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(+)-Magnoflorine Iodide (CAS 13074-53-8)

(+)-Magnoflorine Iodide (CAS: 13074-53-8) has molecular formula C20H24NO4+ and molecular weight 342.4 g/mol. This compound has been the subject of numerous scientific investigations due to its structural features and practical utility in synthetic chemistry and industrial processes. View product details →

Product Background

This comprehensive research profile examines the scientific literature surrounding (+)-Magnoflorine Iodide.

Key Research Findings

  • We show how type I and II band alignments arising under different conditions result in either passivation of surface defects or hole injection.
  • Here, we report the results of synchrotron XRD and X-ray total scattering measurements on putative Cs2AgBiI6 nanocrystals made via anion exchange from parent Cs2AgBiBr6 nanocrystal

Detailed Literature Analysis

Below are the top-ranked research papers for (+)-Magnoflorine Iodide, presented with bibliographic details and scientific abstracts.

Synthetic Chemistry

1. Structure and Stability of the Iodide Elpasolite, Cs2AgBiI6
Kyle T. Kluherz, Sebastian T. Mergelsberg, James J. De Yoreo, Daniel R. Gamelin; arXiv preprint
Iodide elpasolites (or double perovskites, A2B'B"I6, B' = M+, B" = M3+) are predicted to be promising alternatives to lead-based perovskite semiconductors for photovoltaic and optoelectronic applications, but no iodide elpasolite has ever been definitively prepared or structurally characterized. Iodide elpasolites are widely predicted to be unstabl
2. Structure and Stability of the Iodide Elpasolite, Cs2AgBiI6
Kyle T. Kluherz, Sebastian T. Mergelsberg, James J. De Yoreo, Daniel R. Gamelin; arXiv preprint
Iodide elpasolites (or double perovskites, A2B'B"I6, B' = M+, B" = M3+) are predicted to be promising alternatives to lead-based perovskite semiconductors for photovoltaic and optoelectronic applications, but no iodide elpasolite has ever been definitively prepared or structurally characterized. Iodide elpasolites are widely predicted to be unstabl

Biological & Pharmacological Studies

3. Understanding the Effect of Lead Iodide Excess on the Performance of Methylammonium Lead Iodide Perovskite Solar Cells
Zeeshan Ahmad, Rebecca A. Scheidt, Matthew P. Hautzinger, Kai Zhu, Matthew C. Beard; arXiv preprint
The presence of unreacted lead iodide in organic-inorganic lead halide perovskite solar cells is widely correlated with an increase in power conversion efficiency. We investigate the mechanism for this increase by identifying the role of surfaces and interfaces present between methylammonium lead iodide perovskite films and excess lead iodide. We s
4. Understanding the Effect of Lead Iodide Excess on the Performance of Methylammonium Lead Iodide Perovskite Solar Cells
Zeeshan Ahmad, Rebecca A. Scheidt, Matthew P. Hautzinger, Kai Zhu, Matthew C. Beard; arXiv preprint
The presence of unreacted lead iodide in organic-inorganic lead halide perovskite solar cells is widely correlated with an increase in power conversion efficiency. We investigate the mechanism for this increase by identifying the role of surfaces and interfaces present between methylammonium lead iodide perovskite films and excess lead iodide. We s
5. Opposites Attract, Muons as Direct Probes for Iodide Diffusion in Methyl Ammonium Lead Iodide
D. W. Ferdani, A. L. Johnson, S. E. Lewis, P. J. Baker, P. J. Cameron; arXiv preprint
The volume of research into organo-lead hailde perovskites is increasing rapidly, with perovskite solar cell efficiencies reaching as high as 22 percent. There is considerable evidence that mobile ions in the perovskite strongly influence the properties of the solar cell, with the majority of studies carried out on whole cells under bias. Here we u
6. Opposites Attract, Muons as Direct Probes for Iodide Diffusion in Methyl Ammonium Lead Iodide
D. W. Ferdani, A. L. Johnson, S. E. Lewis, P. J. Baker, P. J. Cameron; arXiv preprint
The volume of research into organo-lead hailde perovskites is increasing rapidly, with perovskite solar cell efficiencies reaching as high as 22 percent. There is considerable evidence that mobile ions in the perovskite strongly influence the properties of the solar cell, with the majority of studies carried out on whole cells under bias. Here we u

Other Research

7. Defect-Induced Magnetic Skyrmion in Two-Dimensional Chromium Tri-Iodide Monolayer
Ryan A. Beck, Lixin Lu, Peter V. Sushko, Xiaodong Xu, Xiaosong Li; arXiv preprint
Chromium iodide monolayers, which have different magnetic properties in comparison to the bulk chromium iodide, have been shown to form skyrmionic states in applied electromagnetic fields or in Janus-layer devices. In this work, we demonstrate that spin-canted solutions can be induced into monolayer chromium iodide by select substitution of iodide
8. Defect-Induced Magnetic Skyrmion in Two-Dimensional Chromium Tri-Iodide Monolayer
Ryan A. Beck, Lixin Lu, Peter V. Sushko, Xiaodong Xu, Xiaosong Li; arXiv preprint
Chromium iodide monolayers, which have different magnetic properties in comparison to the bulk chromium iodide, have been shown to form skyrmionic states in applied electromagnetic fields or in Janus-layer devices. In this work, we demonstrate that spin-canted solutions can be induced into monolayer chromium iodide by select substitution of iodide

Conclusion

The research literature on (+)-Magnoflorine Iodide demonstrates sustained scientific interest, with publications continuing through 0. The compound serves as an important building block in synthetic chemistry and has been explored for various applications. Researchers and industrial users can view detailed specifications or submit an inquiry for pricing and availability.

Data Sources: PubMed/MEDLINE, CrossRef. 8 papers analyzed. Last updated: 2026-05-25. This article is automatically generated from peer-reviewed research data.