An investigation of the morphology, structure, composition and optical properties of ZnS:Mn2+ microbelts grown by the thermal evaporation method using ZnS powder and powder as precursor materials is presented. The SEM images of the products show that ZnS:Mn2+ microbelts are bigger and shorter than ZnS microbelts. EDS reveals that the composition of the microbelts include Zn, S, O, Mn and Cl elements. | VNU Journal of Science: Mathematics – Physics, Vol. 34, No. 1 (2018) 8-13 Blue, Green and Yellow Emissions at the Same Time from Mn-doped ZnS Microbelts Nguyen Van Nghia1,2,*, Nguyen Duy Hung1 1 Advanced Institute of Science and Technology (AIST), Hanoi University of Science and Technology (HUST), 01 Dai Co Viet, Hanoi, Vietnam 2 Thuy Loi University, 175 Tay Son, Dong Da, Hanoi, Vietnam Received 23 July 2017 Revised 22 September 2017; Accepted 27 September 2017 Abstract: An investigation of the morphology, structure, composition and optical properties of ZnS:Mn2+ microbelts grown by the thermal evaporation method using ZnS powder and powder as precursor materials is presented. The SEM images of the products show that ZnS:Mn2+ microbelts are bigger and shorter than ZnS microbelts. EDS reveals that the composition of the microbelts include Zn, S, O, Mn and Cl elements. The atom rate of oxygen composition of the doped microbelts seem to be slightly lower than undoped ones. XRD pattern of the prepared microbelts shows that ZnO coexists with ZnS on the undoped microbelts. However, at the Mn-doped microbelts, the component phase of ZnO is disappeared. Photoluminescence spectra of undoped ZnS microbelts reveal a strong broad emission band at visible wavelength region and a weak ultraviolet band. Interestingly, when Mn2+ is doped into the microbelts, the visible emission band is separated into blue, green, and yellow bands peaking at around 442, 520 nm, and 572 nm, respectively. The effects of Mn2+ ions on the emission bands is discussed in detail. Keywords: ZnS :Mn2+ microbelts, photoluminescence, thermal evaporation. 1. Introduction ZnS, an II–VI semiconductor, has been extensively investigated due to its potential applications in optics, photoelectronics, sensors, catalysts and so on [1–3]. Recently, numerous efforts have been employed to control the fabrication of micro and nanomaterials with various morphologies, since the novel properties and .