Your search keyword '"Sidra Chaudhary"' showing total 5 results

1. Al(SO4)(OH)·5H2O Stemming from Complexation of Aluminum Sulfate with Water-Soluble Ternary Copolymer and further Stabilized by Silica Gel as Effective Admixtures for Enhanced Mortar Cementing

Author

Zhiyuan Song, Zainab Bibi, Sidra Chaudhary, Qinxiang Jia, Xiaoyong Li, and Yang Sun

Subjects

ternary copolymer, aluminum sulfate, cement, mortar, setting time, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

A water-soluble ternary copolymer bearing carboxyl, sulfonic, and amide functional groups was synthesized using ammonium persulfate-catalyzed free radical polymerization in water, resulting in high monomer conversion. This copolymer was then complexed with aluminum sulfate, forming an admixture containing Al(SO4)(OH)·5H2O, which was subsequently combined with silica gel. Characterization revealed that the synthesized copolymer formed a large, thin membrane that covered both the aluminum compounds and the silica gel blocks. The introduction of this complex admixture, combining the copolymer and aluminum sulfate, not only reduced the setting times of the cement paste but also enhanced the mechanical strengths of the mortar compared to using aluminum sulfate alone. The complex admixture led to the formation of katoite, metajennite, and C3A (tricalcium aluminate) in the mortar, demonstrating significant linking effects, whereas pure aluminum sulfate could not completely transform C3S within 24 h. Further addition of silica gel to the complex admixture further shortened the setting times of the paste, slightly reduced compressive strength, but improved flexural strength compared to the initial complex admixture. The silicon components appeared to fill the micropores and mesopores of the mortar, accelerating cement setting and enhancing flexural strength, while slightly decreasing compressive strength. This study contributed to the development of new cementing accelerators with improved hardening properties.

Published

2024

2. The Coordination of Aluminum Sulfate with a Water-Soluble Block Copolymer Containing Carboxyl, Amide, Sulfonic and Anhydride Groups Providing Both Accelerating and Hardening Effects in Cement Setting

Author

Zhiyuan Song, Sidra Chaudhary, Zainab Bibi, Yong Wu, Qinxiang Jia, Xiaoyong Li, Weiyi Ouyang, and Yang Sun

Subjects

aluminum sulfate, block copolymer, accelerator, mortar, cement hydration, setting time, Organic chemistry, QD241-441

Abstract

Two water-soluble block copolymers composed of acrylic acid (AA), 2-acrylamido-2-methylpropane sulfonic acid (AMPS), and optionally maleic anhydride (MAH) were synthesized through ammonium persulfate-catalyzed free radical polymerization in water. The introduction of aluminum sulfate (AS) into the resulting mixtures significantly reduced the setting times of the paste and enhanced the mechanical strength of the mortar compared to both the additive-free control and experiments facilitated solely by pure AS. This improvement was primarily attributed to the inhibition of rapid Al3+ hydrolysis, which was achieved through coordination of the synthesized block copolymers, along with the formation of newly identified hydrolytic intermediates. Notably, the ternary copolymer (AA–AMPS–MAH) exhibited superior performance compared to that of the binary copolymer (AA–AMPS). In the early stages of cement setting, clusters of ettringite (AFt) were found to be immobilized over newly detected linkage phases, including unusual calcium silicate hydrate and epistilbite. In contrast to the well-documented role of polymers in retarding cement hydration, this study presents a novel approach by providing both accelerating and hardening agents for cement setting, which has significant implications for the future design of cement additives.

Published

2024

3. Mechanochemical Synthesis of PdO2 Nanoparticles Immobilized over Silica Gel for Catalytic Suzuki–Miyaura Cross-Coupling Reactions Leading to the C-3 Modification of 1H-Indazole with Phenylboronic Acids

Author

Qin Pan, Yong Wu, Aqun Zheng, Xiangdong Wang, Xiaoyong Li, Wanqin Wang, Min Gao, Zainab Bibi, Sidra Chaudhary, and Yang Sun

Subjects

ball milling, Suzuki–Miyaura cross-coupling, 1H-indazole, PdO2 nanoparticle, silica gel, Organic chemistry, QD241-441

Abstract

The C-3 modification of 1H-indazole has produced active pharmaceuticals for the treatment of cancer and HIV. But, so far, this transformation has seemed less available, due to the lack of efficient C-C bond formation at the less reactive C-3 position. In this work, a series of silica gel-supported PdO2 nanoparticles of 25–66 nm size were prepared by ball milling silica gel with divalent palladium precursors, and then employed as catalysts for the Suzuki–Miyaura cross-coupling of 1H-indazole derivative with phenylboronic acid. All the synthesized catalysts showed much higher cross-coupling yields than their palladium precursors, and could also be reused three times without losing high activity and selectivity in a toluene/water/ethanol mixed solvent. Although the palladium precursors showed an order of activity of PdCl2(dppf, 1,1′-bis(diphenylphosphino)ferrocene) > PdCl2(dtbpf, 1,1′-bis(di-tert-butylphosphino)ferrocene) > Pd(OAc, acetate)2, the synthesized catalysts showed an order of C1 (from Pd(OAc)2) > C3 (from PdCl2(dtbpf)) > C2 (from PdCl2(dppf)), which conformed to the orders of BET (Brunauer–Emmett–Teller) surface areas and acidities of these catalysts. Notably, the most inexpensive Pd(OAc)2 can be used as a palladium precursor for the synthesis of the best catalyst through simple ball milling. This work provides a highly active and inexpensive series of catalysts for C-3 modification of 1H-indazole, which are significant for the large-scale production of 1H-indazole-based pharmaceuticals.

Published

2023

4. To Compare the Mean Postoperative Pain Score between Intravenous Paracetamol Vs Intravenous Ketorolac among patients undergoing Gynecological Abdominal Surgery

Author

Sidra Chaudhary, Shahid Iqbal, Rifah Zia, Muhammad Muazzam Butt, Muhammad Baqir Ali Khan, and Abaid-Ur- Rehman

Abstract

Background: Post-operative pain is one of the common concerns in all the surgical interventions including gynecological surgeries. There is always a need for the agent with better efficacy and minimal side effect profiles. Aim: To compare the mean postoperative pain score between intravenous Paracetamol vs intravenous ketorolac among patients undergoing gynecological abdominal surgery Study design: Randomized Controlled Trial Setting & duration: Department of Anesthesia, Hameed Latif Hospital, Lahore from 12-06-2018 to 12-12-2018 Methodology: In this study, females with age 20 - 50 years with ASA I and II undergoing gynecological abdominal surgery were included. Group A was administered with intravenous paracetamol and group B with ketorolac. Pain was measured in terms of mean of numerical rating scale recorded at 12 hours postoperatively. Results: In the present study there were total 80 cases included, 40 in each group. The mean age in group B was 37.66±12.67 years and in group A was 41.29±11.36 years Mean post operative pain score was 3.05±0.61vs 3.56±0.89 in group B and A with p= 0.04 Mean post operative pain was 3.04±0.61 vs 3.51±0.77 with p= 0.03 in cases with BMI > 25. There was no significant difference in terms of type of procedure and mean pain score in both groups. Conclusion: Ketorolac is significantly better than Paracetamol in gynecological abdominal surgeries and this difference is also significantly better in cases with BMI > 25. Keywords: Pain, ketorolac, paracetamol, BMI

Published

2022

5. In-situ synthesis of mercury(II)-N-heterocyclic carbene complexes by using 'oxide route', structural characterization and their photo-catalytic degradation activity for dyes

Author

Sidra Chaudhary, Muhammad Faisal Altaf, Shoomaila Latif, Muhammad Imran, Muhammad Hasnain, and Muhammad Adnan Iqbal

Subjects

Inorganic Chemistry, Organic Chemistry, Materials Chemistry, Physical and Theoretical Chemistry, Biochemistry

Published

2022