Rationally Designed Polyimides for High-Energy Density Capacitor Applications

Development of new dielectric materials is of great importance for a wide range of applications for modern electronics and electrical power systems. The state-of-the-art polymer dielectric is a biaxially oriented polypropylene (BOPP) film having a maximal energy density of 5 J<b>/</b>cm³ and a high breakdown field of 700 MV/m, but with a limited dielectric constant (∼2.2) and a reduced breakdown strength above 85 °C. Great effort has been put into exploring other materials to fulfill the demand of continuous miniaturization and improved functionality. In this work, a series of polyimides were investigated as potential polymer materials for this application. Polyimide with high dielectric constants of up to 7.8 that exhibits low dissipation factors (<1%) and high energy density around 15 J<b>/</b>cm³, which is 3 times that of BOPP, was prepared. Our syntheses were guided by high-throughput density functional theory calculations for rational design in terms of a high dielectric constant and band gap. Correlations of experimental and theoretical results through judicious variations of polyimide structures allowed for a clear demonstration of the relationship between chemical functionalities and dielectric properties

Rational Design of Organotin Polyesters

Large dielectric constant and band gap are essential for insulating materials used in applications such as capacitors, transistors and photovoltaics. Of the most common polymers utilized for these applications, polyvinyldiene fluoride (PVDF) offers a good balance between dielectric constant, >10, and band gap, 6 eV, but suffers from being a ferroelectric material. Herein, we investigate a series of aliphatic organotin polymers, p­[DMT­(CH₂)<i>_n</i>], to increase the dipolar and ionic part of the dielectric constant while maintaining a large band gap. We model these polymers by performing first-principles calculations based on density functional theory (DFT), to predict their structures, electronic and total dielectric constants and energy band gaps. The modeling and experimental values show strong correlation, in which the polymers exhibit both high dielectric constant, ≥5.3, and large band gap, ≥4.7 eV with one polymer displaying a dielectric constant of 6.6 and band gap of 6.7 eV. From our work, we can identify the ideal amount of tin loading within a polymer chain to optimize the material for specific applications. We also suggest that the recently developed modeling methods based on DFT are efficient in studying and designing new generations of polymeric dielectric materials

Synthesis of Nirmatrelvir: Development of an Efficient, Scalable Process to Generate the Western Fragment

Nirmatrelvir (1), a novel and specific inhibitor of the SARS-CoV-2 3C-like protease, was developed by Pfizer scientists in mid 2020. Efforts to develop a scalable process to manufacture nirmatrelvir were undertaken with a great sense of urgency, as there were no effective treatments available for the worldwide patient population at that time. We used a convergent approach to generate this molecule. The first two steps used to generate the western fragment of nirmatrelvir from l-tert-leucine, ethyl trifluoroacetate, and a [3.1.0] bicyclic proline derivative are described here. This is the first of a series of four papers describing the commercial process of the development of nirmatrelvir