{"id":209,"date":"2021-01-25T16:54:39","date_gmt":"2021-01-25T08:54:39","guid":{"rendered":"https:\/\/www.bihec.com\/instruquest\/?p=209"},"modified":"2021-01-25T16:54:39","modified_gmt":"2021-01-25T08:54:39","slug":"humisys-hf-%e6%b9%bf%e5%ba%a6%e5%8f%91%e7%94%9f%e5%99%a8%e5%ba%94%e7%94%a8%ef%bc%9a%e6%9c%a8%e7%bb%86%e8%83%9e%e5%a3%81%e4%b8%ad%e8%8b%af%e9%85%9a-%e7%94%b2%e9%86%9b%e7%9a%84%e5%88%86%e5%ad%90","status":"publish","type":"post","link":"https:\/\/www.bihec.com\/instruquest\/humisys-hf-%e6%b9%bf%e5%ba%a6%e5%8f%91%e7%94%9f%e5%99%a8%e5%ba%94%e7%94%a8%ef%bc%9a%e6%9c%a8%e7%bb%86%e8%83%9e%e5%a3%81%e4%b8%ad%e8%8b%af%e9%85%9a-%e7%94%b2%e9%86%9b%e7%9a%84%e5%88%86%e5%ad%90\/","title":{"rendered":"HumiSys HF \u6e7f\u5ea6\u53d1\u751f\u5668\u5e94\u7528\uff1a\u6728\u7ec6\u80de\u58c1\u4e2d\u82ef\u915a-\u7532\u919b\u7684\u5206\u5b50\u95f4\u76f8\u4e92\u4f5c\u7528 \u7eb3\u7c73\u7ea4\u7ef4\u7d20\u819c \u5e26\u8bb0\u5fc6\u7684\u57fa\u4e8e\u690d\u7269\u7684\u626d\u8f6c\u6267\u884c\u5668"},"content":{"rendered":"

1. SYNCHROTRON-BASED X-RAY FLUORESCENCE MICROSCOPY IN CONJUNCTION WITH NANOINDENTATION TO STUDY MOLECULAR-SCALE INTERACTOINS OF PHENOL-FORMALDEHYDE IN WOOD CELL WALLS.
\n\u57fa\u4e8e\u540c\u6b65\u52a0\u901f\u5668\u7684X\u5c04\u7ebf\u8367\u5149\u663e\u5fae\u955c\u4e0e\u7eb3\u7c73\u538b\u5370\u76f8\u7ed3\u5408\uff0c\u4ee5\u7814\u7a76\u6728\u7ec6\u80de\u58c1\u4e2d\u82ef\u915a-\u7532\u919b\u7684\u5206\u5b50\u95f4\u76f8\u4e92\u4f5c\u7528<\/a>\u3002<\/p>\n

2. VARIATION OF NANOSTRUCTURES, MOLECULAR INTERACTIONS, AND ANISOTROPIC ELASTC MODULI OF LIGNOCELLULOSIC CELL WALLS WITH MOISTURE.
\n\u5177\u6709\u6c34\u5206\u7684\u6728\u8d28\u7ea4\u7ef4\u7d20\u7ec6\u80de\u58c1\u7684\u7eb3\u7c73\u7ed3\u6784\uff0c\u5206\u5b50\u76f8\u4e92\u4f5c\u7528\u548c\u5404\u5411\u5f02\u6027\u5f39\u6027\u6a21\u91cf\u7684\u53d8\u5316\u3002<\/p>\n

3.EFFECTIVE Am(III)\/Eu(III) SEPARATIONS USING BTP FUNCTIONALISED TITANIA NANOPARTICLES AND BEADS
\n\u4f7f\u7528BTP\u529f\u80fd\u6027\u4e8c\u6c27\u5316\u949b\u7eb3\u7c73\u7c92\u5b50\u548c\u73e0\u5b50\u6709\u6548\u5206\u79bbAm(III)\/Eu(III)<\/p>\n

4. THRESHOLD FOR ION MOVEMENTSIN WOOD CELL WALLS BELOW FIBER SATURATION OBSERVED BY X-RAY FLUORESCENCE MICROSCOPY (XFM)
\nX\u5c04\u7ebf\u8367\u5149\u663e\u5fae\u955c\uff08XFM\uff09\u89c2\u5bdf\u5230\u7684\u7ea4\u7ef4\u9971\u548c\u5ea6\u4ee5\u4e0b\u7684\u6728\u8d28\u7ec6\u80de\u58c1\u4e2d\u79bb\u5b50\u8fd0\u52a8\u7684\u9608\u503c<\/p>\n

5. SUBCELLULAR ELECTRICAL MEASUREMENTS AS A FUNCTION OF WOOD MOISTURE CONTENT
\n\u4f5c\u4e3a\u6728\u6750\u6c34\u5206\u542b\u91cf\u7684\u529f\u80fd\u7684\u5b50\u7535\u6c60\u7535\u6c14\u6d4b\u91cf<\/p>\n

6. WOOD AS INSPIRATION FOR NEW STIMULI – RESPONSIVE STRUCTURES AND MATERIALS
\n\u4ee5\u6728\u6750\u4e3a\u7075\u611f\u7684\u65b0\u523a\u6fc0-\u8d1f\u8d23\u4efb\u7684\u7ed3\u6784\u548c\u6750\u6599<\/p>\n

7. THREE-DIMENSIONAL MICROSTRUCTURAL PROPERTIES OF NANOFIBRILLATED CELLULOSE FILMS.
\n\u7eb3\u7c73\u7ea4\u7ef4\u5316\u7ea4\u7ef4\u7d20\u819c\u7684\u4e09\u7ef4\u5fae\u89c2\u7ed3\u6784\u7279\u6027<\/p>\n

8. ANALYSIS OF REAL-TIME METHYL SALICYLATE DETECTION TO ENHANCE THE EVALUATION OF PROTECTIVE ENSEMBLES IN THE MAN-IN-SIMULANT TEST.
\n\u5b9e\u65f6\u5206\u6790\u6c34\u6768\u9178\u7532\u916f\u7684\u68c0\u6d4b\uff0c\u4ee5\u589e\u5f3a\u5bf9\u534a\u4eba\u6a21\u62df\u6d4b\u8bd5\u4e2d\u4fdd\u62a4\u6027\u5305\u88f9\u4f53\u7684\u8bc4\u4f30\u3002<\/p>\n

9.THE EFFECT OF WATER UPTAKE ON MECHANICAL PROPERTIES OF LOW-K ORGANOSILICATE GLASS.
\n\u5438\u6c34\u5bf9\u4f4e\u94be\u6709\u673a\u7845\u73bb\u7483\u673a\u68b0\u6027\u80fd\u7684\u5f71\u54cd\u3002<\/p>\n

10. PLANT-BASED TORSIONAL ACTUATOR WITH MEMORY.
\n \u5e26\u8bb0\u5fc6\u7684\u57fa\u4e8e\u690d\u7269\u7684\u626d\u8f6c\u6267\u884c\u5668<\/a>\u3002<\/p>\n

11. SUIVI PAR DRX DES R\u00e9arrangements Microstructuraux Induits Par Sollicitations M\u00e9caniques Ddans Les Fibres V\u00e9g\u00e9tales Tir\u00e9es Du Chanvre.
\nDRX\u5bf9\u5927\u9ebb\u5f15\u8d77\u7684\u690d\u7269\u7ea4\u7ef4\u4e2d\u673a\u68b0\u5e94\u529b\u5f15\u8d77\u7684\u5fae\u7ed3\u6784\u91cd\u6392\u7684\u8ddf\u8e2a\u7814\u7a76\u3002<\/p>\n

12. CREEP BEHAVIOUR OF SINGLE HEMP FIBRES. Part I: VISCOELASTIC PROPERTIES AND THEIR SCATTERING UNDER CONSTANT CLIMATE.
\n\u5355\u5927\u9ebb\u7ea4\u7ef4\u7684\u8815\u53d8\u884c\u4e3a\u3002 \u7b2c\u4e00\u90e8\u5206\uff1a\u6052\u5b9a\u6c14\u5019\u4e0b\u7684\u7c98\u5f39\u6027\u548c\u6563\u5c04\u6027\u3002<\/p>\n

13. TENSILE BEHAVIOUR OF NATURAL FIBRES. EFFECT OF LOADING RATE, TEMPERATURE AND HUMIDITY ON THE \u201cACCOMMODATION\u201d PHENOMENA.
\n\u5929\u7136\u7ea4\u7ef4\u7684\u62c9\u4f38\u884c\u4e3a\u3002 \u8d1f\u8377\u7387\uff0c\u6e29\u5ea6\u548c\u6e7f\u5ea6\u5bf9\u201c\u4f4f\u5bbf\u201d\u73b0\u8c61\u7684\u5f71\u54cd\u3002<\/p>\n