| 000 | 02619nam a22002057a 4500 | ||
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| 005 | 20240116151058.0 | ||
| 008 | 240116b ||||| |||| 00| 0 eng d | ||
| 022 | _a0021-9584 | ||
| 100 | _aChen, Yuxin | ||
| 245 |
_aA Raspberry Pi Pico Based Low-Cost, Research-Grade, Open-Source Thermal Conductivity Cell Detector for Chemical Laboratory Analysis _b(Journal Article) |
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| 260 |
_aWashington DC _b: American Chemical Society _c, 2023 |
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| 300 | _a3477–3483p. | ||
| 440 |
_aJournal of Chemical Society _v, Volume 100: Number 9, September 2023 |
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| 505 | _a***______{For Hard Copy, Please visit Library.}________*** | ||
| 520 | _aAbstract: The “maker” movement is gaining widespread attention, especially in the field of laboratory education. Here we have built a low-cost, “do-it-yourself”, open-source thermal conductivity cell detector (TCD) for chemical laboratory analysis, which is assembled from thermal conductivity gas sensor elements and 3D-printed flow cell parts based on a Raspberry Pi Pico microcontroller. An ADS1115 digital-to-analog converter (with 16-bit acquisition resolution) is used to acquire the electrical signal from the thermal conductivity sensor response via a Wheatstone bridge. The device is programmed to acquire data based on the open-source Thonny Micro Python IDE software via I2C communication. Temperature programming analysis (TPA) is an important technique to characterize heterogeneous catalysts; therefore, we apply the assembled TCD to characterize the reduction properties of commercial Cu/ZnO/Al2O3 catalysts. The hydrogen temperature-programmed reduction (H2-TPR) profile of the commercial Cu/ZnO/Al2O3 catalyst shows a broad peak in the range of 150–250 °C with a peak position at 213 °C, which is consistent with previous reports. The total amount of hydrogen consumed by the commercial catalyst during H2-TPR is 10.7 mmol/gcat, which can be calculated from the calibrated H2 vol % TCD signal result and the peak area of the H2-TPR profile. The results show that the fabricated TCD detector exhibits excellent performance during the testing process and is capable of meeting research-grade applications. In summary, students will learn a wide range of skills in a hands-on learning environment of a chemistry laboratory course. | ||
| 650 | _aUpper-Division Undergraduate| Temperature-Programmed Analysis| Hands-On Learning/Manipulatives| Micro Python| Laboratory Equipment/Apparatus | ||
| 700 | _aWu, Yuting | Li, Zhengwen | Zheng, Yanyan | Yan, Binhang | Cheng, Yi | ||
| 856 | _uhttps://doi.org/10.1021/acs.jchemed.3c00488 | ||
| 942 | _cPER | ||
| 999 |
_c45278 _d45277 |
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