MARC details
| 000 -LEADER |
|---|
| fixed length control field |
02563nam a2200277Ia 4500 |
| 003 - CONTROL NUMBER IDENTIFIER |
|---|
| control field |
MX-MdCICY |
| 005 - DATE AND TIME OF LATEST TRANSACTION |
|---|
| control field |
20251009160709.0 |
| 040 ## - CATALOGING SOURCE |
|---|
| Transcribing agency |
CICY |
| 090 ## - LOCALLY ASSIGNED LC-TYPE CALL NUMBER (OCLC); LOCAL CALL NUMBER (RLIN) |
|---|
| Classification number (OCLC) (R) ; Classification number, CALL (RLIN) (NR) |
B-21919 |
| 008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION |
|---|
| fixed length control field |
251009s9999 xx 000 0 und d |
| 245 10 - TITLE STATEMENT |
|---|
| Title |
Recent progress on fabrication of carbon nanotube-based flexible conductive networks for resistive-type strain sensors. |
| 490 0# - SERIES STATEMENT |
|---|
| Series statement |
Sensors and Actuators A: Physical, 327, 112755, 2021. |
| 500 ## - GENERAL NOTE |
|---|
| General note |
Artículo |
| 520 3# - SUMMARY, ETC. |
|---|
| Summary, etc. |
Flexible resistive-type strain sensors are attracting wide attention due to their extensive potential applications. Carbon nanotubes (CNTs) with outstanding conductivity and mechanical properties can be assembled by various methods to form different conductive strain sensing networks within elastic polymers due to its nanoscale structure. Herein, the shapes of strain sensors are introduced including film, fiber and yarn, fabric, foams and gels. The various microstructures of CNT-based conductive networks are reviewed, such as uniform mixing, aligned structure, multilayered structure, porous structure, nanomesh structure, island-bridge structure, wavy structure, microarray structure, wrinkled structure, weaving structure. The lithographic processes, solution-based processing methods (such as dropping casting, spraying, ultrasonication, dip coating, sizing coating, layer-by-layer (LBL) assembly), chemical vapor deposition, printing technology (such as screen printing, inkjet printing, 3D printing) and electrospun technology were used to fabricate these conductive networks. The sensing performance and working mechanisms of these strain sensors with different conductive networks have been summarized and analyzed. Furthermore, their applications in the fields of personal healthcare, body motion detection, smart robot, human-machine interaction and structural health monitoring are reviewed. Finally, the existing challenges and prospective research directions are discussed. The CNT-based resistance-type strain sensors will be greatly promoted through innovations in integrating multidisciplinary technologies in future. |
| 650 14 - SUBJECT ADDED ENTRY--TOPICAL TERM |
|---|
| Topical term or geographic name entry element |
CARBON NANOTUBES |
| 650 14 - SUBJECT ADDED ENTRY--TOPICAL TERM |
|---|
| Topical term or geographic name entry element |
CONDUCTIVE NETWORKS |
| 650 14 - SUBJECT ADDED ENTRY--TOPICAL TERM |
|---|
| Topical term or geographic name entry element |
FABRICATING METHODS |
| 650 14 - SUBJECT ADDED ENTRY--TOPICAL TERM |
|---|
| Topical term or geographic name entry element |
FLEXIBLE STRAIN SENSORS |
| 650 14 - SUBJECT ADDED ENTRY--TOPICAL TERM |
|---|
| Topical term or geographic name entry element |
SENSING PERFORMANCE |
| 700 12 - ADDED ENTRY--PERSONAL NAME |
|---|
| Personal name |
Yan, T. |
| 700 12 - ADDED ENTRY--PERSONAL NAME |
|---|
| Personal name |
Wu, Y. |
| 700 12 - ADDED ENTRY--PERSONAL NAME |
|---|
| Personal name |
Yi, W. |
| 700 12 - ADDED ENTRY--PERSONAL NAME |
|---|
| Personal name |
Pan, Z. |
| 856 40 - ELECTRONIC LOCATION AND ACCESS |
|---|
| Uniform Resource Identifier |
<a href="https://drive.google.com/file/d/1ISKgk_eWX2bCbL6FxQuFWGraLXVQZxub/view?usp=drive_link">https://drive.google.com/file/d/1ISKgk_eWX2bCbL6FxQuFWGraLXVQZxub/view?usp=drive_link</a> |
| Public note |
Para ver el documento ingresa a Google con tu cuenta: @cicy.edu.mx |
| 942 ## - ADDED ENTRY ELEMENTS (KOHA) |
|---|
| Source of classification or shelving scheme |
Clasificación local |
| Koha item type |
Documentos solicitados |
