Sains Malaysiana 49(8)(2020): 1875-1890

http://dx.doi.org/10.17576/jsm-2020-4908-10

 

Opto-Electrical Investigation of Zn Metal-Doped Cds and Their Application in Soft Lithographic Technique

(Kajian Opto-Elektrik ke atas Zn Logam-terdop Cd dan Aplikasinya dalam Teknik Litografi Lembut)

 

GULALAI HUSSAIN1, UZMA JABEEN1*, IRFAN HAFEEZ2, M NAJAM KHAN MALGHANI3, AYESHA MUSHTAQ1*, SABEENA RIZWAN1, FARRUKH BASHIR1, FARIDA BEHLIL1, M AAMIR RAZA2 & SHAISTA ANJUM4

 

1Faculty of Basic Sciences, SBK Women’s University Quetta, 87300, Pakistan

 

2Pakistan Council of Scientific and Industrial Research, Pakistan

 

3Faculty of Engineering and Architecture, Takatu campus BUITEMS Quetta, Pakistan

 

4Faculty of Life Sciences, University of Balochistan, Quetta, Pakistan

 

Diserahkan: 12 Oktober 2019/Diterima: 26 Mac 2020

 

ABSTRACT

Un-doped CdS and Zn metal-doped CdS (0.1-0.5 M) were synthesized by chemical precipitation method. Properties like optical band gap and conductivity were determined by different characterization techniques. UV-Visible spectroscopy was applied to estimate the band gap where it showed a significant blue shift due to quantum confinement effect. Size determined by scanning electron microscopy (SEM) was found to be in nanorange from 41 to 60 nm for both un-doped and metal doped CdS nanocrystals. EDAX confirmed the doping by showing peak for Zn. XRD (X-ray diffraction) showed the lattice structure to be cubic for the synthesized nanoparticles and conductivity for un-doped CdS was 7.69E-6 Ω-1m-1 where it changes to 9.25E-6 Ω-1m-1 and 7.98E-6 Ω-1m-1 for 0.2 M and 0.5 M Zn-doped CdS, respectively. In order to obtain good results, nanocrystals having highest conductivity are used in soft lithographic technique. Here µTM (micro transfer-molding) was followed for patterning with PDMS (poly-(dimethylsiloxane)) mold and silicon substrate for better results.

 

Keywords: Band gap; blue shift; conductivity; lithography; Zn dopant

 

ABSTRAK

CdS yang tidak terdop dan Zn logam-terdop (0.1-0.5M) disintesis dengan kaedah pemendakan kimia. Sifat seperti jurang jalur optik dan kekonduksian ditentukan oleh teknik pencirian yang berbeza. Spektroskopi Terlihat UV diterapkan untuk menganggarkan jurang jalur yang menunjukkan peralihan warna biru yang ketara kerana kesan pengurungan kuantum. Ukuran yang ditentukan oleh mikroskopi elektron pengimbasan (SEM) didapati berada dalam jarak nano dari 41 hingga 60 nm untuk kristal nano CdS yang tidak dilekatkan dan logam. EDAX mengesahkan pendopan dengan menunjukkan puncak untuk Zn. XRD (difraksi sinar-X) menunjukkan struktur kisi menjadi kubik bagi zarah nanopartesis yang disintesis dan kekonduksian untuk CdS tanpa pendopan adalah 7.69E-6 Ω-1m-1 dan ia berubah menjadi 9.25E-6 Ω-1m-1 dan 7.98E-6 Ω-1m-1 masing-masing untuk 0.2 M dan 0.5 M Zn-terdop CdS. Untuk memperoleh hasil yang baik, kristal nano yang mempunyai kekonduksian tertinggi digunakan dalam teknik litografi lembut. Di sini µTM (acuan pemindahan mikro) dilakukan untuk membuat corak dengan substrat acuan dan silikon PDMS (poli- (dimetilsiloksana)) untuk hasil yang lebih baik.

 

Kata kunci: Jurang jalur; kekonduksian; litografi; peralihan biru; Zn dopan

 

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*Pengarang untuk surat-menyurat; email: roha64@yahoo.com

   

 

 

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