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Research Article | | Peer-Reviewed

Biogenically Synthesized ZnO and Cu-Doped ZnO Nanoparticles: Effect of Cu-Dopent Concentration and Annealing on Morphology and Optical Properties

Parameswaran Parlikad Subramanian* Rethikala Pandikkappallil Kumaran Manoj Nageri
Published in American Journal of Nano Research and Applications (Volume 12, Issue 1)
Received: 23 June 2024     Accepted: 11 July 2024     Published: 29 July 2024
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Abstract

In this work, ZnO nanoparticles and Cu-doped ZnO nanoparticles were biogenically synthesized using precipitation method in Cissus quadrangularis plant extract medium. The influence of Cu dopant on the crystalline structure, optical properties, and morphology of ZnO was investigated. The samples were characterized by XRD, FTIR, UV–vis spectroscopy and SEM. XRD patterns confirmed the wurtzite formation of doped and undoped ZnO nanoparticles. The average crystallite size of the neat and Cu-doped samples was ~18 nm irrespective of the amount of dopant. The annealing process enhanced the size of both the neat and Cu-doped samples. However, the influence on the size is less prominent in the Cu-doped sample than in the neat sample. The UV-visible spectral analysis shows that all the synthesized doped and undoped nano zinc oxides absorb at ~400nm. The band gap energy of Cu-doped ZnO particles was greater for unannealed samples whereas it was appreciably lowered on annealing for Cu-doped samples. SEM analysis shows rod-like morphology for the unannealed and annealed undoped zinc oxides. It is changed to flower-like morphology with the addition of 5mM Cu2+ and then to nano sheet-like structure with the incorporation of higher amount of Cu2+ ions. Annealing of zinc oxide samples leads to the smoothening of the surfaces with a change in morphology for the ZnO nanoparticles.

Published in American Journal of Nano Research and Applications (Volume 12, Issue 1)
DOI 10.11648/j.nano.20241201.12
Page(s) 15-22
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

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Copyright © The Author(s), 2024. Published by Science Publishing Group
Previous article
Keywords

Green Synthesis, Nano Zinc Oxide, Cissus quadrangularis

1. Introduction
Zinc oxide (ZnO) is a typical electronic and photonic wurtzite n-type semiconductor with a wide direct band gap of 3.37eV and a high exciton binding energy (60 meV) at room temperature
[1]
. Its excellent properties as a semiconductor material like high electron mobility, high thermal conductivity, good transparency, wide direct band gap (3.37eV), large exciton binding energy and easiness of growing in the nanostructure form, make ZnO suitable for applications such as nanogenerators, gas sensors, biosensors, solar cells, varistors, photodetectors and photocatalysts
[2-4]
.
ZnO is an interesting semiconductor material having a Hexagonal Close Packing (hcp) lattice with empty octahedral sites. Plenty of sites available in ZnO can be accommodated by intrinsic defects and extrinsic dopants
[5]
. Doping of selective elements in ZnO nanoparticles is an effective way to modify or tune the optical, electrical, magnetic and catalytic properties of ZnO. The optical properties of ZnO nanoparticles can be tuned by incorporating various ions such as alkaline earth metal ions, transition metal ions and rare earth metal ions into the crystal lattice
[6, 7]
. Copper is used as the dopant, since high conductivity, cheap and availablility on Earth’s crust. Copper has a similar electronic shell structure with zinc and possesses high solubility in ZnO. Cu could produce p-type ZnO by introducing an acceptor energy level in ZnO with energy 0.45 eV above the valence band
[8]
. The doping of Cu in ZnO is expected to modify absorption, and other physical or chemical properties of ZnO
[8, 9]
. Doping of ZnO with copper was intended to enhance the surface defects of ZnO. These can subsequently be used as efficient centres for optical absorption.
Various approaches for the preparation of ZnO nanoparticles (ZnONP) have been developed, namely, sol-gel, microemulsion, thermal decomposition of organic precursor, spray pyrolysis, electrodeposition, ultrasonic, microwave-assisted techniques, chemical vapour deposition and hydrothermal and precipitation methods
[10, 11]
. However, biological methods for the synthesis of ZnONP using microorganisms, enzymes, and plant extracts have been suggested as possible eco-friendly alternatives to chemical and physical methods
 [12-15]
.
Across the tropical world, Cissus quadrangularis is a perennial herb with therapeutic qualities. In India, it is one of the most widely utilized medicinal plants. The plant is said to be indigenous to West Africa, Java, Malaysia, Sri Lanka, and India. Cissus quadrangularis can used for treating diabetes, obesity, high cholesterol, bone fractures, allergies, cancer, stomach upset, painful menstrual periods, asthma, malaria, wound healing, peptic ulcer disease, osteoporosis and as an anabolic steroid
[16]
.
This work aims at the synthesis of ZnONP and Copper doped (Cu-doped) ZnONP samples with varying amounts of dopant, via the precipitation method using Cissus quadrangularis plant extract and compare the optical and the morphological features of the synthesized ZnONP samples.
2. Materials and Methods
Zinc nitrate hexahydrate, Copper sulphate pentahydrate and Sodium Hydroxide were used in the experiments. All the AR grade chemicals used were obtained from E. Merck (Mumbai, India) and were applied without more purification. Deionized water is used for the preparation of solutions and Cissus quadrangularis plants were collected from Sanatana Dharma College Campus, Alappuzha, Kerala.
2.1. Preparation of Cissus quadrangularis Plant Extract
Fresh Cissus quadrangularis plants were collected. Washed thoroughly with water to remove the impurities. About 5g of sliced stem was taken in a 250 mL glass beaker with 100 mL distilled water. The mixture was then heated at 60ºC for a few minutes until the aqueous solution changed from watery to light greenish yellow. The extract was then cooled to room temperature and filtered using whatmann no: 1 filter paper.
2.2. Synthesis of ZnO Nanoparticles
Synthesis of ZnONPs in green medium (ZnONPG): 250 ml 0.05M Zinc Nitrate hexahydrate solution was taken in a 500ml beaker. 2ml aqueous extract of the Cissus quadrangularis plant was introduced into it. 1.0M NaOH solution was added at room temperature drop by drop to reach pH 12 (~20ml NaOH solution), with constant stirring. After the addition, it was stirred for about 2 hours. After completion of the reaction, the white precipitate formed was washed thoroughly with distilled water followed by ethanol to remove impurities. The precipitate was then dried in a hot air oven for 6 hours at 100ºC.
Synthesis of Cu-doped ZnONPs in green medium (ZnONPGCu): Various concentrations of zinc nitrate and copper sulphate i.e, 0.0450M Zn(NO3)2 & 0.0050M(5mM) CuSO4;0.0425M Zn(NO3)2 & 0.0075M(7.5mM) CuSO4 and finally 0.04M Zn(NO3)2 & 0.01M(10mM) CuSO4 in 250ml water were taken for the synthesis of Cu-doped ZnO samples. The method used above was adopted to synthesis Cu-doped ZnONPs Each sample was designated as ZnONPGCu(5), ZnONPGCu(7.5) and ZnONPGCu(10) respectively.
The synthesized samples were annealed at 350ºC and 700ºC for 2 hours. These samples were designated as ZnONPG350, ZnONPG700, ZnONPGCu(5)350, ZnONPGCu(5)700, ZnONPGCu(7.5)350, ZnONPGCu(7.5)700, ZnONPGCu(10)350 and ZnONPGCu(10)700.
2.3. Characterization Methods
Scanning electron microscopy: VEGA3 TESCAN analyzer with acceleration voltage 10 KV was used to take the images of biosynthesized zinc oxide nanoparticles.
X-Ray Diffractogram: Analysis of the synthesized zinc oxide nanoparticles is carried out using X-Ray Diffractometer - Bruker AXS D8 Advance, with Cu k-alpha radiation of wavelength 1.5402 Aº.
UV-vis spectral analysis: UV-visible analysis of the samples was done using a UV 2600 Shimadzu instrument.
FTIR: FTIR spectra of ZnONP samples were taken in Thermo Nicolet Avatar 370 FTIR spectrophotometer (spectral range 4000-400 cm-1 with KBr beam splitter)
3. Results and Discussion
3.1. Solubility
Figure 1 shows the solubility of ZnONPG and Cu-doped sample in Dimethylsulphoxide (DMSO). The image shows that ZnONPG is soluble in DMSO while the Cu-doped sample is partially soluble. The presence of copper in zinc oxide makes it partially insoluble.
Figure 1. Solubility of ZnONPG and ZnONPGCu(5) in DMSO.
3.2. FT-IR Spectroscopy
Figure 2. represents the FTIR spectra of ZnONPG and ZnONPGCu(7.5). Both the samples show peaks at ~434 cm-1. This is due to the Zn-O stretching. The absorption peak at ~1380 cm- 1 corresponds to H-O-H vibrations and the band observed at ~860 cm- 1 can be attributed to the bending vibrational modes (wagging, twisting and rocking) of coordinated water molecules.
Figure 2. FTIR spectra of ZnONPG & ZnONPGCu(7.5).
3.3. UV-vis Spectroscopy
The UV-vis absorption spectra of the samples are recorded in the wavelength range of 200 to 750 nm. The UV-vis spectra of samples are shown in Figure 3.
Figure 3. UV-vis spectra of ZnONPG and Cu-doped unannealed and annealed samples.
All the samples have strong absorption below 400 nm. It can be seen that a slight blue shift is observed in Cu-doped nano zinc oxides. The optical band gap of the nanocrystals can be obtained by analyzing the adsorption edges and by applying the Tauc model
[17]
represented by the following relation (1):
αhυ = B(hυ-Eg)1/2(1)
where h is Planck’s constant, υ is the frequency of incident photons, and B is a constant that depends on the electron-hole mobility.
Figure 4 shows the plots of (αhυ)2 as a function of the photon energy for the prepared ZnO samples. The band gap energy is obtained by extrapolating the straight line portion of the plot to zero absorption coefficient. In the case of nonannealed samples, the band gap energy values are enhanced on Cu doping. But the band gap energy values of the samples are reduced to a greater extent on annealing as can be seen from the figures.
Figure 4. Tauc plot for band gap determination of ZnONPG and ZnONPGCus.
The band gap energy values of the samples from the extrapolation of the straight line portion are shown in Table 1.
Table 1. Band gap energy of synthesized samples.

Samples

Band gap of unannealed samples (eV)

Band gap of samples annealed at 350°C (eV)

Band gap of samples annealed at 700°C (eV)

ZnONPG

3.230

3.231

3.248

ZnONPGCu(5)

3.241

3.228

3.189

ZnONPGCu(7.5)

3.258

3.175

3.182

ZnONPGCu(10)

3.231

3.151

3.157
The band gap energies are in good agreement with the reported values
[18]
. The unannealed Cu-doped ZnO samples show a slight increase in the band gap energy values compared to the neat sample. But on annealing, it can be seen that band gap energies for the Cu-doped samples are decreased appreciably compared to ZnONPG. The annealing influence on band gap energy is not seen in the ZnONPG. The Cu-doped ZnO samples exhibit prominent decrease in the band gap energy. The magnitude of the decrease in band gap energy increases with the increase in concentration of Cu. However, the samples annealed at 350°C and 700°C do not show any marginal difference. The decrease in the band gap energy may be due to the increase in the grain size. When the grain size increases, the band gap energy is found to be decreased, which is due to the quantum confinement
[19]
. At high temperatures, the grain size of the nanoparticles is increased as is evident from the XRD studies.
3.4. XRD Analysis
Figure 5 represents the XRD patterns of ZnONPG, Cu-doped nano zinc oxides, synthesized by varying concentrations of Zn2+ ions and Cu2+ ions in the presence of plant extract, and samples annealed at 700ºC. The diffraction peaks at scattering angles ~ 31.80º, 34.40º, 36.30º, 47.50º, 56.50º, 62.70º and 67.90º correspond to the reflections from (100), (002), (101), (102), (110), (103) and (112) crystal planes respectively. Well-crystallized diffraction peaks are observed from the XRD pattern. The XRD pattern of all annealed samples is almost similar. It can be seen that the annealed samples contain an additional peak at 38.67º. Nano CuO particles show a strong peak at ~38.60º. This indicates a heterophase formation on annealing. The absence of this peak in unannealed samples may be due to the complexation of some of the Cu2+ with phytochemicals present in the plant extract. But on annealing these complexes might have decomposed to CuO.
Figure 5. XRD patterns of ZnONPG and Cu-doped ZnONPGs.
The average crystallite size is calculated from the Debye Scherrer formula and Table 2 shows the average crystallite size of ZnONPG and all Cu-doped nano zinc oxide samples prepared and annealed at 700°C. The average crystallite size is calculated from the intense peaks of XRD data.
Table 2. Crystallite size of unannealed and annealed samples.

Sample

Particle size (nm) unannealed

Particle size (nm) annealed at 700°C

ZnONPG

17.77

23.48

ZnONPGCu(5)

17.53

22.23

ZnONPGCu(7.5)

18.75

19.26

ZnONPGCu(10)

17.95

21.02
From Table 2, it can be seen that the particle size is not appreciably changed when copper is doped in ZnO. However, the samples annealed at 700°C show an increase in grain size. On comparing the particle size of each sample at both conditions, the % increase in particle size is greater for the neat sample compared to Cu-doped samples. The optical band gap of the ZnO samples was blue-shifted with temperatures showing particle size growth.
The lattice constants ‘a’ and ‘c’ of the wurtzite structure of ZnO can be calculated using the relations (2) and (3) given below
a=λ/√3sinθ100(2)
c = λ/sinθ002(3)
where λ = 1.5402 A0 is the wavelength of X-ray radiation used, dhkl is the crystalline surface distance for hkl indices, θ100 and θ002 are the angles of diffraction peaks (100) and (002) respectively. The unit cell volume for hexagonal structure can be calculated by the relation (4).
v = a2c sin 60º= √3 a2c / 2(4)
Table 3. Lattice parameters of various Cu-doped nano zinc oxide samples prepared.

Sample

a (A0)

c (A0)

Unit volume, v (A0)3

ZnONPG

3.266

5.211

48.136

ZnONPGCu(5)

3.279

5.242

48.809

ZnONPGCu(7.5)

3.257

5.223

47.981

ZnONPGCu(10)

3.293

5.264

49.433
The calculated lattice parameters are given in Tables 3 and 4. The evaluated lattice parameters of the samples, from XRD data, are in good agreement with those reported in JCPDS 36-1451 (‘a’ = 3.249 A0, ‘c’ = 5.206 A0 and ‘v’ = 47.62 (A0)3). The slight increase in lattice parameters on doping of Cu2+ may be due to the non-uniform substitution of Cu2+ ions into Zn2+ lattice site even though the ionic radius of Cu2+ and Zn2+ ions are almost similar i.e.7.3 nm & 7.4 nm respectively. Both the doping of Cu to ZnO and the annealing process have not produced any change in the lattice parameters of the ZnO. This indicates the same wurtize structure is retained under these conditions.
Table 4. Lattice parameters of Cu-doped nano zinc oxide samples annealed at 700°C.

Sample

a (A0)

c (A0)

Unit volume, v (A0)3

ZnONPG700

3.264

5.222

48.179

ZnONPGCu(5)700

3.268

5.226

48.334

ZnONPGCu(7.5)700

3.265

5.223

48.217

ZnONPGCu(10)700

3.269

5.227

48.373
3.5. SEM Characterization
Figure 6 depicts the SEM images of unannealed samples and samples annealed at 700ºC.
Figure 6. SEM images of unannealed and annealed ZnO samples: (a) ZnONPG (b) ZnONPGCu(5) (c) ZnONPGCu(10) (d) ZnONPG700 (e) ZnONPGCu(5)700 (f) ZnO NPGCu(10)700.
The unannealed green synthesized zinc oxide, ZnONPG, contains randomly oriented clustered rod-like structure nanoparticles. The annealing leads to the separation of clustered nanoparticles and the rod-like structure becomes more visible. The morphological features of Cu-doped ZnONPG samples are entirely different from that of neat ZnONPG. The SEM picture of ZnONPGCu(5) shows the presence of nanosheets and these are oriented randomly. This is very clear in the annealed sample and has a flower-like ZnO architecture. Flower has a diameter of ~2 µm and consists of a large number of nanosheets, which are spokewise, projected from a common central zone. The surface morphology ZnONPGCu(10) indicates that the surface is very rough and has nanosheets. This indicates that Cu-doped nano ZnO may be used as a photocatalyst due to greater surface area. The flower-like morphology and sheet-like morphology are clearer in the annealed nano ZnO samples doped with Cu. Thus, it is understood that Cu dopant influences the morphological features of the zinc oxide nanoparticles.
4. Conclusion
ZnONP was synthesized by green method in the presence of Cissus quadrangularis plant extract. Cu-doped nano zinc oxides were also synthesized in the plant extract medium by varying the concentration of Zn2 + and Cu2+ solutions. FTIR confirms the formation of ZnO particles from its characteristic absorption peak of Zn-O stretching at ~434 cm-1. ZnONPG and all Cu-doped samples show strong absorption in the UV range, at ~400 nm. The optical band gap increases on Cu doping in unannealed samples. On annealing the band gap value decreases with increase in the amount of Cu doping. The green synthesized ZnO samples are crystalline and the particles are in nano regime as indicated by XRD studies. The particle size of ZnONPG and Cu-doped samples is increased on annealing. A slight increase in unit volume reveals the doping of Cu2+ ions to the Zn2+ lattice site. The SEM images show that the temperature and Cu-doping alter the morphology of the ZnO nanoparticles.
Abbreviations

ZnO

Zinc Oxide

ZnONP

Zinc Oxide Nanoparticle

ZnONPG

Zinc Oxide Nanoparticle Green

ZnONPGCu

Zinc Oxide Nanoparticle Green Copper Doped

XRD

X-ray Diffraction

FTIR

Fourier-Transform Infrared Spectroscopy

UV–vis Spectroscopy

Ultraviolet-visible Spectroscopy

SEM

Scanning Electron Microscopy

DMSO

Dimethyl Sulphoxide

CuO

Cupric Oxide
Acknowledgments
The authors acknowledge the DST, Government of India for the instrumentation facilities provided under the FIST scheme (SR/FIST/College-238/2014(c)).
Author Contributions
Parameswaran Parlikad Subramanian: Conceptualization, Investigation, Methodology, Resources, Writing – review & editing
Rethikala Pandikkappallil Kumaran: Data curation, Formal Analysis, Methodology, Validation, Writing – original draft
Manoj Nageri.: Formal Analysis, Methodology, Software, Writing – original draft
Conflicts of Interest
The authors declare no conflicts of interest.
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    Subramanian, P. P., Kumaran, R. P., Nageri, M. (2024). Biogenically Synthesized ZnO and Cu-Doped ZnO Nanoparticles: Effect of Cu-Dopent Concentration and Annealing on Morphology and Optical Properties. American Journal of Nano Research and Applications, 12(1), 15-22. https://doi.org/10.11648/j.nano.20241201.12

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    Subramanian, P. P.; Kumaran, R. P.; Nageri, M. Biogenically Synthesized ZnO and Cu-Doped ZnO Nanoparticles: Effect of Cu-Dopent Concentration and Annealing on Morphology and Optical Properties. Am. J. Nano Res. Appl. 2024, 12(1), 15-22. doi: 10.11648/j.nano.20241201.12

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    Subramanian PP, Kumaran RP, Nageri M. Biogenically Synthesized ZnO and Cu-Doped ZnO Nanoparticles: Effect of Cu-Dopent Concentration and Annealing on Morphology and Optical Properties. Am J Nano Res Appl. 2024;12(1):15-22. doi: 10.11648/j.nano.20241201.12

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  • @article{10.11648/j.nano.20241201.12,
  author = {Parameswaran Parlikad Subramanian and Rethikala Pandikkappallil Kumaran and Manoj Nageri},
  title = {Biogenically Synthesized ZnO and Cu-Doped ZnO Nanoparticles: Effect of Cu-Dopent Concentration and Annealing on Morphology and Optical Properties
},
  journal = {American Journal of Nano Research and Applications},
  volume = {12},
  number = {1},
  pages = {15-22},
  doi = {10.11648/j.nano.20241201.12},
  url = {https://doi.org/10.11648/j.nano.20241201.12},
  eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.nano.20241201.12},
  abstract = {In this work, ZnO nanoparticles and Cu-doped ZnO nanoparticles were biogenically synthesized using precipitation method in Cissus quadrangularis plant extract medium. The influence of Cu dopant on the crystalline structure, optical properties, and morphology of ZnO was investigated. The samples were characterized by XRD, FTIR, UV–vis spectroscopy and SEM. XRD patterns confirmed the wurtzite formation of doped and undoped ZnO nanoparticles. The average crystallite size of the neat and Cu-doped samples was ~18 nm irrespective of the amount of dopant. The annealing process enhanced the size of both the neat and Cu-doped samples. However, the influence on the size is less prominent in the Cu-doped sample than in the neat sample. The UV-visible spectral analysis shows that all the synthesized doped and undoped nano zinc oxides absorb at ~400nm. The band gap energy of Cu-doped ZnO particles was greater for unannealed samples whereas it was appreciably lowered on annealing for Cu-doped samples. SEM analysis shows rod-like morphology for the unannealed and annealed undoped zinc oxides. It is changed to flower-like morphology with the addition of 5mM Cu2+ and then to nano sheet-like structure with the incorporation of higher amount of Cu2+ ions. Annealing of zinc oxide samples leads to the smoothening of the surfaces with a change in morphology for the ZnO nanoparticles.
},
 year = {2024}
}

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  • TY  - JOUR
T1  - Biogenically Synthesized ZnO and Cu-Doped ZnO Nanoparticles: Effect of Cu-Dopent Concentration and Annealing on Morphology and Optical Properties

AU  - Parameswaran Parlikad Subramanian
AU  - Rethikala Pandikkappallil Kumaran
AU  - Manoj Nageri
Y1  - 2024/07/29
PY  - 2024
N1  - https://doi.org/10.11648/j.nano.20241201.12
DO  - 10.11648/j.nano.20241201.12
T2  - American Journal of Nano Research and Applications
JF  - American Journal of Nano Research and Applications
JO  - American Journal of Nano Research and Applications
SP  - 15
EP  - 22
PB  - Science Publishing Group
SN  - 2575-3738
UR  - https://doi.org/10.11648/j.nano.20241201.12
AB  - In this work, ZnO nanoparticles and Cu-doped ZnO nanoparticles were biogenically synthesized using precipitation method in Cissus quadrangularis plant extract medium. The influence of Cu dopant on the crystalline structure, optical properties, and morphology of ZnO was investigated. The samples were characterized by XRD, FTIR, UV–vis spectroscopy and SEM. XRD patterns confirmed the wurtzite formation of doped and undoped ZnO nanoparticles. The average crystallite size of the neat and Cu-doped samples was ~18 nm irrespective of the amount of dopant. The annealing process enhanced the size of both the neat and Cu-doped samples. However, the influence on the size is less prominent in the Cu-doped sample than in the neat sample. The UV-visible spectral analysis shows that all the synthesized doped and undoped nano zinc oxides absorb at ~400nm. The band gap energy of Cu-doped ZnO particles was greater for unannealed samples whereas it was appreciably lowered on annealing for Cu-doped samples. SEM analysis shows rod-like morphology for the unannealed and annealed undoped zinc oxides. It is changed to flower-like morphology with the addition of 5mM Cu2+ and then to nano sheet-like structure with the incorporation of higher amount of Cu2+ ions. Annealing of zinc oxide samples leads to the smoothening of the surfaces with a change in morphology for the ZnO nanoparticles.

VL  - 12
IS  - 1
ER  -

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