The disclosure describes new compositions and methods related to polyaminals and related polymers. The compositions are useful as therapeutic/drug conjugates, self-healing materials, reversible crosslinking materials, degradable hydrogels, protective coatings, and as metal scavenging agents. New atom efficient synthetic schemes are disclosed, which yield previously unobtainable high molecular weight polyaminals.

The disclosure describes new compositions and methods related to polyaminals and related polymers. The compositions are useful as therapeutic/drug conjugates, self-healing materials, reversible crosslinking materials, degradable hydrogels, protective coatings, and as metal scavenging agents. New atom efficient synthetic schemes are disclosed, which yield previously unobtainable high molecular weight polyaminals.

Methods and materials for patterning a substrate are disclosed herein. A poly(thioaminal) material may be utilized as a thermal resist material for patterning substrates in a thermal scanning probe lithography process. The poly(thioaminal) material may be functionalized with an electron withdrawing group and various monomers may be volatilized upon exposure to a thermal scanning probe.

Methods and materials for patterning a substrate are disclosed herein. A poly(thioaminal) material may be utilized as a thermal resist material for patterning substrates in a thermal scanning probe lithography process. The poly(thioaminal) material may be functionalized with an electron withdrawing group and various monomers may be volatilized upon exposure to a thermal scanning probe.

The disclosure describes new compositions and methods related to polyaminals and related polymers. The compositions are useful as therapeutic/drug conjugates, self-healing materials, reversible crosslinking materials, degradable hydrogels, protective coatings, and as metal scavenging agents. New atom efficient synthetic schemes are disclosed, which yield previously unobtainable high molecular weight polyaminals.

The disclosure describes new compositions and methods related to polyaminals and related polymers. The compositions are useful as therapeutic/drug conjugates, self-healing materials, reversible crosslinking materials, degradable hydrogels, protective coatings, and as metal scavenging agents. New atom efficient synthetic schemes are disclosed, which yield previously unobtainable high molecular weight polyaminals.

To provide a polymer excellent enough in photoelectric 5 conversion efficiency and in light resistance to be suitable for solar cells, also to provide a solar cell using the polymer, and further to provide an electronic product comprising the cell. Embodiments of the present disclosure provide a polymer comprising a repeating unit of the following formula (M1). ##STR00001##
In the formula, R.sup.1 is a substituent group selected from the group 15 consisting of alkyl groups, and alkoxy groups; each R.sup.2 is independently a substituent group selected from the group consisting of hydrogen, halogen, alkyl groups, alkoxy groups, and aryl groups; and each X is independently an atom selected from the group consisting of O, S and Se. The embodiments 20 also provide a solar cell having an active layer containing the above polymer and further an electronic product comprising that cell.

To provide a polymer excellent enough in photoelectric 5 conversion efficiency and in light resistance to be suitable for solar cells, also to provide a solar cell using the polymer, and further to provide an electronic product comprising the cell. Embodiments of the present disclosure provide a polymer comprising a repeating unit of the following formula (M1). ##STR00001##
In the formula, R.sup.1 is a substituent group selected from the group 15 consisting of alkyl groups, and alkoxy groups; each R.sup.2 is independently a substituent group selected from the group consisting of hydrogen, halogen, alkyl groups, alkoxy groups, and aryl groups; and each X is independently an atom selected from the group consisting of O, S and Se. The embodiments 20 also provide a solar cell having an active layer containing the above polymer and further an electronic product comprising that cell.

Methods and materials for patterning a substrate are disclosed herein. A poly(thioaminal) material may be utilized as a thermal resist material for patterning substrates in a thermal scanning probe lithography process. The poly(thioaminal) material may be functionalized with an electron withdrawing group and various monomers may be volatilized upon exposure to a thermal scanning probe.

Methods and materials for patterning a substrate are disclosed herein. A poly(thioaminal) material may be utilized as a thermal resist material for patterning substrates in a thermal scanning probe lithography process. The poly(thioaminal) material may be functionalized with an electron withdrawing group and various monomers may be volatilized upon exposure to a thermal scanning probe.