1. Focused Research Group Two-gap Superconductivity in Bulk Form Magnesium Diboride and its Implications for Applications David C. Larbalestier, University of Wisconsin-Madison, DMR 0514592 & FSU A collaboration between groups at Arizona State University (Nate Newman and John Rowell),, Pennsylvania State University (Zi-Kui Liu and Xiaoxing Xi), the University of Puerto Rico at Mayaguez, and the University of Wisconsin (Eric Hellstrom*, David Larbalestier* and Paul Voyles) *now at the National High Magnetic Field Laboratory, Florida State University 5 two page nuggets of the recent FRG work follow Tuning the superconducting properties of MgB 2 by doping using mechanical alloying MgO Platelets in Doped MgB 2 Thin Films Thermodynamic Modeling of Mg-B-C system Effects of oxygen incorporation on Tc, Jc, & Hc2 of MgB 2 films Accomplishments for Science is Fun - magnetism ASU Outreach Progress : Science is Fun

2. Tuning the superconducting properties of MgB 2 by doping using mechanical alloying E. Hellstrom, D. Larbalestier (FSU) and O. Uwakweh (UPRM) DMR-05-14592 (FRG) The two-gap superconductivity in MgB 2 offers the possibility to tune MgB 2 ’s superconducting properties by doping on the Mg and B sites. We used high-energy ball milling to mechanically alloy MgB 2 with C and other metal diborides (MeB 2 ). We found that milling has the added advantages of reducing the MgB 2 grain size, which can increase pinning, and creating strain in the grains, which increases H c2. C milled into MgB 2 in <60 min. Milling C into MgB 2 increased H c2 to ~37 T at 0K. The maximum C content with HIPping at 1000  C is ~ x = 0.04 (in Mg(B 1-x C x ) 2 ). Our first exploratory milling of MeB 2 (Me = Al, Ta, V, Zr) into MgB 2 showed that AlB 2 mills into MgB 2. In contrast, TaB 2, VB 2, and ZrB 2 do not alloy to an appreciable extent even when consolidating the milled powder in a HIP at 1000C. The other commercially-available MeB 2 s (Me = Cr, Nb, Ti) are currently being investigated in the ongoing collaboration between UPRM and FSU to evaluate how they alloy with MgB 2. J c highest for 1200 min milling at > 5T (15K). Nominal composition Mg(B 0.96 C 0.04 ) 2 ) J c highest for 600 min milling at > 5T (4.2K). Overall composition is 0.95 MgB 2 + 0.05 TaB 2. C doping TaB 2 doping

3. Tuning the superconducting properties of MgB 2 by doping using mechanical alloying E. Hellstrom, D. Larbalestier (FSU) and O. Uwakweh (UPRM) DMR-05-14592 (FRG) A strength of the ongoing collaboration between UPRM and FSU on MgB 2 is the student exchange. This past year three students from UPRM came to FSU (and UW-Madison) to work on MgB 2 : Richard Perez and Yenny Cardona who are graduate students, and Pedro Vargas who is an undergraduate student. Richard Perez also overlapped with Prof. Durval Rodrigues from the University of Sao Paulo-Lorena, Brazil, who spent an 18 month sabbatical leave at UW-Madison working on MgB 2. There was an interesting interflow of knowledge and expertise as a result of our student exchanges. Two years ago Perez helped refurbish an old glove box while at UW-Madison that was subsequently sent to UPRM for MgB 2 work. This past summer, Pedro Vargas, the undergrad who helps maintain the box at UPRM, spent part of his summer at FSU helping refurbish an old glove box for MgB 2 work at FSU. Pedro Vargas, a UPRM undergrad who works with Uwakweh spent summer 2007 as an REU student working on MgB 2 with Hellstrom and Larbalestier at FSU. Yenny Cardona (UPRM), Jian Zhou (FSU), and Richard Perez (UPRM) in front of the hot isostatic press (HIP) at FSU. These graduate students have worked together on the high- energy milling experiments.

4. MgO Platelets in Doped MgB 2 Thin Films Paul M. Voyles (U. Wisconsin-Madison), DMR-0514592 Superconducting magnesium diboride (MgB 2 ) has the potential for applications in NMR, MRI, and high-field magnets, provided that the origins of the exceptional properties of some carbon- doped thin films can be understood. We have studied MgB 2 thin films deposited using methane gas as the source of carbon. In addition to carbon doping, these films contain nanoscale MgO platelets within the MgB 2 layer. These platelets are associated both with increased upper critical magnetic field enhanced vortex pinning. A plausible cause in both cases is the strain introduced into the boron planes. Figure: (top left) Z-contrast STEM image, (top right) High-resolution TEM image, and (bottom) EELS spectrum from a C-doped MgB 2 thin film with MgO platelet inclusions. O B 10 nm SiC MgB 2 MgO SiC MgB 2 MgO

5. International Collaboration on Superconducting MgB 2 Paul M. Voyles (U. Wisconsin-Madison), DMR-0514592 As part of an international collaboration between the FRG on MgB 2 and the University of Genoa, the University of Naples, and the Italian national laboratory CNR-INFM, we have studied the defects introduced into high quality thin films of MgB 2 by neutron irradiation. The Italian groups have shown that irradiation causes merging of the two superconducting gaps. We showed it destroys the crystal lattice in pockets of the MgB 2 a few nanometers in diameter, rendering them amorphous. Voyles visited Genoa in June to promote this collaboration. Please insert an image or group of images here to illustrate your broader impacts activities. If you need more space, you may reduce the adjacent textbox. Please use lettering that is clearly visible (i.e. not too small). Please include a brief figure caption. SiC MgB 2 amorphous pocket

6. Thermodynamic Modeling of Mg-B-C system Prof. Zi-Kui Liu, The Pennsylvania State University DMR-0514592 Using CALculation of PHAse Diagram (CALPHAD) approach, we developed thermodynamic database for Mg-B-C system to understand thin films produced by Hybrid Physical-Chemical Vapor Deposition process (HPCVD). From isothermal section at 1000 K and ~1 torr (condition for growth thin films with HPCVD process) of the Mg-B-C ternary phase diagram, we predicted that the maximum solubility of carbon in MgB 2 is less than 7%. The predicted carbon solubility is in agreement with the experimental value mention in App. Phys. Lett., 91 (082513) 2007. Based on the predicted phase equilibrium between MgB 2 and C, we used the elastic constants from our first-principles calculations to predict the lattice parameter behavior of carbon- doped MgB 2 thin films. Isothermal section of ternary phase diagram of Mg- B-C system at 1000 K and ~1 torr. Preliminary result from the prediction of lattice parameter of carbon-doped MgB 2 thin films with the elastic effect.

7. Future work: Using current work as a guideline, we can focus on the elements that might have significant effects on MgB 2 and develop the thermodynamic database for those potential system. Phases Research Lab: Our group have three undergraduate students, seven graduate students and Three research fellows working on various projects such as magnesium alloys, aluminum alloys, boride, Ni- based superalloys, perovskite oxide and diffusion in intermetallic. Pure MgB 2 have a high Tc (39 K) but other superconducting properties such as Hc2 or Jc values are still small. Doping MgB 2 with various different elements help improve those properties. Our current work is focus on creating a guideline for possible effects upon doping MgB 2 with those elements from the first-principles calculations. Current work: Explore the effects of doping MgB 2 with various elements ( > 40 elements) from first-principles calculation. Enthalpy of formation for doped MgB 2 with various elements Thermodynamic Modeling of Mg-B-C system Prof. Zi-Kui Liu, The Pennsylvania State University DMR-0514592

8. Novel route to obtain high H c2 s by depositing films on low temperature substrates & then annealing at low temperatures. slopes dH c2 /d T are often larger than 1.5T/K (i.e. H c2 s potentially >50 T) This work suggests that to increase H c2 in MgB 2, maximum scattering must be achieved in materials with T c of say 30 to 33K. Results suggest that today the MgB 2 wire manufacturers are using reaction temperatures that are far too high to achieve necessary carrier scattering in MgB 2. Achieving high Hc2 by thermal processing of MgB 2 deposited on low temperature substrates N. Newman and J.M. Rowell, Arizona State University - DMR-0514592

9. Effects of oxygen incorporation on Tc, Jc, & Hc2 of MgB 2 films N. Newman and J.M. Rowell, Arizona State University DMR-0514592 Research impact: Oxygen incorporated in situ and ex situ Very high J c & H c2 (~ 3x10 5 A/cm 2 at 8 T and 4.2 K ) dHc 2 /dT !! increases w/ oxygen concentration –as high as 1.5 T/K for dH c2 /dT & ~ 50 T for H c2 (0) oxygen distributed both in & between the grains. –While T c reduces, intra-grain resistivity increases w/ increased oxygen in sample. –Low inter-grain connectivity obtained by ex situ oxygen incorporation suggests grain boundaries preferentially oxidized Education: 7 graduate students & 4 undergraduates involved in MgB 2 research at ASU. R. Gandikota and L. Yu graduated in 2007. Jihoon Kim graduated in 2005. Societal impact: The high H c2 and J c values may enable production of high- field magnets for wide range of practical applications.

10. ● Two fast-paced, minds-on Science is Fun - Magnetism presentations have been developed with multiple explorations (15 and 45 minute presentations). The associated training materials have also been developed. ● The 15 minute magnetism presentation was so successful that components of both the 15 minute module and the 45 minute module have been incorporated into the daily science is fun standard demonstration that provides services to over 12000 students each year. ● Components of the presentations have been piloted with a diverse population of over 2,000 students with positive feedback: 65% Hispanic 13% Native American 6% Black ● The full 45 minute module was presented to over 2500 students between fall 2007 and spring 2008. Two-Gap Superconductivity in MgB 2 & its Implications for Applications ASU Outreach Progress : Science is Fun N. Newman (co-PI), David Wright & Michael McKelvy, Arizona State University, - DMR-0514592

11. The magnetism pilot, previously piloted to 4th grade students, has been expanded to include grades K-8 and is designed to meet Arizona State standards for those grades. Additionally, classroom materials have been developed for teachers to incorporate further activities on energy, magnetism and electricity. Minority groups that experience “ Science is Fun ” make up more than half of the student population served. Hispanic, Black/African, Asian/Pacific Islanders, and American Indian populations comprise 42.1%, 6.4%, 3.3%, and 2.6% respectively of the population served by the Science is Fun program. 48.8% of the student population served is comprised of female students. Collaborated with FRG partners to enhance outreach impact. Accomplishments for Science is Fun - magnetism ASU Outreach Progress : Science is Fun N. Newman (co-PI), David Wright & Michael McKelvy, Arizona State University, DMR-0514592