Dr. Anil Kumar Singh* is an Associate Professor of Chemistry (CCSIT) at Teerthanker Mahaveer University, Moradabad, Uttar Pradesh. With an **M.Sc. and Ph.D. in Physical Chemistry, he has over **20 years of teaching and research experience.
His research focuses on the kinetic solvent effect, with **52 published papers, **112 citations, **h-index 7, and **i10-index 4. He has also presented **8 conference papers, attended **09 seminars, and holds **28 patents.
As a research mentor, Dr. Singh has guided one Ph.D. scholar and currently supervises two doctoral candidates. He is also engaged in a **research project worth Rs. 1,000,00.
Dr. Singh continues to contribute significantly to research and innovation in Physical Chemistry while inspiring future scientists.
EDUCATION
M Sc Ph. D in chemistry
RESEARCH, TEACHING, or OTHER INTERESTS
Physical and Theoretical Chemistry, Physical and Theoretical Chemistry, Physical and Theoretical Chemistry, Physical and Theoretical Chemistry
8
Scopus Publications
Scopus Publications
Cancer Drug Discovery in the Digital Age: A Computational Perspective Absar Ahmad, Souvik Sur, Anil Kumar Singh Macromolecular Symposia, 2026 The overarching goal of multi‐scale computational integration seeks to enhance early clinical outcome prediction in order to increase the efficiency and productivity of the therapeutic development pipeline. Rather than incremental improvements offered by tweaking existing isolated methods like QSAR or molecular docking, fundamentally reinventing the modeling paradigm to appropriately represent biological mechanisms across interconnected scales promises a transformational advance. Challenges certainly exist in managing model complexity while retaining biological traceability. However, the expected dividends from even partially attaining mechanistically articulated dynamical mappings between salient molecular events through physiological responses and ultimately clinical data warrant sustained collaborative pursuit by the quantitative pharmacology modeling community in coming years. Ultimately, the grand aim centers on inverting the dominant workflow overly reliant on brute empirical force. Instead, it remains eminently feasible to judiciously supplement but largely replace serial experimentation driving late stage optimization with rationally designed in silico trials simulating and troubleshooting various what‐if intervention scenarios.
Hydrothermal Synthesis of Z-Scheme FeWO4/BiOBr Nanocomposite for Photocatalytic Degradation of Rhodamine B Dye Mohammad Farhan, Anil Kumar Singh, Gandharve Kumar Macromolecular Symposia, 2026 FeWO 4 /BiOBr photocatalyst was prepared by the hydrothermal route of synthesis, and it was characterized by various techniques such as scanning electron microscopy, powder X‐ray diffraction, and UV–vis diffuse reflectance spectroscopy. Photocatalytic activity was evaluated by photocatalytic degradation of Rhodamine B (RhB) under the irradiation of visible light. The 15 wt.% FeWO 4 /BiOBr photocatalysts degraded 99% (RhB, 10 mg/L), with a degradation rate (0.037 min −1 ), which was 4.83 times and 6.41‐times higher than that of the BiOBr (0.0077 min −1 ) and FeWO 4 (0.0058 min −1 ) photocatalysts, respectively. The strong visible light absorption by 15 wt.% FeWO 4 /BiOBr nanocomposite, band position of FeWO 4 and BiOBr which are like Z‐scheme, proficient inhibition of charge carrier recombination, in situ formation of reactive oxygen species are the main reasons for the better photocatalytic efficiency of FeWO 4 /BiOBr nanocomposite.
Integration of Graphene Oxide and Halide Perovskites for High-Performance Supercapacitors: A Review Sonu, Anil Kumar Singh, Mrinmoy Kumar Chini Macromolecular Symposia, 2026 The coordinated development of materials for energy conversion and storage is necessary due to the rising demand for energy worldwide. This article discusses the advancements made in the direction of graphene oxide based halide perovskite electrode for energy storage device. Specially, Graphene oxide based halide perovskite electrode is being deliberated as the potential electrode materials for great power supercapacitor application due to its exceptional chemical and physical characteristics, including high electrical conductivity and a huge surface area. In the development of high‐performance supercapacitors, graphene oxide and halide perovskites have demonstrated encouraging outcomes. Because of their huge surface area and superior electrical conductivity, graphene‐based materials are very sought‐after for supercapacitors. According to a study, an aqueous electrolyte with tailored three‐dimensional graphene frameworks can have a superior gravimetric capacitance of 330 F g −1 . Organic and gel electrolytes were among the electrolytes used to test this performance; the latter demonstrated an outstanding capacitance of 285 F g −1 along with outstanding rate capability and cycle life. The maximum energy density of around 22 Wh kg −1 and power density of 900 W kg −1 for the supercapacitor were achieved with a particular ratio of bromide to iodide in the perovskite materials. Incorporating GO into CH 3 NH 3 PbI 3 perovskite layers improved humidity resistance and device lifespan by acting as a water diffusion barrier. Our review article will comprise of Structure, dimensionality, properties, supercapacitor & classification, 2D, 3D & graphene oxide based halide perovskite materials for supercapacitor, challenges/ limitation, Future Scope of supercapacitor in brief.
Hydrothermal Synthesis of Z-Scheme ZnWO4/BiOBr Nanocomposite for Photocatalytic Degradation of Rhodamine B Dye Mohammad Farhan, Anil Kumar Singh, Gandharve Kumar Asian Journal of Chemistry, 2025 The ZnWO4/BiOBr heterostructured photocatalyst was prepared using a hydrothermal synthesis method and systematically characterized using advanced analytical techniques. Its photocatalytic performance was evaluated under simulated sunlight, demonstrating efficient degradation of rhodamine B (RhB) dye. The best performing 10 wt.% ZnWO4/BiOBr photocatalysts remove about 99% RhB (10 mg/L), whose photocatalytic degradation rate was 17-times and 5-times superior than ZnWO4 and BiOBr parent materials, respectively. The enhanced photocatalytic efficiency of the 10 wt.% ZnWO4/BiOBr nanocomposite under visible light is attributed to its favourable band alignment resembling a Z-scheme mechanism, which facilitates effective charge separation, suppresses electron-hole recombination and promotes the in situ generation of reactive oxygen species.
HYDROTHERMAL FABRICATION OF Z-SCHEME Sn3O4/BiVO4 NANOCOMPOSITE FOR PHOTOCATALYTIC DEGRADATION OF RHODAMINE B DYE Mohammad Farhan, Anil Kumar Singh, Gandharve Kumar Rasayan Journal of Chemistry, 2025 Sn3O4/BiVO4 photocatalyst was prepared by the hydrothermal route, and its activity was tested on the degradation of RhB dye under sunlight. The 15 wt% Sn3O4/BiVO4 photocatalysts degraded 99 % (RhB, 10 mg/L), whose degradation rate was 5.7 times and 10 times superior to BiVO4 and Sn3O4 photocatalysts, respectively. The strong visible light absorption by 15 wt% Sn3O4/BiVO4 nanocomposite, band position of Sn3O4 and BiVO4, which are like Z-scheme, proficient suppression of electron-hole recombination, and formation of reactive oxygen species in situ are the main reasons for the better photocatalytic efficiency of Sn3O4/BiVO4 nanocomposite.
Synthesis and Characterization of FeWO4/BiOCl Nanocomposites for Photocatalysis and Cytotoxicity in CHO Cell Line Mohammad Farhan, Anil Kumar Singh, Gandharve Kumar Asian Journal of Chemistry, 2025 A novel FeWO4/BiOCl nanocomposite was prepared by hydrothermal route of synthesis and characterized by high-resolution transmission electron microscopy (HRTEM), field-emission scanning electron microscopy (FESEM), powder X-ray diffraction (pXRD) and UV-visible diffuse reflectance spectroscopy (UV-Vis DRS). Photocatalytic activity was evaluated by photocatalytic degradation of rhodamine B (RhB) under the irradiation of visible light. The biological activities such as cytotoxicity were investigated by propidium iodide (PI), a fluorescent dye, uptake and cellular uptake studies. The 15 wt.% FeWO4/BiOCl photocatalysts degraded 98% (RhB, 10 wt.%), whose degradation rate was 3.92 times and 7.34 times higher than that of BiOCl and FeWO4 photocatalysts, respectively. The synthesized FeWO4/BiOCl nanocomposite showed the cytotoxicity to Chinese Hamster Ovary (CHO) cells at concentration increase from 1 µg/mL to 75 µg/mL. In case of cellular uptake studies, FeWO4/BiOCl nanoparticles shows decreases cell viability after 24 h of exposure, as the concentration increase from 1-100 µg/mL.
