Biotemplated Synthesis of Titanium Oxide Nanoparticles in the Presence of Root Extract of Kniphofia schemperi and Its Application for Dye Sensitized Solar Cells

Metal oxide nanoparticles prepared by biological route using green plant parts as a template are eco-friendly as well as yield good results than the conventional methods. This present study focusses on biosynthesis and characterization of TiO2 NPs using root extract of Kniphofia schemperi for dye-sensitized solar cells. TiO2 NPs were synthesized using 0.25M titanium tetra butoxide in the presence of root extract of Kniphofia schemperi with the volume ratios. The analysis result revealed that the synthesized TiO2 NPs were thermally stable above 500 °C and have spherical morphology, with the average crystalline size of 11.7, 8.3, and 8.6 nm, and band gap energy of 3.35 eV, 3.33 eV, and 3.36 eV, respectively, for the TiO2 NPs prepared at the volume ratios of 2 : 3, 1 : 1, and 3 : 2. Biosynthesized TiO2 NPs were used as photoanode in dye-sensitized solar cells (a device used for converting absorbed light into electricity). Solar cell devices were fabricated using roots of Kniphofia schemperi sensitizer in the presence of TiO2 NPs biosynthesized within (2 : 3, 1 : 1, and 3 : 2) volume ratio, which showed power conversion efficiency of 0.039%, 0.117%, and 1.3%. Incident photon to current conversion efficiency (IPCE) analysis using TiO2 (2 : 3, 1 : 1, and 3 : 2) photoelectrodes showed 6.64%, 2.66%, and 18%. Among the biosynthesized TiO2 different volume ratios, TiO2 (3 : 2) NPs showed relatively maximum solar cell efficiency and IPCE value due to its uniform spherical shape that enables to absorb large dye molecules on its surface, and this intern improves device efficiency.


Introduction
Energy exists in different forms from burning woods to obtain fire in prehistoric times to electricity productions in the modern age. Its consumption is one of the most important aspects in everyday life activities of human beings. However, the original sources of energy that peoples used to harvest have shown signs of deficiency due to the rapid growth in industrialization in many countries. As a result, increasing concerns about energy crisis, climate change, shortage in fossil fuels, and environmental issues are motivating the researcher to develop clean, sustainable, and renewable energy resources that will power the future [1].
Recent advances in solar energy conversion technologies based on organic semiconductors as light harvesting layer employ metallic oxide semiconductor (MOS) nanostructures for efficient charge extraction and transportation between the electrode and organic molecules [2]. Solar cells based on dye-sensitized and porous nanocrystalline TiO 2 photoanode with attractive performance were first reported in 1991 [3]. Dye-sensitized solar cell (DSSC) is a low-cost cell and belongs to the group of thin film solar cells. The interconnected TiO 2 NP in DSSCs has been widely used as the mesoporous electrode film layer, because it is beneficial for light adsorption with a large amount of dye molecules due to its large surface areas [4]. TiO 2 NPs have been routinely synthesized by several approaches such as hydrothermal, solvothermal, sol-gel, direct oxidation, chemical vapor deposition, electro-deposition, sonochemical, chemical bath deposition, and microwave methods [5]. However, these methods are costly, toxic, not friendly to the natural ecosystem. Nowadays, there is an increased demand to develop TiO 2 with high yielding, low cost, and nontoxicity by exploring with biological sources and eco-friendly methods. The biological method involves the use of environment-friendly materials such as plant extracts (leave, flower, bark, root, seed, and peels), bacteria, fungi, and enzymes in the synthesis of titanium dioxide nanoparticles together with the use of green solvents [6].
The species Kniphofia are herbaceous perennials growing from rhizomes. Kniphofia schemperi is also known as Kniphofia schemperi baker; its root has been traditionally applied for the treatment of various diseases such as menstrual pains, abdominal cramps, intestinal tape worm, wounds, dysmenorrheal, bacterial, and fungal infections, malaria, chest complaint, and gonorrhea, and hepatitis B [7]. Furthermore, the presence of various functional groups within the root extract of Kniphofia schemperi such as flavonoids, carbonyl groups, carboxylic acids, ketones, and phenols could be used for the synthesis of TiO 2 nanoparticles in order to avoid the use of toxic and expensive chemical species for the synthesis process. The root extract of the plant with same family name, Kniphofia foliosa, has been used for synthesis of TiO 2 NPs for antibacterial activity by Eneyew et al. [8]. And under this work, the root extract of Kniphofia schemperi was investigated as a template for the synthesis of TiO 2 NPs and also could be used as a natural sensitizer for solar cell application.
DSSCs using inorganic complex dyes and commercially available and chemically synthesized TiO 2 NPs have been explored and its corresponding performance is also measured. But titanium oxide nanoparticles are not produced using a biosynthesized and eco-friendly method for DSSCs applications as photoanode using root extract of Kniphofia schemperi [9]. To the knowledge of different researchers, green synthesis of TiO 2 NPs using indigenous medicinal plant extract from the root of Kniphofia schemperi for DSSCs application is not done yet. Therefore, the focus of the current work was biosynthesis of TiO 2 NPs in different volume ratios using titanium tetra butoxide and Kniphofia schemperi root extract as a reducing and capping agent and then to fabricate DSSCs using sensitizers obtained from root of Kniphofia schemperi. In the present findings, the root extract of Kniphofia schemperi was played two roles, in one case used as a capping and reducing agent for TiO 2 biosynthesis, and in the second case, it was used as a sensitizer during photoanode preparation to coat the prepared film.
2.2. Extraction of Root of Kniphofia schemperi. Healthy and fresh roots of Kniphofia schemperi were collected and cleaned using distilled water several times and were dried in a shaded room till all the moisture content of the roots were removed. The dried Kniphofia schemperi root was ground using plant grinding machine. The extraction process was performed by mixing 15 grams of powder of the root with 250 mL of absolute ethanol in a 500 mL erlenmeyer flask. And then, the mixture was allowed to boil at 50°C for about one hour. The extracted solution was collected and stored at 4°C within a refrigerator [10]. The filtrate of the extract was used as a capping and reducing agent for the biosynthesis of TiO 2 NPs within three different volume ratios.

Biosynthesis of TiO 2 NPs
Using Root of Kniphofia schemperi. TiO 2 NPs were biosynthesized by using 0.25 M of the precursor Titanium tetra butoxide, C 16 H 36 O 4 Ti, and ethanolic root extract of Kniphofia schemperi of different volume ratios: 2 : 3 (40 mL precursor salt versus 60 mL of root extract of Kniphofia schemperi), 1 : 1 (50 mL precursor salt versus 50 mL root extract of Kniphofia schemperi), and 3 : 2 (60 mL precursor salt versus 40 root extract of Kniphofia schemperi). The prepared NPs were labeled as TiO 2 (2 : 3), TiO 2 (1 : 1), and TiO 2 (3 : 2). All solutions of different volume ratios were stirred for about five hours without heating. The precipitated was formed by drop wise addition of solution of sodium hydroxide as a precipitating agent. The solution with a precipitate was centrifuged at 1000 rpm and washed four times with distilled water and absolute ethanol, dried in oven overnight at 100°C, and calcined at 500°C for about four hours [10]. Figure 1 shows the schematic synthesis process of TiO 2 NPs using root extract of Kniphofia schemperi and from its titanium tetra butoxide precursor.

Extraction and Preparation of Sensitizer. Roots of
Kniphofia schemperi were collected from Bale National Park, Oromia regional state, Ethiopia. Those collected samples were surface cleaned repeatedly and allowed to dry under shadow at room temperature. Then, it was ground into powder and packed in a plastic bottle by covering with aluminum foil and storing it in a dark area. The extract was obtained by taking 4 g powders of roots of Kniphofia schemperi to be socked in an erlenmeyer flask with 100 mL of absolute ethanol. The mixture solution was placed in a dark place and covered with aluminum foil to avoid photooxidation. The solution was stored for about 24 h at room temperature until the required pigment solution was extracted. Then, the solid materials were hold still overnight, and the clear solution of the dye was obtained. The clear solution to be used for sensitization purpose was separated from solid materials using glass filters [17,18].

Fabrication
Steps of DSSCs 2.6.1. Preparation of the Substrate for Deposition. The conductive fluorine-doped tin oxide (FTO) glass substrate with an area of 2 cm × 2:5 cm was cleaned repeatedly with distilled water and acetone, isopropanol, and ethanol sequentially under ultrasonication for about 20 minutes in each different solvent in order to remove organic and inorganic dirts from the surface of the substrate. The substrates were thoroughly cleaned before deposition of films of biosynthesized TiO 2 (2 : 3, 1 : 1, and 3 : 2) NPs was carried out.

Semiconductor Oxide Material Paste Preparation and
Deposition. TiO 2 paste was prepared according to the method developed by Nazeeruddin et al. [19]. As an example, 0.76 g powder from each kind of TiO 2 volume ratio was ground in a porcelain mortar with a drop-wise addition of 1 mL of H 2 O containing 0.56 mL of 1 M HNO 3 to prevent reaggregation. After the powder had been dispersed by the high shear forces in the viscous paste, it was diluted by additional drop-wise of DH 2 O for continuous grinding. Finally, 0.025 mL of Triton × -100 was added as a dispersing agent followed by grinding well with the mixture for additional 30 minutes until the paste became homogeneous. The prepared paste was deposited near the top edge of FTO glass between the two pieces of the tape and then was coated by tape casting skill with a doctor blade [20][21][22]. This process was continued until the layer became uniform and smooth. The tape was removed with care without scratching the TiO 2 coating. Figure 2 shows the corresponding paste preparation procedures using biosynthesized TiO 2 NPs and its deposition on to the cleaned FTO glass substrate. The as-prepared biosynthesized TiO 2 film was fired at 450°C in a muffle furnace for about 30 minutes to remove the organic solvents. This procedure also ensured electrical contact with good adhesion between the particle film and substrate.
2.6.3. Electrode Sensitization. Sensitizers obtained from roots of Kniphofia schemperi dye were adsorbed on top of TiO 2 photoelectrodes as follows. The TiO 2 film-coated electrode was immersed into the solutions of roots of Kniphofia schemperi (dye) until the films were fully soaked with the dye solution for about 12 hours (shown in Figure 3(a)). The TiO 2 film-coated substrates with the adsorbed molecules of dye were taken out and rinsed with the same solvent used in dye extraction (absolute ethanol) to remove the unadsorbed dyes from the surface of the TiO 2 -photoanode [19].  3 International Journal of Photoenergy 2.6.4. Preparation of Redox Electrolytes. The polymer gel electrolyte was prepared according to the method developed by Fan et al. [23]. This was done by taking 4 mL 1-ethylene-3methyl immidazolium iodide (EMIM-I) of 0.9 M and 25 mL acetonitrile, a high dielectric constant organic solvent, to form a homogeneous liquid electrolyte of 5.3 g under continuous stirring. In order to obtain a better conductivity, 0.5 M of sodium iodide was dissolved in the above homogeneous liquid electrolytes and then 0.12 M iodine and 35% (w/w) of polyvinyl pyrrolidone were added. Figure 4 reveals the formation of the quasisolid-state redox electrolyte from its components. The resulting mixture was heated at 70-80°C under vigorous stirring to dissolve the added PVP followed by cooling down to room temperature. Figure 4(b) with upside-down vial containing the redox electrolyte shows that the prepared electrolyte was really quasisolid (do not flow).
2.6.5. Coating the Counter Electrodes. The counter electrodes were prepared through electrochemical polymerization of 3, 4-ethylenedioxythiophene (EDOT) in a three-electrode cell by using an electrochemical analyzer. The electrochemical cell was consisted of FTO-spattered (conductive) glass sub-strate as the working electrode, a platinum foil as the counter electrode, and quasisilver/silver chloride as reference electrode. The solution/electrolyte system used for the preparation of counter electrode was performed by mixing 0.1 M EDOT and 0.1 M (C 2 H 5 ) 4 NBF 4 in acetonitrile solvent. The polymerization was carried out at a potential of +1.8 V for about 2 seconds through the bulk electrolysis with coulometer. At this potential, the electrode surface was covered with a blue-doped PEDOT film [24]. FTO glass substrates that were coated with PEDO counter electrode is shown in Figure 3       International Journal of Photoenergy monochromator (Model 77250) was placed into the light path and used to select a wavelength between 300 and 800 nm with a 20-minute interval during measurement of incident photon to current conversion efficiency (IPCE).

Results and Discussion
3.1. Thermal Gravimetric and Differential Thermal Analysis (TGA-DTA). TGA-DTA was performed as a function of temperature as it can be shown in Figure 5. The analysis was done by taking 5.94 mg of the uncalcined biosynthesized TiO 2 (1 : 1) NP sample. The observed weight loss below 150°C was due to the evacuation of physically and chemically entangled water molecules from the surface of nanomaterials.
In the temperature range of 150-355°C, the weight loss was also occurred due to the process of pyrolysis and carbonization of biomass materials from the synthesized TiO 2 NPs [25]. Weight loss was again observed and continued up to 483.15°C that was associated with a strong exothermic peak, which can be attributed to the vaporization of carbonized residues present over the surface of the biosynthesized nano-TiO 2 . Similar result related to the present findings was also reported [12]. After 483.15°C-900°C, no considerable weight loss was observed as observed under the spectrum; therefore, 500°C was chosen as the calcination temperature for the biosynthesized TiO 2 NPs formed within three different volume ratios.

XRD Analysis.
The crystalline nature of the biosynthesized TiO 2 NPs was analyzed using X-ray diffraction measurements. Figure 6 shows the XRD crystalline nature of the biosynthesized TiO 2 NPs formed within three different volume ratios. The diffraction peaks were observed at the 2θ values of ≈25. The average crystalline sizes were calculated based on Debye Scherer's equation [12], and the values were found to be 11.7, 8.3, and 8.6 nm for 2 : 3, 1 : 1, and 3 : 2 volume ratios, respectively. Similar result related to the present study was also reported [26]. As compared to XRD result of TiO 2 (3 : 2) ratio, TiO 2 (1 : 1) ratio had a relatively smaller average crystalline size of ≈8.3 nm. This difference might be due to the fact that the excess amount of root extract added and used as a template to block the grain growth of TiO 2 (1 : 1) relative to the remaining two ratios of TiO 2 NPs. As it was observed from the XRD spectrum, TiO 2 (2 : 3) NP losses their crystalline nature due to the excessive addition of the root extract of Kniphofia schemperi. The excessive root extract with the polymer chain structure is difficult to completely burn out at 500°C; therefore, those residues on TiO 2 NPs block the diffraction signals with XRD analysis.

SEM-EDS Analysis.
Morphology of the formed nanoparticles within three volume ratio of precursor salt and that of Kniphofia schemperi ethanolic root extract has been studied with the help of SEM-EDS. Figure 7 depicts the SEM images of TiO 2 NPs biosynthesized in the volume ratios of (a) 2 : 3, (b) 1 : 1, and (c) 3 : 2 and the corresponding EDS analysis of TiO 2 from the selected area in SEM image. From SEM images, the morphology of TiO 2 NPs was found to be spherical in shape with distinct edges. SEM image also revealed the increase in the particle size with the corresponding increase in the amount of ethanolic root extract of Kniphofia schemperi [27]. Agglomeration of the particles in Figure 7(a) is attributed because of the presence of excess amount of root extract [28]. To confirm and gather different information, a further insight about the biosynthesized TiO 2 nanoparticles formed within a volume ratio of 2 : 3, 1 : 1, and 3 : 2, analysis of the sample using EDS techniques was performed. It is necessary to verify the presence of desired elements in the biosynthesized TiO 2 NPs formed as 2 : 3, 1 : 1, and 3 : 2. The absence of any foreign materials in all of the three ratios indicates the high purity of our synthesized TiO 2 NPs [29].  [12].
The image in Figure 8(c) showed HRTEM of anatase TiO 2 NPs. A fringe width of 0.355 nm Figure 8(b) in particle demonstrates for the (101) plane of anatase biosynthesized TiO 2 NPs. The lattice fringes also display the nanocrystalline nature of the biosynthesized TiO 2 NP anatase phase form. Figure 9(a) shows the UV-Vis absorption spectra of TiO 2 NPs prepared at different volume ratios of 2 : 3, 1 : 1, and 3 : 2 in terms of the 0.25 Ti precursor salt and root extract of Kniphofia schemperi. The absorbance of TiO 2 NPs showed spectral shift for TiO 2 NPs at different precursor ratios. Compared to the very low absorption of the reference TiO 2 NPs, our TiO 2 NPs biosynthesized at different volume ratios exhibited a slight shift of the absorption edge towards the visible region due to their smaller size. The energy bandgaps of the biosynthesized TiO 2 NPs were estimated using the Tauc's plot method technique [15]. With the Tauc plot in terms of the ðαhνÞ 2 versus hν in Figure 9(b), the energy bandgaps (E g )f TiO 2 NPs were determined to be 3.35, 3.33, and 3.36 eV for the different volume ratios of TiO 2 synthesized within a volume ratio of 2 : 3, 1 : 1, and 3 : 2, respectively. The slight variation in E g for TiO 2 NPs is due to the variation in volume ratio between Ti precursor salt and the root extract of Kniphofia schemperi that results in light absorption at different UV-Vis regions of absorption.

UV-Vis Absorbance and Tauc Plot Analysis.
3.6. Functional Group Analysis Using FTIR. Fourier transformation infrared spectroscopy analysis was done to identify and confirm the role of biomolecules that was responsible for capping and reducing of the bioreduction of TiO 2 NPs. Figure 10 displays the FTIR spectra analysis of root powder of Kniphofia schemperi (a), calcined biosynthesized TiO 2 NPs (b), and uncalcined biosynthesized TiO 2 NPs (c). The peak presented around 1620.65 cm -1 could also represent the C=C bond of saturated hydrocarbons. The characteristic peaks of 1387.52 represents the C-H rock alkenes, while the peak observed at around 1065.32 cm -1 indicates the presence of C-O stretching alcohols, carboxylic acids, esters, and ethers. This peak may also depict the existence of aliphatic amines [30].   International Journal of Photoenergy or to C=C groups of aromatic rings that plays as stabilizer and reducing agents during the stage of synthesis. This band also relate to the bending mode of vibration of O-H group and flavones. The peak represented by 1380.55 cm -1 refers to the aromatic ethers of C-O stretching and also the C-H rock like alkene groups. Peaks of C=O and C=C clearly indicates the presence of biomolecules and bioactive constituents from roots of Kniphofia schemperi extract that was used as a capping and reducing agent during the synthesis process of TiO 2 NPs within different volume ratios. The peak at 551.81 cm -1 is indicating the presence of Ti-O stretching vibration, and this confirms the formation of metal-oxygen bonding [31]. The analysis confirms the formation of TiO 2 with many surface hydroxyl function groups. The extra peaks from the organic C and O bonds are attributed to a trace amount of extract pyrolytic residues left after a relatively lower temperature firing procedure. These results indicated that the presence of alcohols, phenols, primary amines, ketones, and aliphatic amines in the root extract of Kniphofia schemperi that have been participated in the process of synthesis of TiO 2 NPs is responsible for the bioreduction of TiO(OH) 2 to TiO 2 NPs [30].
As it can be depicted under Figure 10(c), the peaks observed at 3409.81, 2922.63, 2320.05, 1620.65 1319.36, 1038.21, and 777.97 cm -1 represent O-H bond stretching due to adsorbed moisture, the CH, CH 2 , and CH 3 functional groups linked via H-bonds, C=O bond stretching that might be due to the presence of adsorbed carbon dioxide on the surface of TiO 2 , the surface water and hydroxyl groups, the C-H of alkenes, and the C-O bond of stretching of alcohols, carboxylic acids, ethers, and esters, respectively. In addition to this, the FTIR analysis indicated in Figure 9(c) shows the broad band centered at round 777.97 cm -1 which represents a characteristic peak to be believed due to the interaction of the biosynthesized nanooxide with biomolecules of the extract. As compared to the FTIR spectra of root powder and uncalcined TiO 2 NPs, the absence of different functional groups located at around 2922.63, 2840.53, and 1038.21 cm -1 in the calcined biosynthesized TiO 2 NPs confirms that these functional groups were eliminated during the firing process. Therefore, this characterization technique provides information as the extract plays great role and removed after calcination process was carried out [31].

Absorption Spectra of Root Extract of Kniphofia schemperi
Sensitizer. Figure 11 reveals the corresponding optical absorption spectra of root of Kniphofia schemperi natural sensitizer. The roots of Kniphofia schemperi sensitizer show a strong absorption band at around 231 nm. The absorption of Kniphofia schemperi ascribes to the component, namely, anthocyanin, a group of natural phenolic compounds [32]. This result confirms that the pigment extracted from this natural dye can be used as a photosensitizer because it strongly absorbs photons in a wide UV-Vis region of electromagnetic radiation. One of the essential requirements for photosensitizer with the best performance is to have the broad and intense absorption in the UV-Vis and near-IR regions of the solar spectrum.   Figure 12 shows the J-V curves of root of Kniphofia schemperi-based DSSCs prepared using TiO 2 photoanode at different precursor ratios. The compiled data from the J-V curves were presented in Table 1. The solar cell with TiO 2 (3 : 2) biosynthesized photoelectrodes shows the highest η value of 1.3%, the highest V OC of 161 mV, the highest J SC of 2:46 × 10 −2 mA/cm 2 , and slightly lower FF of 32.8%. The improvement in J SC value of TiO 2 (3 : 2)-based DSSC is basically due to the improved absorption of light caused by the  9 International Journal of Photoenergy wider range of absorption of sensitizer adsorbed on nanoparticles, as supported with Figure 12, while the enhanced efficiency attributed due to the improved crystallinity and morphological nature of TiO 2 photoelectrodes to allow more dye adsorption on its surface, larger band gap energy, and higher interaction between TiO 2 nanocrystalline film and the root extract of the sensitizer for better charge transfer [33].
In general, the efficiencies of DSSCs not only depend on the molecular structure of the natural pigment but also depend strongly on the properties of the biosynthesized photoelectrodes such as crystallinity, morphology, and aggregation of the dye molecules [34]. It was earlier reported that the power conversion efficiency of most of the DSSCs made from natural dyes and some organic synthetic dyes suffers from the low open circuit voltage, which is also the case in the present study where the open circuit voltage ranged from 29 to 161 mV for the biosynthesized photoanode with the different precursor volume ratios.

IPCE Characteristics of Biosynthesized TiO 2 -Based DSSCs.
Photoaction spectra provide further insights on the photoelectrochemical performance of biosynthesized photoelectrodes with the presence of sensitizers. As it can be observed from Figure 13, relatively maximum IPCE% value was obtained using TiO 2 (3 : 2) in the presence of ethanolic root extract of Kniphofia schemperi sensitizer, and this value is 8.11%, which was located at a wavelength of 340 nm. The improvement in IPCE% value relative to the remaining photoelectrodes results from higher electron transportation at the electrolyte interfaces and good electrocatalytic activity of the phototelectrode [34]. Again, TiO 2 (1 : 1) with the presence of Kniphofia schemperi sensitizer possess an IPCE% of 2.66% which occurs at 500 nm. This action spectra response is contributed by sensitizer.
Low IPCE% value was recorded using biosynthesized phototelectrode obtained within a 2 : 3 ratio, and the value was estimated as 1.27% at a wavelength value of 800 nm. This low value of IPCE% may be attributed due to inefficient light harvesting efficiency (LHE) by the dye, that is, inefficient charge injection into the prepared TiO 2 film or inefficient collection of injected electrons [35].
For devices of DSSCs (with 2 : 3 volume ration of TiO 2 film), the IPCE values of 1~2% were recorded at 500-800 nm as shown in Figure 13, while negligibly small amount of absorption was observed for the film (Figure 9(a)). The IPCE value of DSSCs depends not only on the lightabsorbing nature of semiconductor (TiO 2 NPs) but also on light absorption of sensitizer (dye), absorption and interaction of redox electrolyte, and the interaction of dye molecules with TiO 2 film.
According to previous reports [36][37][38], the redox couple (quasisolid-state electrolyte) involves in light absorption (in certain amount) in visible region even beyond 500 nm and has a contribution for IPCE values. The films of photoanode of TiO 2 NPs (with anatase phase structure) are highly porous. These porous structures of TiO 2 NPs provide larger surface area for anchoring of dye molecules [39,40]. Lightabsorbing dye molecules attached to the semiconductor (TiO 2 NPs) through their functional groups such as carboxylic acid, phenol, and flavonoids interact with titanium metal as ligand in the film. As of some other reports [41], the ligandmetal (push-pull) type of interaction established between dye molecule and TiO 2 NPs contributes for significant charge separation, minimizes electron-hole recombination, and minimizes series resistance between semiconductor (TiO 2 NPs) and light sensitizer that confirms the higher efficiency of photon-to-electron conversion or incident photon to current conversion efficiency (IPCE%).

Conclusion
In conclusion, TiO 2 NPs had been successfully biosynthesized using titanium tetra butoxide precursor salt and Kniphofia schemperi root extract at different volume ratios. The biosynthesized NPs were thermally stable above 500°C. XRD

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International Journal of Photoenergy analysis proved that the average particle size of the synthesized TiO 2 NPs was found in the range of 8.3-11.7 nm. SEM-EDS revealed morphology of the biosynthesized TiO 2 NPs to be spherical and the composition with only the elements of Ti and O. The calculated bandgap energies were in the range of 3.33-3.36 eV. Functional group analysis indicated the presence of a trace amount of extract pyrolytic residues left. Among the TiO 2 NPs biosynthesized at different precursor ratios, the best solar cell conversion to electricity was obtained for Kniphofia schemperi-based dye-filled DSSC using TiO 2 (3 : 2) photoelectrodes which was estimated as 1.3%.

Data Availability
The research data used to support the findings of this study are included in the article.

Conflicts of Interest
The authors fully declare that they have no conflicts of interest.