STRUCTURE CONTROL FOR DIFFERENT TYPES OF PAPER BY ATOMIC FORCE MICROSCOPY

Zhukov Mikhail V

2014 , VOLUME 14, NUMBER 1 ( JANUARY-FEBRUARY )

ISSN 2226-1494 (print), ISSN 2500-0373 (online)

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Nikiforov
Vladimir O.
D.Sc., Prof.

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STRUCTURE CONTROL FOR DIFFERENT TYPES OF PAPER BY ATOMIC FORCE MICROSCOPY

M. V. Zhukov

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Abstract

The paper deals with the precision control for the parameters of manufactured paper production, such as various kinds of paper and photo paper for printing. Research of untreated, matte, glossy and laminated paper is conducted by atomic force microscopy by means of educational and scientific scanning probe microscope NanoEducator LE in the framework of this paper. Visualization of characteristic structure for each type of studied paper was conducted, histogram of roughness was obtained, and average roughness of height differences was defined. A laminated paper has got the lowest roughness (Ra of about 70 nm) and glossy paper has got Ra of about 170 nm; roughness of untreated paper with cellulose fibers is about 530-540 nm, and matte paper has got the highest roughness parameters (Ra about 670-680 nm). Scanning probe microscopy application for parameters monitoring of cellulosic paper production is shown to give the possibility of such microscopy type application in the production of paper products and high-precision control of its parameters.

Keywords: paper, atomic force microscopy, roughness, photo paper, scanning probe microscope

References

1. Список продукции материалов для струйной печати Lomond [Электронный ресурс]. Режим доступа: http://printer.ucoz.ua/Lomond-2005.pdf, свободный. Яз. рус. (дата обращения 05.12.2013).

2. Chinga G. Structural studies of LWC paper coating layers using SEM and image analysis techniques. Ph D. Thesis. Norwegian University of Science and Technology Department of Chemical Engineering. February 2002. 122 p. [Электронный ресурс]. Режим доступа: http://www.divaportal.org/smash/get/diva2:121743/FULLTEXT01.pdf, свободный. Яз. англ. (дата обра- щения 05.12.2013).

3. Yang D., Parlange J.-Y., Walker L.P., Moran-Mirabal J.M. Investigation of the porous structure of cellulosic substrates through confocal laser scanning microscopy // Biotechnology and Bioengineering. 2013. V. 110. N 11. P. 2836–2845.

4. Witec. Focus innovations. Confocal Raman & AFM Imaging of Paper [Электронный ресурс]. Режим дос- тупа: http://www.witec.de/assets/Downloads/afm/Paper.pdf, свободный. Яз. англ. (дата обращения 05.12.2013).

5. CD-Laboratory for Surface Chemical and Physical Fundamentals of Paper Strength [Электронный ресурс]. Режим доступа: https://www.ipz.tugraz.at/index.php/wbPage/wbShow/cd?lang=en, свободный. Яз. англ. (дата обращения 05.12.2013).

6. Shimadzu – AFM Observation of Coated Paper and Printed Surface [Электронный ресурс]. Режим досту- па: http://www.shimadzu.com/an/surface/spm/data/appli/paper.html, свободный. Яз. англ. (дата обраще- ния 05.12.2013).

7. Maattanen A., Fors D., Wang S., Valtakari D., Ihalainen P., Peltonen J. Paper-based planar reaction arrays for printed diagnostics // Sensors and Actuators B. 2011. V. 160. N 1. P. 1404–1412.

8. JPK Instruments. Application note. Studying texture of paper with AFM and Upright optical microscopy using the BioMAT Workstation [Электронный ресурс]. Режим доступа:https://www.google.ru/url?sa=t&rct=j&q=&esrc=s&source=web&cd=7&ved=0CGoQFjAG&url=ht tp%3A%2F%2Fwww.jpk.com%2Findex.download.2cd8ad3d77e6aa0fb7b45cc3b9d0d192&ei=GxSfUtLfG Mrd4QTN34HIBA&usg=AFQjCNEUFL_TpQfKNzaYtg2ANUGALZSKFQ&bvm=bv.57155469,d.bGE&ca d=rjt, свободный. Яз. англ. (дата обращения 05.12.2013).

9. Paiva A.T., Sequeira S.M., Evtuguin D.V., Kholkin A.L., Portugal I. Nanoscale Structure of Cellulosic Materials: Challenges and Opportunities for AFM // Modern Research and Educational Topics in Microscopy/ Eds A. Méndez-Vilas, J. Díaz. Formatex, 2007. V. 2. P. 726–733.

10. Persson B.N.J., Ganser C., Schmied F., Teichert C., Schennach R., Gilli E., Hirn U. Adhesion of cellulose fibers in paper // J. Phys.: Condens. Matter. 2013. V. 25. N 4. P. 045002-1– 045002-11.

11. Pinzari F., Pasquariello G., De Mico A. Biodeterioration of Paper: A SEM Study of Fungal Spoilage Reproduced Under Controlled Conditions // Macromol. Symp. 2006. V. 238. N 1. P. 57–66.

12. Ion R.-M., Doncea S.M., Ion M.-L., Rădiţoiu V., Amăriuţei V. Surface investigations of old book paper treated with hydroxyapatite nanoparticles // Applied Surface Science. 2013. V. 285. Part A. P. 27–32.

13. Piantanida G., Pinzari F., Montanari M., Bicchieri M., Coluzza C. Atomic Force Microscopy Applied to the Study of Whatman Paper Surface Deteriorated by a Cellulolytic Filamentous Fungus // Macromol. Symp. 2006. V. 238. N 1. P. 92–97.

14. NT-SPb. Наноэдьюкатор LE [Электронный ресурс]. Режим доступа: http://ntspb.dev.ntmdt.ru/device/view/nanoeducator-1-1, свободный. Яз. рус. (дата обращения 05.12.2013).

15. Голубок А.О., Пинаев А.Л., Феклистов А.А., Чивилихин С.А. Об устойчивости вольфрамовых зондов при функционировании сканирующего зондового микроскопа в режимах динамической силовой лито- графии и наноиндентирования // Научно-технический вестник СПбГУ ИТМО. 2011. № 4 (74). С. 91–97.

16. Бумага для принтера – Svetocopy Paper [Электронный ресурс]. Режим доступа: http://sveto-copy.ru/, свободный. Яз. рус. (дата обращения 05.12.2013).

17. Материалы для струйной печати офисных форматов Lomond [Электронный ресурс]. Режим доступа: http://www.lomond.ru/, свободный. Яз. рус. (дата обращения 05.12.2013).

18. ISO 4287:1997. Geometrical Product Specifications (GPS) – Surface texture: Profile method – Terms, definitions and surface texture parameters. 01.04.1997. Geneva, International Organization for Standardization. 35 p.

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