<?xml version="1.0" encoding="utf-8"?>
<rss version="2.0" xmlns:atom="http://www.w3.org/2005/Atom" xmlns:cf="http://www.microsoft.com/schemas/rss/core/2005">
<channel xmlns:cfi="http://www.microsoft.com/schemas/rss/core/2005/internal" cfi:lastdownloaderror="None">
<title cf:type="text"><![CDATA[ -->生物质基智能传感材料与器件]]></title>
<item>
<title xmlns:cf="http://www.microsoft.com/schemas/rss/core/2005" cf:type="text"><![CDATA[Research Progress in the Design Strategies of Conductive Hydrogels and Their Application in Wearable Sensors]]></title>
<link><![CDATA[http://zgzzxb.ijournals.cn/zzxben/ch/reader/view_abstract.aspx?file_no=202503001&flag=1]]></link>
<description xmlns:cf="http://www.microsoft.com/schemas/rss/core/2005" cf:type="html"><![CDATA[Conductive hydrogels， owing to their tunable mechanical properties， good adhesiveness， and biocompatibility， are emerging as promising candidates for wearable sensor applications. This review focused on the functional requirements of wearable sensors and systematically summarized the major synthetic routes and structural design strategies of conductive hydrogels. Research advances in multifunctional composite conductive hydrogels with self-healing ability， strong adhesion， anti-freezing and water-retention properties were highlighted. Strategies for performance optimization were discussed， and the open challenges in applying conductive hydrogels to wearable electronics were analyzed. Finally， potential future research directions were proposed.]]></description>
<pubDate>2025/9/23 19:02:02</pubDate>
<category><![CDATA[生物质基智能传感材料与器件]]></category>
<author><![CDATA[QIAN Jin,FU Yingjuan,ZHANG Yongchao,WANG Changjian,LIU Lifeng,QIN Menghua,CHEN Xiaoqian]]></author>
<atom:author xmlns:atom="http://www.w3.org/2005/Atom">
<atom:name>QIAN Jin,FU Yingjuan,ZHANG Yongchao,WANG Changjian,LIU Lifeng,QIN Menghua,CHEN Xiaoqian</atom:name>
</atom:author>
<guid><![CDATA[http://zgzzxb.ijournals.cn/zzxben/ch/reader/view_abstract.aspx?file_no=202503001&flag=1]]></guid><cfi:id>5</cfi:id><cfi:read>true</cfi:read></item>
<item>
<title xmlns:cf="http://www.microsoft.com/schemas/rss/core/2005" cf:type="text"><![CDATA[Research Progress of Enhancement Method of Paper-based Biosensor Chromogenic Property]]></title>
<link><![CDATA[http://zgzzxb.ijournals.cn/zzxben/ch/reader/view_abstract.aspx?file_no=202503002&flag=1]]></link>
<description xmlns:cf="http://www.microsoft.com/schemas/rss/core/2005" cf:type="html"><![CDATA[Paper-based color sensors have been widely used in environmental pollution monitoring， food safety analysis， and biological detection due to their low cost， convenience， and ease of operation. However， most of the paper-based color sensors could not be successfully incubated into commercial products， because the disadvantages of their color uniformity and poor color intensity were difficult to meet the demands of practical applications. Therefore， the research progress on improving the color rendering performance of paper-based color sensors was summarized in this paper， including the paper-based material types， the color rendering principle， and the enhancement methods. The shortcomings of the existing enhancement methods were analyzed and the future outlook was proposed.]]></description>
<pubDate>2025/9/23 19:02:03</pubDate>
<category><![CDATA[生物质基智能传感材料与器件]]></category>
<author><![CDATA[WEI Yuxuan,TANG Ruihua,YANG Xuyao,DU Aoqi]]></author>
<atom:author xmlns:atom="http://www.w3.org/2005/Atom">
<atom:name>WEI Yuxuan,TANG Ruihua,YANG Xuyao,DU Aoqi</atom:name>
</atom:author>
<guid><![CDATA[http://zgzzxb.ijournals.cn/zzxben/ch/reader/view_abstract.aspx?file_no=202503002&flag=1]]></guid><cfi:id>4</cfi:id><cfi:read>true</cfi:read></item>
<item>
<title xmlns:cf="http://www.microsoft.com/schemas/rss/core/2005" cf:type="text"><![CDATA[Construction and Performance of Paper-based NH<sub>3</sub> Sensor with MoS<sub>2</sub>/Zinc Stannate Heterojunction Modification]]></title>
<link><![CDATA[http://zgzzxb.ijournals.cn/zzxben/ch/reader/view_abstract.aspx?file_no=202503003&flag=1]]></link>
<description xmlns:cf="http://www.microsoft.com/schemas/rss/core/2005" cf:type="html"><![CDATA[This study utilized Lysine （Lys） modified MoS<sub>2</sub> nanosheets and combined with zinc stannate to prepare an n-n heterojunction composite gas-sensitive material， which were then deposited onto paper-based substrates to construct paper-based NH₃ sensors. The gas-sensing performance of the sensors was tested， and the gas-sensing mechanism was investigated. The results indicated that the paper-based NH<sub>3</sub> sensor constructed using the heterojunction exhibited a responsiveness of 11.76% to 0.15 g/L NH<sub>3</sub> at room temperature， which was approximately 3.5 times that of the paper-based MoS<sub>2</sub> sensor （3.34%）.]]></description>
<pubDate>2025/9/23 19:02:03</pubDate>
<category><![CDATA[生物质基智能传感材料与器件]]></category>
<author><![CDATA[LIU Peiting,TIAN Xiuzhi,LI Yujia,LI Mingqin,HOU Enfeng,JIANG Xue]]></author>
<atom:author xmlns:atom="http://www.w3.org/2005/Atom">
<atom:name>LIU Peiting,TIAN Xiuzhi,LI Yujia,LI Mingqin,HOU Enfeng,JIANG Xue</atom:name>
</atom:author>
<guid><![CDATA[http://zgzzxb.ijournals.cn/zzxben/ch/reader/view_abstract.aspx?file_no=202503003&flag=1]]></guid><cfi:id>3</cfi:id><cfi:read>true</cfi:read></item>
<item>
<title xmlns:cf="http://www.microsoft.com/schemas/rss/core/2005" cf:type="text"><![CDATA[Application Research Progress of Lignin-based Hydrogels in the Field of Intelligent Sensing]]></title>
<link><![CDATA[http://zgzzxb.ijournals.cn/zzxben/ch/reader/view_abstract.aspx?file_no=202503004&flag=1]]></link>
<description xmlns:cf="http://www.microsoft.com/schemas/rss/core/2005" cf:type="html"><![CDATA[Lignin possesses characteristics such as renewability， good biocompatibility， and the ability to be functionally modified. In recent years， with the development of green chemistry and sustainable materials， lignin-based hydrogels have gradually become a research hotspot in the field of smart sensing due to their unique porous structure， stimulus responsiveness， and multifunctional interface properties. This paper introduced the construction strategies and functionalization modification methods of lignin-based hydrogels， reviewed their research progress in intelligent sensing such as biomedical sensing， humidity-induced power generation， strain sensing， and flexible supercapacitors， summarized the structural design and performance optimization strategies of multifunctional lignin-based hydrogels， and put forward the challenges and solutions for achieving multi-scenario adaptability and advancing industrialization of lignin-based hydrogels.]]></description>
<pubDate>2025/9/23 19:02:04</pubDate>
<category><![CDATA[生物质基智能传感材料与器件]]></category>
<author><![CDATA[TANG Xinli,ZHAO Wei,JIAO Jixuan,SHI Qiang,XIE Jianqiang,NIU Shilei,SUN Jiankui]]></author>
<atom:author xmlns:atom="http://www.w3.org/2005/Atom">
<atom:name>TANG Xinli,ZHAO Wei,JIAO Jixuan,SHI Qiang,XIE Jianqiang,NIU Shilei,SUN Jiankui</atom:name>
</atom:author>
<guid><![CDATA[http://zgzzxb.ijournals.cn/zzxben/ch/reader/view_abstract.aspx?file_no=202503004&flag=1]]></guid><cfi:id>2</cfi:id><cfi:read>true</cfi:read></item>
<item>
<title xmlns:cf="http://www.microsoft.com/schemas/rss/core/2005" cf:type="text"><![CDATA[Construction of Bentonite-reinforced Polyvinyl Alcohol/Nanocellulose Deep Eutectic Gel and Its Application in Strain Sensors]]></title>
<link><![CDATA[http://zgzzxb.ijournals.cn/zzxben/ch/reader/view_abstract.aspx?file_no=202503005&flag=1]]></link>
<description xmlns:cf="http://www.microsoft.com/schemas/rss/core/2005" cf:type="html"><![CDATA[Using a deep eutectic solvent （DES） as the antifreeze medium， based on the polymer hydrogen bond network， and coordination interection between zinc ions and the polyvinyl alcohol/cellulose nanofiber-bentonite （PVA/CNF-BT） gel matrix， a PVA/CNF-BT DES gel with both high mechanical strength and excellent freeze resistance was successfully constructed. The results showed that when the PVA addition amount was 10% （mass fraction relative to DES）， and the addition amounts of BT nanosheets and CNF （both mass fractions relative to PVA） were 0.6% and 20%， respectively， the tensile strength and break elongation rate of the gel material reached 3.35 MPa and 832%. Its ionic conductivity at room temperature and the extreme temperature of -38 ℃ was 0.24 and 0.23 mS/cm， respectively， demonstrating outstanding freeze resistance and low-temperature conductivity. Furthermore， the DEG-based strain sensor integrated from the PVA/CNF-BT DEG possessed a wide strain response range （0~1 000%）， high sensitivity （gauge factor could reach 3.36）， and durability over 300 strain cycles. When applied to monitor motion in human body parts such as the index finger， wrist， and elbow， the DES-based strain sensor exhibited excellent sensing performance.]]></description>
<pubDate>2025/9/23 19:02:05</pubDate>
<category><![CDATA[生物质基智能传感材料与器件]]></category>
<author><![CDATA[DU Lin,HU Jianquan,WANG Yida,LIU Yuxin]]></author>
<atom:author xmlns:atom="http://www.w3.org/2005/Atom">
<atom:name>DU Lin,HU Jianquan,WANG Yida,LIU Yuxin</atom:name>
</atom:author>
<guid><![CDATA[http://zgzzxb.ijournals.cn/zzxben/ch/reader/view_abstract.aspx?file_no=202503005&flag=1]]></guid><cfi:id>1</cfi:id><cfi:read>true</cfi:read></item>
</channel>
</rss>