J.F. Pulecio
Wednesday, February 22, 2017
Session Chair - X50: Nanoscale Magnetic Dynamics, APS March Meeting 2017
I will be chairing a session Friday, March 17, 2017 on Nanoscale Magnetic Dynamics . Hope to see you there.
APS March Meeting 2017
SESSION TOPIC: ATOMIC, MOLECULAR AND OPTICAL (AMO) PHYSICS
http://meetings.aps.org/Meeting/MAR17/Session/T1.352
Figure: Expansion of Skyrmion Bubble with out-of-plane field pulses. |
Tuesday, November 1, 2016
61st Annual Conference on Magnetism and Magnetic Materials
I will be presenting some of work on Skyrmions at INTERMAG 2017. Check out the program here.
Figure: The different spin textures result from interlayer dipolar coupling, where N is the number of stack repetitions.
Wednesday, February 10, 2016
Large-Area Growth of Turbostratic Graphene on Ni(111) via Physical Vapor Deposition
Check out our publication on the growth of Turbostratic Graphene via physical vapor deposition.
Tuesday, November 10, 2015
Non-Boolean Computation w/Nanomagnets
Congratz to my former PhD advisor Dr. Sanjukta Bhanja who recently published and acknowledged the work we originated in Nature Nanotechnology.
Feature from NSF:
http://www.nsf.gov/news/news_summ.jsp?cntn_id=136758&org=NSF&from=ne
Check out the article here:
http://www.nature.com/nnano/journal/vaop/ncurrent/full/nnano.2015.245.html
Feature from NSF:
http://www.nsf.gov/news/news_summ.jsp?cntn_id=136758&org=NSF&from=ne
Check out the article here:
http://www.nature.com/nnano/journal/vaop/ncurrent/full/nnano.2015.245.html
Monday, May 4, 2015
Physicists - National Institute for Standard and Technology
I am excited to be joining the Nanoscale Spin Dynamics Group group at NIST. We will be working on understanding the unique spin physics in 2D materials. We will study spin inject and transport into materials, such as graphene, from a spin battery device.
Thursday, April 30, 2015
Thanks to the Nanostructure and EM group at BNL
I would like to thank Dr. Yimei Zhu, Dr. Dario Arena, and all my colleagues at Brookhaven National Laboratory for the excellent experience and opportunity to conduct world class research with such amazing people. I look forward to continuing our research collaborations and be in touch soon!
Monday, December 1, 2014
NRC Fellowship Awarded
I have been awarded the prestigious National Research Council Fellowship to pursue fundamental spin properties of 2D and low dimensional materials. Its my privilege to work with Dr. Mark Keller and Dr. Tom Silva in the Quantum Electromagnetic Division at the National Institute of Standards and Technology.
Monday, September 29, 2014
Symmetry breaking of magnetic vortices before annihilation (APL Cover)
Pulecio, J. F., Pollard, S. D., Warnicke, P., Arena, D. A., & Zhu, Y. (2014, September 29). Symmetry breaking of magnetic vortices before annihilation. Applied Physics Letters. AIP Publishing. doi:10.1063/1.4893422
Wednesday, May 14, 2014
Invited Panelist: 51st Design Automation Conference
I will be serving as an invited panelist at the 51st Design Automation Conference CRAW/CDC Workshop May 31st-June 1st. See the link below for more details:
http://www2.dac.com/events/eventdetails.aspx?id=170-277
http://www2.dac.com/events/eventdetails.aspx?id=170-277
Friday, May 2, 2014
Coherence and modality of driven interlayer-coupled magnetic vortices - Nature Communications
Pulecio, J. F., Warnicke, P., Pollard, S. D., Arena, D. A., & Zhu, Y. (2014). Coherence and modality of driven interlayer-coupled magnetic vortices. Nature Communications, 5, 3760. doi:10.1038/ncomms4760
Press Release: http://www.bnl.gov/newsroom/news.php?a=11635
Wednesday, November 6, 2013
Session Chair: 2013 MRS Fall Meeting
U2: Magnetic Nanostructures and Spin-Electron-Lattice Phenomena in Functional Materials
I will be chairing a technical session at the 2013 MRS Fall Meeting.
Tuesday, October 1, 2013
Book Chapter: Parallel Energy Minimizing Computation via Dipolar Coupled Single Domain Nanomagnets
Pulecio, J. F., Bhanja, S., & Sarkar, S. (2013). Parallel Energy Minimizing Computation via Dipolar Coupled Single Domain Nanomagnets. In J. E. Morris & K. Iniewski (Eds.), Nanoelectronic Device Applications Handbook (p. 940). CRC Press. Retrieved from http://www.crcpress.com/product/isbn/9781466565234
Sunday, September 1, 2013
2013 MRS Fall Meeting Talk
I will be presenting our work:
3:30 PM - U2.07 Topological Nature of Magnetic Vortices in Patterned Mesoscopic Disks
Functional magnetic materials have garnered interest due to the potential applications in the emerging field of spintronics. More specifically magnetic vortices have been widely studied due to the quasi-particle/topological nature and are described as having two degrees of freedom, polarity and chirality. While there has been several studies exploring the fascinating behavior of vortices under perturbations using electrical measurements, scanning probe microscopy, and synchrotron based x-ray techniques, transmission electron microscopy provides unparalleled high resolution magnetic and structural information. This allows for a detailed analysis on how the local structure of different materials affects the translation motion of a vortex core under perturbation. Here, we present a direct imaging study of magnetically soft and hard mesoscopic discs of Permalloy and Cobalt under external field perturbations from equilibrium through annihilation and nucleation. The high resolution magnetic imaging of sub 6nm in Lorentz mode affords detail below critical domain wall features of less than 20nm where the soliton-regime breaks down into transverse Bloch walls far from equilibrium. By holding the ferromagnetic system in an external field we can capture the magnetic configuration far from equilibrium states near annihilation and during the nucleation process. Integrating these experiment with micromagnetic simulations we will describe how differently magnetic vortices can behave under perturbations, which is important when attempting to use them in applications such as logic, memories, and antennas.
Work supported by the DOE-BES-MSE,under Contract number DE-AC02-98CH10886 .
Wednesday, July 31, 2013
Congratulations to Joseph Garlow
I want to congratulate my former undergraduate mentee Joseph Garlow who completed his baccalaureate degree in Bio-engineering and is starting his graduate studies in the dept. of Material Science at SBU. He is now formally a PhD student member of our Electron Microscopy and Nanostructure Group, dept. CMPMS @BNL.
During his time under my mentorship Mr. Garlow focused on the growth and characterization of graphene using physcial vapor deposition (PVD) from a solid carbon source. He became well versed in ultra high vacuum technology, electron beam evaporation, scanning electron microscopy, and raman spectroscopy among other things. We are currently working on packaging up this work for peer-reviewed journal publications.
Welcome to the group and I wish you well in your scientific endeavors.
During his time under my mentorship Mr. Garlow focused on the growth and characterization of graphene using physcial vapor deposition (PVD) from a solid carbon source. He became well versed in ultra high vacuum technology, electron beam evaporation, scanning electron microscopy, and raman spectroscopy among other things. We are currently working on packaging up this work for peer-reviewed journal publications.
Welcome to the group and I wish you well in your scientific endeavors.
An SEM micrograph of PVD graphene grown on epitaxially grown Ni film (scale bar 5 um).
Wednesday, March 20, 2013
Invited Talk: Fundamental Magnetic Interactions in Patterned Nanostructures: Simulation, Fabrication and High-Resolution Microscopy
Thank you to the organizers of the 2013 MXLS Workshop "New Opportunities for Magnetic Dynamics and Materials at NSLS-II and MAX-IV” for the invited talk.
Fundamental Magnetic Interactions in Patterned Nanostructures: Simulation, Fabrication and High-Resolution Microscopy
Fundamental Magnetic Interactions in Patterned Nanostructures: Simulation, Fabrication and High-Resolution Microscopy
Through the use of complimentary
multi-technique experimental approaches, investigations of fundamental magnetic interactions, such as
magnetostatic, direct exchange, and indirect exchange, in nanomagnetic
structures perturbed by static and high frequency excitation, are presented.
Suggestions of using
dipolar coupled single domain patterned nanomagnets for applications such as
logic, has demonstrated the potential for low-power room temperature operation.
The fundamental evolution of reaching desired states can be described as an
energy minimization process, where elements exhibit preferential magnetization axes due to engineered shape anisotropies, and local energy minima are reached
utilizing external stimuli and strong magnetostatic interactions. Magnetic
Force Microscopy (MFM) was implemented in conjunction with NIST’s micromagnetic
framework OOMMF, in order to detail the energies associated with different
local ground states of coupled nanomangets. The kink energy and magnetic
frustrations in ferromagnetic and anti-ferromagnetic ordered elements in
various directional applied fields will also be discussed.
Dipolar interactions produce
long range force fields but stronger yet are the quantum mechanical short range
exchange interactions of neighboring spins. The competing energies of exchange
interactions in domain walls and magnetic flux due to surface
charges at boundaries can lead to interesting topological charges in room
temperature nanomagnetic systems. In a properly engineered nanodisk, magnetic
vortices appear, with two degrees of freedom (chirality and polarity), four
degenerate states, and exhibit radial symmetry at equilibrium. Utilizing
ferromagnetic resonance, transmission electron microscopy, and x-ray
transmission microscopy, details of competing direct exchange, demagnetization,
indirect exchange energies in magnetic vortex systems are investigated through
the observation of core deformation in static fields. The use of high frequency
field excitations applied in-situ in TEM to dual vortex core indirect exchange
coupled nanodisk heterostructues and the frequency response probed through the time
averaged orbital amplitude are also presented.
Sunday, February 24, 2013
APS March Meeting 2013 Talk
I will be presenting our XTM and TEM microscopy work on interlayer exchange couple magnetic vortices under an applied field.
Abstract:
The figure above shows the domain wall phase diagram measured via Lorentz TEM under quasi-static applied fields.
We report on the magnetic evolution of magnetic vortices in nanoscale and multilayer disk structures. The tri-layer structure consists of Co and Permalloy (Py) layers, coupled across a thin (1nm) Cu spacer that provides strong coupling between the Co and Py layers. Element-resolved full-field XMCD microscopy is combined with ultra-high resolution Lorentz transmission electron microscopy, permitting measurement of both layer-resolved domain patterns and the vortex structure averaged across the tri-layer. We examine the evolution of the vortex structure while the nanostructure is cycled through the M-H hysteresis loop. In particular we will discuss the effects of strong interlayer exchanged coupling on a dual vortex core system, including analysis of the layer-resolved coercivity, and the evolution, deformation, annihilation, and nucleation of the vortices.
Thursday, January 10, 2013
Introduction to Electron Microscopy
To the class,
It was a pleasure being your instructor. I hope you enjoyed the course and wish you well in your future. I am aware that I may not been able to answer all your questions. Please feel free to ask questions in the comment section below. It may be a similar question(s) that a classmate has and so could be informative to others in this format. All the best.
Tuesday, October 9, 2012
Girl Scout Troops@BNL
Update 2012-10-18: You can now read the official BNL press release:
http://www.bnl.gov/newsroom/news.php?a=23393
It was great to see all of you and your interest in science. I enjoyed contributing to the lesson. Here is possibly the smallest Girl Scout logo every made :) The total width of the logo is ~7.5 micrometers. That's the same size of a red blood cell!! The thickness of the logo was only ~30 nanometers. Click here to download the logo in other colors. Good luck with your future science interactions and feel free to ask questions by clicking on comments below.
http://www.bnl.gov/newsroom/news.php?a=23393
It was great to see all of you and your interest in science. I enjoyed contributing to the lesson. Here is possibly the smallest Girl Scout logo every made :) The total width of the logo is ~7.5 micrometers. That's the same size of a red blood cell!! The thickness of the logo was only ~30 nanometers. Click here to download the logo in other colors. Good luck with your future science interactions and feel free to ask questions by clicking on comments below.
--Javier
The image to the left is of the Girl Scouts logo captured using Atomic Force Microscopy. The troop had a hands on nano lesson explaining the fundamentals of Scanning Probe Microscopy before they saw the equipment in action at the CFN. The logo was fabricated using a top-down electron beam lithography process. The raised areas are 30nm of Cobalt on top of Silicon.
Wednesday, April 4, 2012
NSF Review Panelist
Wednesday, January 4, 2012
APS March Meeting 2012 Talk
I will be presenting our work entitled:
High Frequency Excitation of Nanometer-Scale, Strongly Coupled FM / NM / FM Disks
Abstract:
There is great interest in the manipulation of magnetic domains in nanostructures from both a fundamental and applications perspective. In particular, the use of resonant frequency excitations permits a power reduction of the driving forces necessary to induce detectable motion in magnetic vortex structures. Here we present an experimental and numerical study of patterned tri-layered disk stacks which are composed of 25nm Permalloy | 1nm Copper | 15nm Permalloy, excited at resonance, ranging from 250-500nm in radii. In-situ Lorentz microscopy was used to acquire time averaged real space images of the vortices' gyrotropic motion and micromagnetic simulations were implemented to further understand the coupled dynamics between the ferromagnetic layers across the thin non-magnetic spacer layer. We discuss the effects of interlayer coupling on the vortex trajectories and resonant frequencies for the individual ferromagnetic layers.
High Frequency Excitation of Nanometer-Scale, Strongly Coupled FM / NM / FM Disks
Abstract:
There is great interest in the manipulation of magnetic domains in nanostructures from both a fundamental and applications perspective. In particular, the use of resonant frequency excitations permits a power reduction of the driving forces necessary to induce detectable motion in magnetic vortex structures. Here we present an experimental and numerical study of patterned tri-layered disk stacks which are composed of 25nm Permalloy | 1nm Copper | 15nm Permalloy, excited at resonance, ranging from 250-500nm in radii. In-situ Lorentz microscopy was used to acquire time averaged real space images of the vortices' gyrotropic motion and micromagnetic simulations were implemented to further understand the coupled dynamics between the ferromagnetic layers across the thin non-magnetic spacer layer. We discuss the effects of interlayer coupling on the vortex trajectories and resonant frequencies for the individual ferromagnetic layers.
The figure above shows the gyrotropic motion of a vortex core under a high frequency applied magnetic field.
Tuesday, July 19, 2011
Javier F. Pulecio receives USF's Outstanding Dissertation Award
The Outstanding Thesis/Dissertation (OTD) Awards are intended to recognize those USF graduates who have demonstrated exceptional performance during their graduate careers at USF... links below
http://www.grad.usf.edu/outstanding-thesis.asp
http://www.eng.usf.edu/about/news/07-18-11%20Outstanding%20Dissertation%20Award.pdf
http://www.grad.usf.edu/outstanding-thesis.asp
http://www.eng.usf.edu/about/news/07-18-11%20Outstanding%20Dissertation%20Award.pdf
Tuesday, April 5, 2011
Intel Judge at the NYSSEF
It was very inspiring to see young men and women undertake and present their research at such a high level during the Intel sponsored New York State Science and Engineering Fair. It was a pleasure serving and I look forward to doing it again in the near future.
Sunday, January 2, 2011
Physics Research Associate - Brookhaven National Labs
I am excited to announce my next professional endeavor at BNL in Dr. Yimei Zhu's Nanostructure and Electron Microscopy group in the department of Condensed Matter Physics and Materials Science. I look forward to making contributions to the group's research and furthering our expertise in magnetism and electron microscopy.
Thursday, December 30, 2010
Thanks to Dr Bhanja and USF
I wanted to thank Dr Sanjukta Bhanja and all my colleagues at USF for the wonderful opportunity and experiences I had in the Nano Computing Research Group. I know the work we started there will continue to grow beyond our initial efforts and look forward to seeing the groups success in the near future.
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