Program Highlights

Conductive polymers, i.e. plastics, that conduct electricity, are important in science and technology as they offer the potential for cheap, flexible electronic devices. This work examines the mechanisms by which electrons are transported in such materials, a process that remains far from understood. One of the main results of the work is that the behavior of such materials, at very high densities of charge carriers, is radically different to simple expectations.

New technique produces heterojunctions in single-atom-thick graphene

Many of today’s electronic devices, including solar cells and transistors, are based on heterojunctions — precisely sculpted, atomic-scale interfaces between different materials. To reach the ultimate limit in miniaturization, scientists must learn to make these near-perfect unions in materials that are only a single atom in thickness.

Self-replication is ubiquitous in the living world but artificial self-replication has been elusive. We have developed a process for self-replication of an arbitrary seed made from nanometer scale DNA tiles. The tiles are constructs of 10 DNA strands which form a bent triple helix, BTX, with four lateral single strands -- ‘sticky ends’ -- for recognition and hybridization with complementary tiles, and six longitudinal sticky ends for joining tiles to form a sequence.

In 2008 The Penn MRSEC assisted a high school science teacher, Schuyler Patton, to prepare a year-long elective course on materials science for his high school, Central HS, Philadelphia. It started with one class of 33 students and it was very successful. In 2010-11, it was expanded to two sections with 66 students. In summer 2010, the Penn MRSEC offered a series of three hands-on workshops for teachers based on the laboratory experiments used in this course. The themes of these workshops were a) thermal properties and b) mechanical properties.