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Highlights

Highlights

Fabrication of hybrid nanorods. Low- (lower left) and high- (lower right) resolution SEM images, of hybrid nanorod arrays before release. Upper right, SEM image of released hybrid nanorods. Red arrows highlight nanorods sitting on the substrate on their sides.
Fabrication of hybrid nanorods. Low- (lower left) and high- (lower right) resolution SEM images, of hybrid nanorod arrays before release. Upper right, SEM image of released hybrid nanorods. Red arrows highlight nanorods sitting on the substrate on their sides.
Oct 26, 2018
UPENN Materials Research Science and Engineering Centers

High-strength magnetically switchable plasmonic nanorods

M. Zhang, D.J. Magagnosc, I. Liberal, Y. Yu, H. Yun, H. Yang, Y. Wu, J. Guo, W. Chen, Y.J. Shin, A. Stein, J.M. Kikkawa, N. Engheta, D.S. Gianola, C.B. Murray, C.R. Kagan, Nature Nanotechnology 12, 2017
Next-generation 'smart' nanoparticle systems should be precisely engineered in size, shape and composition to introduce multiple functionalities, unattainable from a single material. Bottom-up chemical methods are prized for the synthesis of crystalline nanoparticles, i.e., nanocrystals with size-and shape-dependent physical properties, but they are less successful in achieving multifunctionality. Top-down lithographic methods can produce multifunctional nanoparticles with precise size and shape control, yet this approach becomes increasingly difficult at sizes of order 10 nm.
Schematic of glass films formed by physical vapor deposition. Image source: Felice Macera
Schematic of glass films formed by physical vapor deposition. Image source: Felice Macera
Oct 26, 2018
UPENN Materials Research Science and Engineering Centers

Birefringent Stable Glasses with Predominantly Isotropic Molecular Orientation

Zahra Fakhraai and Jay Kikkawa, IRG3, University of Pennsylvania
Stable glasses produced by physical vapor deposition are important to understand. They exhibit optical birefringence, which traditionally implies that the constituent molecules are aligned.
Oct 26, 2018
UPENN Materials Research Science and Engineering Centers

Janus dendrimersomes as models for cell fusion and fission.

Virgil Percec, Michael Klein, Dan Hammer, and Tobias Baumgart, IRG2, University of Pennsylvania & Temple University
Vesicle fusion and fission processes often occur in biological systems, usually with the aid of specialized proteins. Percec, Klein, Hammer, and Baumgart carried out comprehensive fusion/fission experiments based on three membrane ingredients: hydrogenated (RH), fluorinated (RF), and hybrid-hydrogenated/fluorinated (RHF) Janus dendrimers (Figure – Top Left).
Focal conic domains (FCDs) form on inner surfaces of spherical shells filled with cholesteric LC. Image source: Lisa Tran
Focal conic domains (FCDs) form on inner surfaces of spherical shells filled with cholesteric LC. Image source: Lisa Tran
Oct 26, 2018
UPENN Materials Research Science and Engineering Centers

Shells of Cholesteric Liquid Crystals

Daeyeon Lee, Kathleen Stebe, and Randall Kamien, IRG1, University of Pennsylvania
Liquid crystals, fluids with aligned phases of rod-like constituent molecules, are used in everything from computer and television displays to mood rings. “Handedness” or chirality, is ubiquitous in complex biological systems and can be controlled and quantified in synthetic materials such as cholesteric liquid crystals.
Fig. 1 (top) shows yield stress vs modulus for disordered solids (IRG 1 data) and crystalline solids (balloons). Remarkably, the yield stress is tightly distributed around 3% for systems spanning over 13 decades in modulus. Fig. 1 (bottom) shows the size of rearrangements vs particle size for 6 systems (3 experimental, 3 computational) spanning nearly 7 orders of magnitude of particle size. Inset shows that the size (exponential length scale) of rearrangements is universally about one particle diameter at low strains.
Fig. 1 (top) shows yield stress vs modulus for disordered solids (IRG 1 data) and crystalline solids (balloons). Remarkably, the yield stress is tightly distributed around 3% for systems spanning over 13 decades in modulus. Fig. 1 (bottom) shows the size of rearrangements vs particle size for 6 systems (3 experimental, 3 computational) spanning nearly 7 orders of magnitude of particle size. Inset shows that the size (exponential length scale) of rearrangements is universally about one particle diameter at low strains.
Jun 27, 2018
UPENN Materials Research Science and Engineering Centers

Universal Signatures of Plasticity in a Wide Range of Disordered Solids

Paulo E. Arratia (MEAM), Robert W. Carpick (MEAM), Doug Durian (Physics & Astronomy), Zahra Fakhraai (Chemistry), Daeyeon Lee (CBE), Robert A. Riggleman (CBE), Kevin T. Turner (MEAM), Arjun G. Yodh (Physics & Astronomy), Andrea Liu (Physics & Astronomy), University of Pennsylvania
Researchers explore approaches to increase the toughness of disordered materials that are otherwise prone to fail in a catastrophic, brittle fashion.
Sophia Siefert working with students from Girard College and Pennsylvania School for the Deaf as they explore different types of materials. Image source: © Felice Macera
Sophia Siefert working with students from Girard College and Pennsylvania School for the Deaf as they explore different types of materials. Image source: © Felice Macera
Jun 27, 2018
UPENN Materials Research Science and Engineering Centers

Middle School Summer Program: Girard College and Pennsylvania School for the Deaf

The summer camp was conceived, planned, and run by Mark Licurse and Sophia Siefert of the University of Pennsylvania MRSEC’s Education and Outreach group, with help from Professor Eric Detsi (MSE), an African American faculty member at Penn with special interest in the school for the deaf.
Students from Girard College and the Pennsylvania School for the Deaf participate in lab experiments, materials science lessons, and visits to various Penn facilities. The primary purpose of the program is to introduce URG students to STEM at an early age. 
Predictive model of the static structure and the evolution of the system.
Predictive model of the static structure and the evolution of the system.
Jun 8, 2018
UChicago Materials Research Center (2014)

Tunable nechanics and dynamics in biopolymer-based nematic materials

David Kovar and Gregory Voth groups
At the University of Chicago MRSEC, we have shown that building blocks of the biopolymers, actin and microtubule, form lyotropic liquid crystals with controllable structure and mechanics.
Rabi-swap pulse sequence. The qubit and resonator interact for a time τ , and the qubit state is then measured.
Rabi-swap pulse sequence. The qubit and resonator interact for a time τ , and the qubit state is then measured.
Jun 8, 2018
UChicago Materials Research Center (2014)

Quantum control of surface acoustic wave phonons

K. J. Satzinger, Y. P. Zhong, H.-S. Chang, G. A. Peairs, A. Bienfait, Ming-Han Chou, A. Y. Cleland, C. R. Conner, E. Dumur, J. Grebel, I. Gutierrez, B. H. November, R. G. Povey, S. J. Whiteley, D. D. Awschalom, D. I. Schuster, A. N. Cleland
The University of Chicago MRSEC has used super-conducting circuits and piezo-electricity to manipulate single phonons in a surface acoustic wave resonator (SAW).
MRSEC representatives and conference attendees interact at the International Materials Research Congress in Cancun, Mexico.
MRSEC representatives and conference attendees interact at the International Materials Research Congress in Cancun, Mexico.
Jun 5, 2018
Northwestern Materials Research Science and Engineering Center

NSF-MRSEC Booth at the International Materials Research Congress
Following a successful inaugural year in 2016, a NSF-MRSEC booth was again featured at the XXVI International Materials Research Congress (IMRC) in Cancun, Mexico on August 19-25, 2017 to increase awareness, promote international collaboration, and broaden participation from traditionally underrepresented groups in the National Science Foundation Materials Research Science and Engineering Center (NSF-MRSEC) program. Dr. William Kung (Northwestern University), Ms. Michelle McCombs (Ohio State University), and Ms.
Research Experience for Teachers (RET) participants with the RET Program Director, Professor Lincoln Lauhon (left).
Research Experience for Teachers (RET) participants with the RET Program Director, Professor Lincoln Lauhon (left).
Jun 5, 2018
Northwestern University Materials Research Science and Engineering Center (2017)

Research Experience for Teachers
Since its inception in 1992, the NU-MRSEC has offered the Research Experience for Teachers (RET) program each summer to middle-school, high-school, and community-college teachers with the principal goals of engaging them in research, developing a network of scientific colleagues, learning about new scientific and technological developments, and transferring this knowledge to the classroom. Concurrent with their summer research, teachers develop a related curriculum project to be implemented in their classrooms and shared with colleagues and administrators.

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