T. Chen scite author profile

T. Chen

2Publications

34Citation Statements Received

82Citation Statements Given

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University of Florida

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Chamber simulation of photooxidation of dimethyl sulfide and isoprene in the presence of NO<sub>x</sub>

Chen

Jang

2012

Atmos. Chem. Phys.

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Abstract. To improve the model prediction for the formation of H2SO4 and methanesulfonic acid (MSA), aerosol-phase reactions of gaseous dimethyl sulfide (DMS) oxidation products [e.g., dimethyl sulfoxide (DMSO)] in aerosol have been included in the DMS kinetic model with the recently reported gas-phase reactions and their rate constants. To determine the rate constants of aerosol-phase reactions of both DMSO and its major gaseous products [e.g., dimethyl sulfone (DMSO2) and methanesulfinic acid (MSIA)], DMSO was photooxidized in the presence of NOx using a 2 m3 Teflon film chamber. The rate constants tested in the DMSO kinetic mechanisms were then incorporated into the DMS photooxidation mechanism. The model simulation using the newly constructed DMS oxidation mechanims was compared to chamber data obtained from the phototoxiation of DMS in the presence of NOx. Within 120-min simulation, the predicted concentrations of MSA increase by 200–400% and those of H2SO4, by 50–200% due to aerosol-phase chemistry. This was well substantiated with experimental data. To study the effect of coexisting volatile organic compounds, the photooxidation of DMS in the presence of isoprene and NOx has been simulated using the newly constructed DMS kinetic model integrated with the Master Chemical Mechanism (MCM) for isoprene oxidation, and compared to chamber data. With the high concentrations of DMS (250 ppb) and isoprene (560–2248 ppb), both the model simulation and experimental data showed an increase in the yields of MSA and H2SO4 as the isoprene concentration increased.

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A Micromachined Geometric Moiré Interferometric Floating-Element Shear Stress Sensor

Horowitz

Chen

Chandrasekaran

et al. 2004

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This paper presents the development of a floating-element shear stress sensor that permits the direct measurement of skin friction based on geometric Moiré interferometry. The sensor was fabricated using an aligned waferbond/thin-back process producing optical gratings on the backside of a floating element and on the top surface of the support wafer. Experimental characterization indicates a static sensitivity of 0.26 µm/Pa, a resonant frequency of 1.7 kHz, and a noise floor of 6.2 mPa/√Hz.

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T. Chen

Chamber simulation of photooxidation of dimethyl sulfide and isoprene in the presence of NO<sub>x</sub>

A Micromachined Geometric Moiré Interferometric Floating-Element Shear Stress Sensor

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T. Chen

Chamber simulation of photooxidation of dimethyl sulfide and isoprene in the presence of NO&lt;sub&gt;x&lt;/sub&gt;

A Micromachined Geometric Moiré Interferometric Floating-Element Shear Stress Sensor

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Chamber simulation of photooxidation of dimethyl sulfide and isoprene in the presence of NO<sub>x</sub>