文献类型：期刊文献

英文题名：Correction to: Carbon nanotube modified cellulose nonwovens: superhydrophobic, breathable, and sensitive for drowning alarm and motion monitoring (Cellulose, (2023), 10.1007/s10570-023-05695-7)

作者：Zhang, Rui[1,2]; Ye, Suxian[1]; Suzuki, Ryuki[3]; Xie, Chengbo[1]; Wang, Jian[1,2,4]; Huang, Weizhe[1]; Zou, Zhuanyong[1,2,4]

机构：[1] School of Textile and Apparel, Shaoxing University, Zhejiang, Shaoxing, 312000, China; [2] Key Laboratory of Clean Dyeing and Finishing Technology of Zhejiang Province, Shaoxing University, Zhejiang, Shaoxing, 312000, China; [3] Center for Material Design Science, School of Integrated Design Engineering, Keio University, 3-14-1 Hiyoshi, Yokohama, 223-8522, Japan; [4] Shaoxing Key Laboratory of High Performance Fibers & amp, Products, Shaoxing University, Zhejiang, Shaoxing, 312000, China

年份：2024

外文期刊名：Cellulose

收录：EI(收录号：20241015698995)

语种：英文

外文摘要：In the original published article, the authors discovered that while processing the data, they have mistakenly treated Rmin as R0, resulting in a deviation in the result, which resulted in having to update the sensitivity section in Fig.?4 and Fig.?6. (Figure presented.) a Resistance values of CHN and SCHN for different impregnation times; b Breathability of CHN and SCHN for different number of impregnations; c Comparison of the permeability of HN, CHN and SCHN; d Comparison of the contact angle of HN, CHN and SCHN; e–g?Comparison of the sensitivity of single, three and five layers of SCHN; h Comparison of the permeability of one, three and five layers of CHN and SCHN; i Glass bottle filled with dry ice and warm water covered with HN, j impregnated once, k impregnated three times, and l 3 layers of SCHN covering the top of the glass bottle containing dry ice and warm water.(Scale bar 3.5?cm) In addition to the relative resistance values of a,b,c,d,g in Fig.?5, the relative resistance values of a, b, c, d, e, and l in Fig.?8 and the ordinate in Fig.?9 also need to be updated, and do not affect the main results and conclusions of the paper. (Figure presented.) (Figure presented.) (Figure presented.) (Figure presented.) a Pressure response curves of 5?g weights; b Pressure response curves of 10?g weights; c Pressure response curves of 20?g weights; d Comparison of pressure response curves for weights of 5?g, 10?g, and 20?g; (4) Responses of water drops at different heights; (5) Responses of drops of different species at the same height; g SCHN sensor response and recovery time; h–i Endurance testing under 2.5?kPa pressure for 2000 consecutive cycles Star-shaped comparison of sensor performance with other sensors reported in the literature a?Finger press response for different forces; b Response for different finger clicks; c Elbow flexion movement; d Wrist flexion movement; e Finger flexion movement; f Resistance change when the volunteer swallows; g Real-time monitoring of "CNT" and "PDMS" speech response vibrations; h Mouth opening; i Blinking; j Detection of arterial heart pulse signals on the wrist; k Morse code table of 26 English letters; l Signals from Morse code a Photographs of 5?g, 10?g, and 20?g weights placed on a 4 × 4 SCHN sensor array and distribution of relative resistance changes; b Photograph of a Bluetooth headset placed on a 4 × 4 SCHN sensor array and distribution of relative resistance changes; c Photograph of a black marker placed on a 4 × 4 SCHN sensor array and distribution of relative resistance changes However, the authors apologize for any inconvenience or confusion that this error may have caused to the readers and reviewers. The correct version of Figs.?4, 5, 6, 8 and 9 are provided in this correction. Due to this error, the sensitivity value "128.39?kPa?1 in 0–0.6?kPa and 0.027?kPa?1 in 0.6–210?kPa" appearing in the Abstract, Introduction (fourth paragraph) and the conclusion section should be "11.78?kPa?1 in 0–5.20?kPa and 0.058?kPa?1 in 5.20–210?kPa". Also, the information "It can be seen from the figure that the sensitivity of the one-layer structure sensor is 0.012?kPa?1 in the range of 0–57 kPa and 0.00069?kPa?1 in the range of 57–300?kPa. In contrast, the three-layer structure sensor has sensitivities as high as 128.39?kPa?1 in the range of 0 to 0.6 kPa and 0.027?kPa?1 in the range of 0.6 to 210 kPa. In the range of 0 to 0.84?kPa and 0.84 to 225?kPa, the sensitivity of the five-layer structure sensor is 131.51?kPa?1 and 0.086?kPa?1, which is an increase of only a small amount compared to the three-layer structure." present in the section "Preparation and characterization of SCHN" under heading "Results and discussion" should be "It can be seen from the figure that the sensitivity of the one-layer structure sensor is 0.18?kPa?1 in the range of 0–13.58?kPa and 0.065?kPa?1 in the range of 13.58–143?kPa. In contrast, the three-layer structure sensor has ensitivities as high as 11.78?kPa?1 in the range of 0–5.20?kPa and 0.058?kPa?1 in the range of 5.20–210?kPa. In the range of 0–4.41 kPa and 4.41–157?kPa, the sensitivity of the five-layer structure sensor is 12.31?kPa?1 and 0.103?kPa?1, which is an increase of only a small amount compared to the three-layer structure". The original article has been corrected. ? The Author(s), under exclusive licence to Springer Nature B.V. 2024.