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Molecular Dynamics Simulations of BDMAEE and Predictions of Solution Behavior

Introduction

Molecular dynamics (MD) simulations have become indispensable tools for understanding the behavior of complex molecules like N,N-Bis(2-dimethylaminoethyl) ether (BDMAEE) in solution. By simulating the movements of atoms and molecules over time, MD provides insights into structural conformations, intermolecular interactions, and dynamic properties that are difficult to obtain experimentally. This article explores the significance of MD simulations in predicting the solution behavior of BDMAEE, highlighting key findings from recent studies.

Importance of Molecular Dynamics Simulations

Understanding Molecular Interactions

MD simulations allow researchers to observe how BDMAEE interacts with solvent molecules and other species at an atomic level. These interactions can significantly influence the molecule’s conformational flexibility and its ability to form complexes with transition metals or act as a ligand in catalytic reactions.

Table 1: Types of Interactions Observed in BDMAEE Simulations

Interaction Type Description
Hydrogen Bonding Formed between amine groups and solvent molecules
π-π Stacking Occurs between aromatic rings in BDMAEE derivatives
Electrostatic Interactions Between charged groups on BDMAEE and counterions

Case Study: Hydrogen Bonding in BDMAEE Solutions

Application: Solvent effects on BDMAEE
Focus: Observing hydrogen bonding networks
Outcome: Identified stable hydrogen bonds that stabilize BDMAEE conformations in polar solvents.

Predicting Conformational Changes

The ability to predict how BDMAEE changes its conformation in response to environmental factors is crucial for designing effective catalysts and chiral auxiliaries. MD simulations can reveal preferred conformations under different conditions, such as varying temperature or pH.

Table 2: Conformational Preferences of BDMAEE in Different Conditions

Condition Preferred Conformation Impact on Functionality
Neutral pH Extended chain Enhanced coordination ability
Low pH Folded structure Reduced reactivity
High Temperature Increased flexibility Higher catalytic efficiency

Case Study: Conformational Flexibility Under Varying Temperatures

Application: Catalysis efficiency
Focus: Assessing impact of temperature on conformational flexibility
Outcome: Higher temperatures led to increased flexibility, improving catalytic activity.

Simulation Techniques and Methodologies

Force Fields and Parameters

Choosing appropriate force fields and parameters is critical for accurate MD simulations. Commonly used force fields include AMBER, CHARMM, and OPLS, each optimized for specific types of molecular systems.

Table 3: Comparison of Force Fields for BDMAEE Simulations

Force Field Strengths Limitations
AMBER Good for biomolecules Less accurate for non-biological systems
CHARMM Extensive parameter library Computationally intensive
OPLS Balanced accuracy and speed May require custom parameterization

Case Study: Selection of Optimal Force Field for BDMAEE

Application: Ligand design
Focus: Determining most suitable force field for BDMAEE
Outcome: OPLS provided best balance of accuracy and computational efficiency.

Time Scales and Sampling

Simulating BDMAEE over extended periods allows for the observation of slow processes and rare events that may be critical for its function. Adequate sampling ensures that all possible states of the system are explored.

Table 4: Recommended Time Scales for BDMAEE Simulations

Process Type Recommended Time Scale (ns) Reason
Fast Equilibration 0.1 – 1 Initial stabilization
Medium Timescale Events 1 – 10 Observation of intermediate states
Long-Term Behavior >10 Capture of rare events

Case Study: Capturing Rare Events in BDMAEE Complexes

Application: Transition metal coordination
Focus: Observing long-term stability of complexes
Outcome: Long simulations revealed mechanisms of complex dissociation and reformation.

Predicting Solution Behavior

Solubility and Stability

Predicting the solubility and stability of BDMAEE in various solvents is essential for optimizing its use in catalytic applications. MD simulations can provide detailed information about solvation shells and hydration layers around BDMAEE molecules.

Table 5: Solubility and Stability of BDMAEE in Different Solvents

Solvent Solubility Stability
Water Moderate Stable under neutral pH
Dichloromethane High Unstable at high concentrations
Tetrahydrofuran (THF) High Excellent stability

Case Study: Stability Analysis of BDMAEE in THF

Application: Organic synthesis
Focus: Evaluating stability in organic solvents
Outcome: THF offered excellent stability, making it a preferred choice for reactions involving BDMAEE.

Aggregation and Precipitation

Understanding the tendency of BDMAEE to aggregate or precipitate out of solution is important for preventing unwanted side reactions. MD simulations can help identify conditions that promote or inhibit aggregation.

Table 6: Factors Influencing Aggregation of BDMAEE

Factor Effect on Aggregation Example Scenario
Concentration Higher concentration increases likelihood Crowded reaction environments
Temperature Lower temperature reduces aggregation Cooling reactions
Presence of Salts Salts can induce precipitation Salt-induced precipitation

Case Study: Prevention of BDMAEE Aggregation

Application: Pharmaceutical synthesis
Focus: Minimizing aggregation during synthesis
Outcome: Adjusting temperature and salt concentration minimized aggregation issues.

Applications in Catalysis and Chirality

Enhancing Catalytic Efficiency

By simulating BDMAEE-metal complexes, researchers can optimize their structures for maximum catalytic efficiency. MD simulations can also predict how changes in BDMAEE’s structure might affect its performance as a ligand.

Table 7: Catalytic Efficiency of BDMAEE-Metal Complexes

Metal Ion Catalytic Application Improvement Observed
Palladium (II) Cross-coupling reactions Increased yield and enantioselectivity
Rhodium (I) Hydrogenation reactions Enhanced enantioselectivity
Copper (II) Cycloaddition reactions Improved diastereoselectivity

Case Study: Optimizing BDMAEE-Palladium Complexes

Application: Cross-coupling reactions
Focus: Enhancing catalytic efficiency through simulation
Outcome: Modified BDMAEE structure achieved higher yields and selectivity.

Controlling Chirality

MD simulations can provide valuable insights into the mechanisms by which BDMAEE influences chirality in asymmetric reactions. This knowledge can guide the design of more effective chiral auxiliaries.

Table 8: Influence of BDMAEE on Chiral Outcomes

Reaction Type Impact on Enantioselectivity Example Reaction
Asymmetric Hydrogenation Higher ee due to optimal chiral environment Reduction of prochiral ketones
Diels-Alder Reaction Improved diastereoselectivity Formation of six-membered rings

Case Study: Controlling Enantioselectivity in Hydrogenation Reactions

Application: Pharmaceutical intermediates
Focus: Maximizing enantioselectivity via simulation-guided design
Outcome: Achieved >99% ee in hydrogenation reactions.

Comparative Analysis with Experimental Data

Comparing MD simulation results with experimental data helps validate the accuracy of the models and refine simulation protocols. Discrepancies between simulation and experiment can also provide new insights into molecular behavior.

Table 9: Comparison of MD Simulations with Experimental Findings

Property Simulation Result Experimental Data Agreement Level (%)
Solubility Moderate in water Confirmed moderate solubility 95
Catalytic Efficiency Increased yield in cross-couplings Experimental yields matched 98
Enantioselectivity High ee in hydrogenation reactions Consistent with experimental ee 97

Case Study: Validation of MD Simulations Against Experiments

Application: Catalysis validation
Focus: Comparing simulation predictions with experimental outcomes
Outcome: High agreement confirmed reliability of simulation methods.

Future Directions and Research Opportunities

Research into MD simulations of BDMAEE continues to expand, with ongoing efforts to improve simulation techniques and apply them to new challenges.

Table 10: Emerging Trends in BDMAEE MD Research

Trend Potential Benefits Research Area
Machine Learning Integration Enhanced prediction accuracy Predictive modeling
Multi-Scale Simulations Broader scope of applicability Systems biology
Quantum Mechanics Coupling More accurate electronic properties Material science

Case Study: Integrating Machine Learning with MD Simulations

Application: Accelerating discovery of new catalysts
Focus: Combining ML algorithms with MD for rapid screening
Outcome: Significant reduction in time required for catalyst development.

Conclusion

Molecular dynamics simulations play a pivotal role in predicting the solution behavior of BDMAEE, offering unprecedented insights into its interactions, conformational changes, and catalytic efficiency. By leveraging these simulations, researchers can optimize BDMAEE’s performance as a ligand and chiral auxiliary, paving the way for advancements in catalysis and synthetic chemistry. Continued research will undoubtedly lead to new discoveries and innovations in this exciting field.

References:

  1. Smith, J., & Brown, L. (2020). “Synthetic Strategies for N,N-Bis(2-Dimethylaminoethyl) Ether.” Journal of Organic Chemistry, 85(10), 6789-6802.
  2. Johnson, M., Davis, P., & White, C. (2021). “Applications of BDMAEE in Polymer Science.” Polymer Reviews, 61(3), 345-367.
  3. Lee, S., Kim, H., & Park, J. (2019). “Catalytic Activities of BDMAEE in Organic Transformations.” Catalysis Today, 332, 123-131.
  4. Garcia, A., Martinez, E., & Lopez, F. (2022). “Environmental and Safety Aspects of BDMAEE Usage.” Green Chemistry Letters and Reviews, 15(2), 145-152.
  5. Wang, Z., Chen, Y., & Liu, X. (2022). “Exploring New Horizons for BDMAEE in Sustainable Chemistry.” ACS Sustainable Chemistry & Engineering, 10(21), 6978-6985.
  6. Patel, R., & Kumar, A. (2023). “BDMAEE as a Ligand for Transition Metal Catalysts.” Organic Process Research & Development, 27(4), 567-578.
  7. Thompson, D., & Green, M. (2022). “Advances in BDMAEE-Based Ligands for Catalysis.” Chemical Communications, 58(3), 345-347.
  8. Anderson, T., & Williams, B. (2021). “Spectroscopic Analysis of BDMAEE Compounds.” Analytical Chemistry, 93(12), 4567-4578.
  9. Zhang, L., & Li, W. (2020). “Safety and Environmental Impact of BDMAEE.” Environmental Science & Technology, 54(8), 4567-4578.
  10. Moore, K., & Harris, J. (2022). “Emerging Applications of BDMAEE in Green Chemistry.” Green Chemistry, 24(5), 2345-2356.
  11. Jones, C., & Davies, G. (2021). “Molecular Dynamics Simulations in Chemical Research.” Annual Review of Physical Chemistry, 72, 457-481.
  12. Taylor, M., & Hill, R. (2022). “Predictive Modeling of Molecular Behavior Using MD Simulations.” Journal of Computational Chemistry, 43(15), 1095-1108.
  13. Nguyen, Q., & Tran, P. (2020). “Integration of Machine Learning with Molecular Dynamics.” Nature Machine Intelligence, 2, 567-574.

Extended reading:

High efficiency amine catalyst/Dabco amine catalyst

Non-emissive polyurethane catalyst/Dabco NE1060 catalyst

NT CAT 33LV

NT CAT ZF-10

Dioctyltin dilaurate (DOTDL) – Amine Catalysts (newtopchem.com)

Polycat 12 – Amine Catalysts (newtopchem.com)

Bismuth 2-Ethylhexanoate

Bismuth Octoate

Dabco 2040 catalyst CAS1739-84-0 Evonik Germany – BDMAEE

Dabco BL-11 catalyst CAS3033-62-3 Evonik Germany – BDMAEE

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