution, achievable in linear and angular traps. Here, we overcome these limitations through the use of single-crystal rutile TiO2, which has an exceptionally large optical birefringence, a high index of refraction, good chemical stability, and is amenable to geometric control at the nanoscale. We show that rutile TiO2 nanocylinders form powerful joint force and torque transducers in aqueous environments by using only moderate laser powers to apply nN·nm torques at kHz rotational frequencies to tightly trapped particles. In doing so, we demonstrate how rutile TiO2 nanocylinders outperform other materials and offer unprecedented opportunities to expand the control of optical force and torque at the nanoscale.

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Information visualization techniques in bioinformatics during the postgenomic era

Tang

Liu

Friedman

et al. 2004

Drug Discovery Today: BIOSILICO

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Information visualization techniques, which take advantage of the bandwidth of human vision, are powerful tools for organizing and analyzing a large amount of data. In the postgenomic era, information visualization tools are indispensable for biomedical research. This paper aims to present an overview of current applications of information visualization techniques in bioinformatics for visualizing different types of biological data, such as from genomics, proteomics, expression profiling and structural studies. Finally, we discuss the challenges of information visualization in bioinformatics related to dealing with more complex biological information in the emerging fields of systems biology and systems medicine.

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Improving forecasting accuracy of daily enterprise electricity consumption using a random forest based on ensemble empirical mode decomposition

Tang

et al. 2018

Energy

146

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Ying Tang

Information theory applied to the sparse gene ontology annotation network to predict novel gene function

Single-Crystal Rutile TiO₂ Nanocylinders are Highly Effective Transducers of Optical Force and Torque

Information visualization techniques in bioinformatics during the postgenomic era

Improving forecasting accuracy of daily enterprise electricity consumption using a random forest based on ensemble empirical mode decomposition

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Ying Tang

Information theory applied to the sparse gene ontology annotation network to predict novel gene function

Single-Crystal Rutile TiO2 Nanocylinders are Highly Effective Transducers of Optical Force and Torque

Information visualization techniques in bioinformatics during the postgenomic era

Improving forecasting accuracy of daily enterprise electricity consumption using a random forest based on ensemble empirical mode decomposition

Contact Info

Product

Resources

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Single-Crystal Rutile TiO₂ Nanocylinders are Highly Effective Transducers of Optical Force and Torque