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Low temperature scanning tunneling microscopy (LT-STM), Ag (111) surface

Year 2014, Volume: 2 Issue: 2, 236 - 245, 01.12.2014

Abstract

Bu makalede, Ag (111) yüzeyi deneysel ve teorik olarak detaylı şekilde aratılmıştır. Deneysel
çalışma için
düşük
sıcaklık taramalı tünelleme mikroskopu ve teorik çalışma için STMAFM bilgisayar
programı metotları
kullanılmıştır. Bunun için nano boyutta veri almak için LT-STM ultra
vakum şartlarında doğru bir şekilde kurul
muş ve diğer ekipmanlar dizayn edilmiştir. Deneysel
işlemlerle Ag (111) yüzeyinden alınan veriler 5 K de şartların
da alınmıştır. Taramalı tünelleme
mikroskopunun çalışması için gerekli karmaşık ekipmanlar ve bu ekipman
ların nasıl kurulduğu ve ses ve sinyal
izolasyonunun nasıl sağlandığı ve taramalı tünelleme mikroskobunun bir malzeme
incelerken nasıl çalıştırıldığı detaylı olarak laboratuarda yapılmıştır. Atomik
olarak temizlenmiş Ag
(111) yüzeyinden alınan bu veriler analiz edilmiştir. Bunun yanı sıra
STMAFM bilgisayar programı yardımıyla
Ag atomlan arasındaki mesafe teorik olarak hesaplanacak
ve analizi yapılacak ve bunun deneyle tam uyum gösterdiği gösterilecektir. Bu
çalışma gelecekteki spintronik aygıtların uygulamasına temel olarak, bilimsel
boşluğu doldurduğundan önem arz etmektedir. Aynca, STM'in atomik ölçekte
atomları kontrol etmesiyle, bottom-up na-
nochip
tasarımında, daha küçük ölçekte nanochip dizayn etme yolu açılacaktır.




References

  • [1]. Chen, C. Julian.,Introduction to Scanning Tunneling Microscopy,New York:Oxford Press, 2008. [2]. John, B., Alan, D., Robert, L., Joy, M., Andrew, N. Quantum Physics of Matter, London: Institue of Physics Publishing, 2000. [3]. Mohsen, R. Quantum Theory of Tunneling, Singapore: World Scientific Publishing Co. Pte. Ltd, 2003. [4]. Chambers,A., Fitch, R.K., Halliday, B.S., Basic Vacuum Technology, London: Institue of Physics Publishing, 1998. [5]. Besocke, K., An Easily Operatable Scanning Tunneling Microscope, Surface Science, 181, 145-153, 1987. [6]. Chunli, B., Gerhard, E., Robert, G., Hans, L., Douglas, L.M., Scanning Tunneling Microscopy and Its Applications, Shanghai, Shanghai Scientific and Technical Publishers, 1992. [7]. Hablanian, M.H., High-Vacuum Technology, APractical Guide, New York: Marcel Dekker, Inc, 1997. [8]. Karl., J., Handbook of Vacuum Technology, Wemheim: Verlag GmbH Co., 2008. [9]. F.O'Hanlon, John. A User's Guide to Vacuum Technolog, New Jersey: John Wiley&Sons, Inc., 2003. [10]. Hla, S-W, Bartels, L., Meyer, G. and Reider K.-H., Inducing All Steps of a Chemical Reaction with the Scanning Tunneling Microscope Tip: Towards Single Molecule Engineering, Phys. Rev. Lett. 85, 2777-2780, 2000. [11]. Hla, S-W, Scanning Tunneling Microscopy Single Atom/Molecule Manipulation and Its Application to Nanoscience and Technology, J Vac. Sci Tech B, 23,1251-1360, 2005. [12]. Eigler, D.M., Schweizer, E.K. Positioning Single Atoms with A Scanning Tunneling Microscope, Nature 344, 524-526,1990. [13]. Shen,T.C. Atomic-Scale Desorption Through Electronic and Vibrational Excitation Mechanism,,Science, 268, 1590-1592, 1995. [14]. Nilius, N., Wallis, T.M., Ho, W., Development of One-Dimensional Band Structure in Artifical Gold Chains, Science, 297, 1853-1856, 2002. [15]. Vacancy scanning tunneling spectroscopy on Ag (111), Poster Presentation, APS March meeting Baltimore, US A, 2006. [16]. Noriaki Takagi, C-L.L., Tsukahara, N., Kawai, M., Arafune, R. Silicene on Ag(lll): Geometric and Electronic Structures of a New Honeycomb Material of Si, Progress in Surface Science, 1-20, 2015. [17]. Seymur Cahangirov, V.O., Atomic Structure of the V3 x V3 Phase of Silicene on Ag(lll), Physical Review B, 1-5, 2014. [18]. Wu, K., Persistent Dirac Fermion State in a Silicon-based Material, Program of the 4th ICQs Conference on Spintronics, Beijing, 15, 2014.
Year 2014, Volume: 2 Issue: 2, 236 - 245, 01.12.2014

Abstract

References

  • [1]. Chen, C. Julian.,Introduction to Scanning Tunneling Microscopy,New York:Oxford Press, 2008. [2]. John, B., Alan, D., Robert, L., Joy, M., Andrew, N. Quantum Physics of Matter, London: Institue of Physics Publishing, 2000. [3]. Mohsen, R. Quantum Theory of Tunneling, Singapore: World Scientific Publishing Co. Pte. Ltd, 2003. [4]. Chambers,A., Fitch, R.K., Halliday, B.S., Basic Vacuum Technology, London: Institue of Physics Publishing, 1998. [5]. Besocke, K., An Easily Operatable Scanning Tunneling Microscope, Surface Science, 181, 145-153, 1987. [6]. Chunli, B., Gerhard, E., Robert, G., Hans, L., Douglas, L.M., Scanning Tunneling Microscopy and Its Applications, Shanghai, Shanghai Scientific and Technical Publishers, 1992. [7]. Hablanian, M.H., High-Vacuum Technology, APractical Guide, New York: Marcel Dekker, Inc, 1997. [8]. Karl., J., Handbook of Vacuum Technology, Wemheim: Verlag GmbH Co., 2008. [9]. F.O'Hanlon, John. A User's Guide to Vacuum Technolog, New Jersey: John Wiley&Sons, Inc., 2003. [10]. Hla, S-W, Bartels, L., Meyer, G. and Reider K.-H., Inducing All Steps of a Chemical Reaction with the Scanning Tunneling Microscope Tip: Towards Single Molecule Engineering, Phys. Rev. Lett. 85, 2777-2780, 2000. [11]. Hla, S-W, Scanning Tunneling Microscopy Single Atom/Molecule Manipulation and Its Application to Nanoscience and Technology, J Vac. Sci Tech B, 23,1251-1360, 2005. [12]. Eigler, D.M., Schweizer, E.K. Positioning Single Atoms with A Scanning Tunneling Microscope, Nature 344, 524-526,1990. [13]. Shen,T.C. Atomic-Scale Desorption Through Electronic and Vibrational Excitation Mechanism,,Science, 268, 1590-1592, 1995. [14]. Nilius, N., Wallis, T.M., Ho, W., Development of One-Dimensional Band Structure in Artifical Gold Chains, Science, 297, 1853-1856, 2002. [15]. Vacancy scanning tunneling spectroscopy on Ag (111), Poster Presentation, APS March meeting Baltimore, US A, 2006. [16]. Noriaki Takagi, C-L.L., Tsukahara, N., Kawai, M., Arafune, R. Silicene on Ag(lll): Geometric and Electronic Structures of a New Honeycomb Material of Si, Progress in Surface Science, 1-20, 2015. [17]. Seymur Cahangirov, V.O., Atomic Structure of the V3 x V3 Phase of Silicene on Ag(lll), Physical Review B, 1-5, 2014. [18]. Wu, K., Persistent Dirac Fermion State in a Silicon-based Material, Program of the 4th ICQs Conference on Spintronics, Beijing, 15, 2014.
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Details

Journal Section Research Article
Authors

Asim Mantarcı

Publication Date December 1, 2014
Published in Issue Year 2014 Volume: 2 Issue: 2

Cite

APA Mantarcı, A. (2014). Low temperature scanning tunneling microscopy (LT-STM), Ag (111) surface. Mus Alparslan University Journal of Science, 2(2), 236-245.
AMA Mantarcı A. Low temperature scanning tunneling microscopy (LT-STM), Ag (111) surface. MAUN Fen Bil. Dergi. December 2014;2(2):236-245.
Chicago Mantarcı, Asim. “Low Temperature Scanning Tunneling Microscopy (LT-STM), Ag (111) Surface”. Mus Alparslan University Journal of Science 2, no. 2 (December 2014): 236-45.
EndNote Mantarcı A (December 1, 2014) Low temperature scanning tunneling microscopy (LT-STM), Ag (111) surface. Mus Alparslan University Journal of Science 2 2 236–245.
IEEE A. Mantarcı, “Low temperature scanning tunneling microscopy (LT-STM), Ag (111) surface”, MAUN Fen Bil. Dergi., vol. 2, no. 2, pp. 236–245, 2014.
ISNAD Mantarcı, Asim. “Low Temperature Scanning Tunneling Microscopy (LT-STM), Ag (111) Surface”. Mus Alparslan University Journal of Science 2/2 (December 2014), 236-245.
JAMA Mantarcı A. Low temperature scanning tunneling microscopy (LT-STM), Ag (111) surface. MAUN Fen Bil. Dergi. 2014;2:236–245.
MLA Mantarcı, Asim. “Low Temperature Scanning Tunneling Microscopy (LT-STM), Ag (111) Surface”. Mus Alparslan University Journal of Science, vol. 2, no. 2, 2014, pp. 236-45.
Vancouver Mantarcı A. Low temperature scanning tunneling microscopy (LT-STM), Ag (111) surface. MAUN Fen Bil. Dergi. 2014;2(2):236-45.