`
`
`
`DAVID P. ARNOLD
`
`213 Larsen Hall, University of Florida
`PO Box 116200, Gainesville, FL 32611-6200
`352-392-4931 darnold@ufl.edu
`http://www.img.ufl.edu/darnold
`
`EDUCATION
`Ph.D.
`Electrical and Computer Engineering
`M.S.
`Electrical and Computer Engineering
`B.S.
` Electrical Engineering
`
`B.S.
` Computer Engineering
`
`
`Georgia Institute of Technology
`University of Florida
`University of Florida
`University of Florida
`
`
`
`Dec. 2004
`Dec. 2001
`May 1999
`May 1999
`
`ACADEMIC APPOINTMENTS
`George Kirkland Engineering Leadership Professor, Dept. Electrical and Computer
`
`Eng., University of Florida
`3/2010–12/2020
`Affiliate Professor, Dept. Materials Science and Eng., University of Florida
`8/2014–8/2016
`Professor, Dept. Electrical and Computer Eng., University of Florida
`10/2011–11/2011
`Visiting Scientist, FRIAS/IMTEK, University of Freiburg, Germany
`9/2011–10/2011
`Visiting Professor, G2ELab/INPG/Institut Néel, Grenoble, France
`Associate Professor (tenure), Dept. Electrical and Computer Eng., University of Florida 8/2010–8/2014
`6/2005–8/2010
`Assistant Professor, Dept. Electrical and Computer Eng., University of Florida
`Postdoctoral Fellow, School of Electrical and Comp. Eng., Georgia Tech
`1/2005–6/2005
`
`8/2016-present
`
`LEADERSHIP
`UF Site Director and University/Industry Partnerships Director, NSF Engineering
`
`Research Center for the Internet of Things for Precision Agriculture (IoT4Ag),
`
`University of Florida
`Associate Chair for Research, Dept. of Electrical and Computer Engineering
`Deputy Director, NSF I/UCRC on Multi-functional Integrated System Technology
`
`(MIST Center), University of Florida
`Inaugural Director, Interdisciplinary Microsystems Group (IMG), University of Florida 4/2016-4/2019
`Interim Director, Nanoscience Institute for Medical and Engineering Technology
`1/2012–6/2013
`
`(NIMET), University of Florida
`
`
`8/2019-present
`8/2014-3/2021
`
`9/2020-present
`
`RESEARCH INTERESTS
`Micro/nanostructured magnetic materials
`Magnetic microsystems and electromechanical transducers
`Biomedical applications of magnetic systems
`Compact (<100 W) power/energy systems (wireless power, energy harvesting, interface circuits)
`
`HONORS & AWARDS
`AIP Advances in Magnetism Award (Best Paper) Finalist (2019)
`UF ECE Excellence Award for Teaching (2019)
`Best Poster, 2018 Fall MIST Center Meeting (2018)
`Anderson Scholar Faculty Honoree (2018, 2019)
`Best Demo, 2018 Spring MIST Center Meeting (2018)
`Best Poster, 2017 Fall MIST Center Meeting (2017)
`Best Demo, 2017 Fall MIST Center Meeting (2017)
`
`Last Updated: 6/14/21
`
`1 of 37
`
`Momentum Dynamics Corporation
`Exhibit 1004
`Page 001
`
`
`
`DAVID P. ARNOLD
`
`UF Term Professorship (2017-2020)
`Best Application Paper, 2017 MARSS Conference (2017)
`UF ECE Excellence Award for Service (2017)
`George Kirkland Engineering Leadership Professorship (2016-present)
`Best Paper, SPIE ‘Smart Biomedical and Physiological Sensor Technology XIII’ Conference (2016)
`UF Research Foundation Professorship (2016-2019)
`Best Poster, Frontiers in Biomagnetic Particles Conf. (2015)
`UF Technology Innovator (2013, 2014, 2015, 2016)
`UF Engineering Doctoral Dissertation Advisor/Mentoring Award (2013)
`UF Engineering Pramod P. Khargonekar Junior Faculty Award for Excellence (2011)
`DARPA Young Faculty Award (2009)
`Presidential Early Career Award for Scientists and Engineers (PECASE) - DoD (2008)
`UF Dean’s Honor Roll of Teaching (2007)
`Southeastern Center for Electrical Engineering Education (SCEEE) Young Investigator Grant (2007)
`UF ECE Teacher of the Year, Runner-Up (2005-06)
`Georgia Tech Presidential Fellowship (2002-04)
`National Science Foundation Graduate Research Fellowship (2000-03)
`Trainer of the Year, Honorable Mention, MiRC Cleanroom, Georgia Tech (2003)
`Best Paper, AIAA Aerodynamic Measurement Technical Committee (2002)
`Tau Beta Pi Fellowship (1999-2000)
`UF ECE "Electric E" Award (1999)
`
`TEACHING HISTORY
`
`
`
`
`
`Title
`Course
`Term
`EEL 3008 Physics of EE
`Spr 2021
`EGN 6933 Eng. Faculty Development
`Spr 2021
`Fall 2020 EEL 3008 Physics of EE
`Spr 2020
`EGN 6933 Eng. Faculty Development
`Spr 2020
`EEL 4412 Appl. Magn. & Magn. Mtls.
`Spr 2020
`EEL 5417 Appl. Magn. & Magn. Mtls.
`Fall 2019 EEL 3008 Physics of EE
`Fall 2018 EEL 3008 Physics of EE
`Spr 2018
`EGN 6933 Eng. Faculty Development
`Spr 2018
`EEE 6465 Design MEMS Transducers
`Fall 2017 EEL 3008 Physics of EE
`Fall 2017 EEL 4412 Appl. Magn. & Magn. Mtls.
`Fall 2017 EEL 5417 Appl. Magn. & Magn. Mtls.
`Spr 2017
`EEL 3008 Physics of EE
`Spr 2017
`EMA6936 Eng. Faculty Development
`Fall 2016 EEL 3008 Physics of EE
`Spr 2016
`EEE 6465 Design MEMS Transducers
`Fall 2015 EEL 5225 Prin. MEMS Transducers
`Spr 2015
`EEL 4930 Appl. Magn. & Magn. Mtls.
`Spr 2015
`EEL 5934 Appl. Magn. & Magn. Mtls.
`Fall 2014 EEL 3111 Circuits 1
`Fall 2013 EEL 5225 Prin. MEMS Transducers
`
`Last Updated: 6/14/21
`
`2 of 37
`
`Instructor
`Instructor
`Overall†
`Evaluation*
`Instr. Dept. Coll. Instr. Dept. Coll.
`4.82
`4.36
`4.25
`--
`--
`--
`4.82
`4.78
`4.25
`--
`--
`--
`4.69
`4.30
`4.25
`--
`--
`--
`4.73
`4.54
`4.26
`--
`--
`--
`4.71
`4.34
`4.26
`--
`--
`--
`4.88
`4.53
`4.26
`--
`--
`--
`4.63
`4.32
`4.19
`--
`--
`--
`4.80
`4.38
`4.27
`4.82
`4.35
`4.22
`4.80
`4.54
`4.51
`4.88
`4.58
`4.50
`4.94
`4.56
`4.51
`5.00
`4.54
`4.50
`4.57
`4.25
`4.17
`4.62
`4.21
`4.11
`4.93
`4.25
`4.17
`5.00
`4.21
`4.11
`4.81
`4.39
`4.41
`4.75
`4.34
`4.40
`4.50
`4.30
`4.21
`4.55
`4.26
`4.16
`4.69
`4.40
`4.45
`4.69
`4.39
`4.43
`4.42
`4.30
`4.20
`4.46
`4.28
`4.15
`4.73
`4.45
`4.45
`4.71
`4.46
`4.45
`4.75
`4.30
`4.20
`4.75
`4.29
`4.16
`4.44
`4.30
`4.17
`4.33
`4.30
`4.14
`4.93
`4.30
`4.17
`5.00
`4.30
`4.14
`4.46
`4.20
`4.16
`4.65
`4.17
`4.13
`4.78
`4.29
`4.18
`5.00
`4.27
`4.17
`
`Momentum Dynamics Corporation
`Exhibit 1004
`Page 002
`
`
`
`DAVID P. ARNOLD
`
`EEL 5934 Appl. Magn. & Magn. Mtls.
`Spr 2013
`4.15
`4.30
`4.29
`4.15
`4.27
`4.24
`EEL 5934 Appl. Magn. & Magn. Mtls.
`Spr 2011
`4.11
`4.19
`4.85
`4.10
`4.18
`4.77
`EEE 6465 Design MEMS Transducers
`Spr 2011
`4.11
`4.19
`4.86
`4.10
`4.18
`4.80
`Fall 2010 EEL 5225 Prin. MEMS Transducers
`4.39
`4.41
`4.29
`4.34
`4.40
`4.33
`Spr 2010
`EEE 6465 Design MEMS Transducers
`4.41
`4.50
`4.44
`4.36
`4.47
`4.55
`Fall 2009 EEL 3211 Basic Electr. Energy Eng.
`4.10
`4.14
`4.67
`4.06
`4.09
`4.48
`Spr 2009
`EEL 5934 Appl. Magn. & Magn. Mtls.
`4.40
`4.56
`4.69
`4.36
`4.50
`4.50
`Fall 2008 EEE 4331 Microelectronic Fab. Tech.
`4.11
`4.19
`4.67
`4.07
`4.13
`4.60
`Fall 2008 EEE 5405 Microelectronic Fab. Tech.
`4.40
`4.45
`4.40
`4.33
`4.38
`4.37
`Spr 2008
`EEE 6465 Design MEMS Transducers
`4.43
`4.60
`4.78
`4.35
`4.48
`4.57
`Fall 2007 EEL 4331 Microelectronic Fab. Tech.
`4.22
`4.07
`4.82
`4.17
`4.02
`4.74
`Fall 2007 EEE 5405 Microelectronic Fab. Tech.
`4.38
`4.37
`5.00
`4.32
`4.31
`4.93
`Spr 2007
`EEE 6465 Design MEMS Transducers
`4.42
`4.39
`4.79
`4.37
`4.37
`4.82
`Fall 2006 EEL 5225 Prin. MEMS Transducers
`4.35
`4.19
`4.00
`4.29
`4.18
`4.07
`Spr 2006
`EEL 4331 Solid-State Technology
`4.04
`4.18
`4.75
`4.00
`4.12
`4.57
`Spr 2006
`EEL 5934 Microelectronic Fab. Tech.
`4.29
`4.36
`5.00
`4.25
`4.30
`4.85
`Fall 2005 EEL 5225 Prin. MEMS Transducers
`4.26
`4.28
`4.71
`4.22
`4.26
`4.62
`AVERAGES
`4.26
`4.32
`4.69
`4.25
`4.32
`4.65
`Numerical evaluations based on 5.0 scale. Semesterly undergraduate or graduate department (Dept.)
`and college (Coll.) averages are shown for comparison. *Average of N specific questions relating to
`the instructor (N=9 for 2005–2018; N=6 for 2019–present). †Overall evaluation based on a single
`question (this question eliminated in 2019).
`
`SPONSORED RESEARCH HISTORY
`Summary:
`49 distinct projects from 20 different sponsors
`$46M in total funding ($7M as PI), $10M my portion
`$409k/year average research expenditures (FY2018-20)
`
`
`
`Title
`NSF Engineering Research Center for the Internet
`of Things for Precision Agriculture (IoT4Ag)
`Magnetic Nanoparticles and Symbiosis
`
`Phase II IUCRC University of Florida: Center for
`Multi-functional Integrated System Technology
`(MIST)
`Planning Grant: Engineering Research Center for
`Ubiquitous Wireless Power for a Healthy World
`(POWERHEALTH)
`Development of Wirelessly Rechargeable Battery
`Technology
`Collaborative: Single-Input Control of Large
`Microrobot Swarms using Serial Addressing for
`Microassembly and Biomedical Applications
`Electromagnetic and Magnetic Penetration for
`High-Resolution Image Reconstruction
`Rapid, Portable Detection of Coliforms and E.
`coli. in Drinking Water
`
`Role
`CoPI
`
`CoPI
`
`CoPI
`
`Sponsor
`NSF
`
`Dates
`9/1/20-8/31/25
`
`Moore
`Foundation
`NSF
`
`9/1/20-8/30/23
`
`4/1/20-3/31/25
`
`CoPI
`
`NSF
`
`9/1/19-8/31/20
`
`PI
`
`PI
`
`UF
`
`7/9/18-12/31/19
`
`NSF
`
`6/1/17-5/30/21
`
`CoPI
`
`DARPA 12/6/17-5/30/20
`
`PI
`
`Innovative
`Space
`
`8/15/17-7/14/18
`
`Amount*
`$31,014,717
`(7%)
`$549,426
`(17%)
`$750,000
`(50%)
`
`$100,000
`(0%)
`
`$24,850
`(100%)
`$295,191
`(100%)
`
`$1,070,000
`(14%)
`$49,759
`(85%)
`
`Last Updated: 6/14/21
`
`3 of 37
`
`Momentum Dynamics Corporation
`Exhibit 1004
`Page 003
`
`
`
`DAVID P. ARNOLD
`
`SNM: Large-area Manufacturing of Integrated
`Devices with Nanocomposite Magnetic Cores
`Magnetic Thick Films for Integrated Microwave
`Devices
`Miniaturization of Resonant Wireless Power
`Transfer System Components
`Chip-Scale MEMS Receivers for Low-Power
`Wireless Charging
`Electrodynamic Wireless Power Transmission
`Prototype
`Zero-Power Magnetic Field Sensors Using
`Magnetoelectric Nanowires
`Levitated Microfactories for High-speed Adaptive
`Microassembly
`Biological and Fluidic Measurements using
`Magnetic Microdiscs
`Modeling of the Magnetic Particle Imaging Signal
`Due to Magnetic Nanoparticles
`Directed Nanoparticle Assembly by
`Electrophoretic Deposition
`High-Performance CoPt Micromagnets
`
`Development of Integrated Magnetic Sensors:
`Phase 2
`EAGER: Processes for Manufacturing High-
`Performance Magnetic Materials in Electronic
`Systems
`I/UCRC Phase I: Multi-functional Integrated
`System Technology (MIST)
`Development of Nanocomposite Micro-Inductor
`Prototypes
`Distributed Wireless Power Transmission to
`Compact Electronic Devices
`Magnetic Collection of Joint-Level Osteoarthritis
`Biomarkers
`Development of Integrated Magnetic Sensors
`
`Planning Grant: I/UCRC for Multi-functional
`Integrated System Technology
`Collaborative Research: Tailoring Energy Flow in
`Magnetic Oscillator Arrays
`Magnetic Nanoparticle/Biomarker Harvesting
`Technologies for the Early Diagnosis and
`Treatment of Osteoarthritis
`Magnetic Characterization of Leadframe
`Materials
`Interdisciplinary Research Group on Magnetic
`
`Tech.
`(DHA)
`NSF
`
`CoPI
`
`7/1/17-6/30/22
`
`PI
`
`DARPA
`
`2/1/17-1/31/22
`
`CoPI
`
`CoPI
`
`PI
`
`CoPI
`
`PI
`
`PI
`
`MIST
`Center
`MIST
`Center
`UF
`
`MIST
`Center
`SRI
`(DARPA)
`UF
`
`1/1/17-12/31/17
`
`1/1/17-6/30/18
`
`6/15/16-6/30/18
`
`1/1/16-12/31/19
`
`6/15/15-5/31/17
`
`6/1/15-8/31/16
`
`CoI
`
`NIH
`
`3/1/15-1/31/18
`
`PI
`
`PI
`
`PI
`
`PI
`
`MIST
`Center
`MIST
`Center
`Allegro
`Microsyst.
`NSF
`
`1/1/15-12/31/15
`
`1/1/15-12/31/15
`
`10/1/14-6/30/15
`
`9/1/14-4/30/16
`
`CoPI
`
`PI
`
`PI
`
`Invest.
`
`PI
`
`CoPI
`
`PI
`
`NSF
`
`UF
`
`9/1/14-8/31/20
`
`
`7/11/14-12/31/15
`
`GTS
`(US Army)
`NIH
`
`Allegro
`Microsyst.
`NSF
`
`12/1/13-12/31/15
`
`9/16/13-8/31/15
`
`9/1/13-5/31/14
`
`7/1/13-6/30/15
`
`NSF
`
`6/1/13-12/31/16
`
`CoPI
`
`UF
`
`5/1/13-4/30/15
`
`PI
`
`CoPI
`
`Allegro
`Microsyst.
`UF
`
`3/15/13-5/15/13
`
`9/1/12-8/31/14
`
`$1,396,666
`(28%)
`$1,119,928
`(72%)
`$25,000
`(50%)
`$75,000
`(50%)
`$25,526
`(100%)
`$195,000
`(49%)
`$170,000
`(100%)
`$22,005
`(100%)
`$386,844
`(29%)
`$47,000
`(100%)
`$47,000
`(100%)
`$50,000
`(100%)
`$120,000
`(64%)
`
`$957,012
`(50%)
`$22,986
`(100%)
`$200,000
`(100%)
`$335,070
`(37%)
`$84,143
`(100%)
`$55,971
`(50%)
`$250,000
`(100%)
`$87,792
`(17%)
`
`$4,700
`(100%)
`$222,000
`
`Last Updated: 6/14/21
`
`4 of 37
`
`Momentum Dynamics Corporation
`Exhibit 1004
`Page 004
`
`
`
`DAVID P. ARNOLD
`
`PI
`
`DARPA 9/13/11-12/12/13
`
`CoPI
`
`PI
`
`PI
`
`PI
`
`PI
`
`PI
`
`Encell
`Technology
`UF
`
`7/15/11-11/14/11
`
`8/1/11-12/31/11
`
`ARO
`
`10/1/09-3/31/15
`
`DARPA 9/16/09-9/15/11
`
`Vertical
`Partners
`ARO
`
`9/1/09-1/31/10
`
`5/1/09-10/31/10
`
`CoPI
`
`AFOSR
`
`3/1/09-10/31/11
`
`PI
`
`PI
`
`PI
`
`Siemens-
`FHTCC
`
`12/1/08-3/9/10
`
`ARL
`
`7/1/08-8/27/12
`
`Siemens 1/1/08-12/31/08
`
`CoPI
`
`Boeing
`
`12/1/07-4/1/09
`
`PI
`
`SCEEE
`
`7/1/07-6/30/08
`
`PI
`
`CoPI
`
`CoPI
`
`
`NSF
`
`5/1/07-10/31/08
`
`NASA
`
`3/19/07-3/18/11
`
`NASA
`
`12/1/06-11/30/10
`
`Biomaterials
`Micromachining of Permanent Magnet Undulator
`Structures for Compact X-ray Sources
`High Energy Density 3-D Electrodes for Energy
`Storage Applications
`Faculty Enhancement Opportunity Fund
`
`Development of Fully-Integrated Micromagnetic
`Actuator Technologies (PECASE)
`Microelectromechanical Inductors for Switch-
`Mode Power Converters
`Alternative Energy Technologies
`
`Femtosecond Laser for 3D Micromachining
`(DURIP)
`Demonstration of a Wingless Electromagnetic Air
`Vehicle
`Magnetic Induction Power Generation for
`Wireless Sensor Systems Embedded in Gas
`Turbines
`Ultra-Miniature Power Management for
`Microsystem Platforms
`Vibrational Energy Scavenging Technology to
`Power Remote Wireless Sensors
`Progress in MEMS Sensor Technology toward
`Suitability for Aeroacoustic Phased Array
`Measurement Applications: Phase IV
`Optimization and Experimental Validation of an
`Electromagnetic Vibrational Energy Scavenger
`SGER: Microfabrication Approaches for
`Microscale Permanent Magnets
`Development of Advanced Zero-Net Mass-Flux
`Actuators for Active Flow Control Applications
`Shear-Stress Sensor Array Measurement
`Technology for the Support of Turbulence Model
`Development for Flow Separation
`Magnetic Self-Assembly of Small Parts
`
`PI
`
`PI
`Micromachined Thermoelectric Generators for
`
`Waste Heat Power Generation
`*Total award values and percentages attributed to D. P. Arnold are indicated
`
`NSF
`
`ARL
`
`5/1/06-4/30/10
`
`1/1/06-6/30/08
`
`PRIMARY STUDENT/POSTDOC SUPERVISION
`Role
`Student
`Research Topic
`
`Chair,
`20 Ph.D.
`Dissertation
`
`Sai Amirisetti*
`Connor Smith
`Yuzheng Wang
`
`Home
`Dept.
`CHE
`Magnetic nanocomposites
`Electro-infiltrated magnetic composites ECE
`Electroplated CoPt /FePt micromagnets ECE
`
`Last Updated: 6/14/21
`
`5 of 37
`
`(33%)
`$1,078,701
`(51%)
`$44,000
`(50%)
`$7,549
`(100%)
`$1,000,000
`(100%)
`$300,000
`(100%)
`$26,250
`(100%)
`$175,000
`(100%)
`$453,459
`(21%)
`$92,666
`(100%)
`
`$665,000
`(50%)
`$125,000
`(100%)
`$310,000
`(6%)
`
`$36,000
`(100%)
`$74,860
`(100%)
`$695,869
`(34%)
`$644,202
`(18%)
`
`$226,000
`(100%)
`$362,259
`(100%)
`
`Completion
`Date
`current
`current
`current
`
`Momentum Dynamics Corporation
`Exhibit 1004
`Page 005
`
`
`
`DAVID P. ARNOLD
`
`Magnetic microdisc pathogen detector ECE
`Keisha Castillo-Torres
`Dynamic characterization nanoparticles ECE
`Nicolas Garraud
`Magnetic patterning of magnetic films ECE
`Camilo Velez Cuervo
`Magnetic nanocomposite materials
`ECE
`Xiao Wen
`Magneto-mechanical lattices
`MAE
`Robin Carroll**
`Micromagnetic field mapping
`ECE
`William Patterson
`Electroplated CoPt micromagnets
`ECE
`Ololade Oniku
`Synthetic jet microactuators
`ECE
`Shashank Sawant
`Microfabricated plasma actuators
`ECE
`Justin Zito
`Energy harvesting interface circuits
`ECE
`Yuan Rao
`Microinductors, microtransformers
`ECE
`Christopher Meyer
`Electrodynamic transformers
`ECE
`Shuo Cheng
`Wireless shear-stress sensors
`ECE
`Jeremy Sells
`Permanent magnets for MEMS
`MSE
`Naigang Wang***
`Thermoelectric power generators
`ECE
`Israel Boniche
`Magnetic self assembly of small parts
`ECE
`Sheetal Shetye
`Model/design synthetic jet actuators
`ECE
`Janhavi Agashe
`Sivaraman Masilamani MEMS-based heat exchangers
`ECE
`
`MAE
`Magnetic microrobots
`BME
`Biomagnetic manipulation
`MSE
`Magnetoelectric devices
`Electrodynamic wireless power transfer ECE
`Wireless power receivers
`MAE
`Power management for WPT receivers ECE
`Screen-printed magnetic composites
`MSE
`Wireless power transfer
`ECE
`Magnetic imaging
`ECE
`Magnetic needles for particle capture
`ECE
`Electrodynamic ZNMF actuators
`MAE
`Thermoelectric power generators
`ECE
`Magnetic powders for MEMS
`ECE
`
`5/2020
`12/2018
`8/2017
`8/2017
`12/2016
`12/2015
`12/2015
`8/2015
`8/2013
`8/2013
`5/2012
`12/2011
`5/2011
`5/2010
`5/2010
`8/2009
`5/2009
`8/2008
`
`current
`current
`current
`5/2021
`5/2021
`5/2020
`5/2019
`5/2015
`12/2014
`5/2013
`5/2010
`12/2006
`12/2006
`
`Committees
`
`(17
`graduated)
`
`
`
`Chair,
`1 M.S.
`Thesis
`Committee
`Chair, 13
`Undergrad.
`Committees
`w/ Final
`Presentations
`
`(Supervised
`30+ other
`undergrad
`researchers)
`
`Nathaniel Ball‡
`Catalina Morrison‡
`Cazlin Rains#
`Joseph Samman‡
`Spencer Smith†
`Stasiu Chyszewski§†
`Jacob Ewing†
`Mihailo Zivkovic‡
`Evan Shorman‡
`Zachary Kaufman†
`Ilan Eskinazi†
`Christopher Meyer†
`Benjamin Bowers‡
`* Co-chair with Carlos Rinaldi, CHE
`** Co-chair with Mark Sheplak, MAE
`***Co-chair with David Norton, MSE
`# UF University Research Scholars Program
`§ UF Emerging Scholars Program
`‡ UF University Scholars Program
`† High/Highest Honors Thesis Chair
`
`Graduated Ph.D. Students
`Summary:
`17 PhD graduates (1.1/year)
`
`
`2 currently postdocs, 1 faculty, 1 government research lab, 13 industry
`4 women, 13 men
`3 Hispanic, 1 Black, 7 Asian (3 Indian, 4 Chinese), 6 White (non-Hispanic)
`3 first-generation college students
`
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`
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`17. Keisha Castillo-Torres, “Magnetic Isolation of Fecal Indicating Bacteria using Bio-Functionalized
`Magnetic Microdiscs for Water Quality Monitoring,” May 2020. (initial/current position: Postdoc,
`UF)
`16. Nicolas Garraud, “Characterization of the Rotational Dynamics of Magnetic Particles in
`Suspension,” Dec. 2018. (initial/current position: Postdoc, CEA, France)
`15. Camilo Velez, “Engineering Microscale Magnetic Devices for Next-Generation Microrobotics,”
`Aug. 2017. (initial position: Postdoc, Carnegie Mellon University; current position: Assistant
`Professor, University of California, Irvine)
`14. Xiao Wen, “Exploration Of Electro-Infiltrated Magnetic Nanocomposites,” Aug. 2017.
`(initial/current position: Engineer, Intel)
`13. Robin E. Carroll, “Microfabricated Magneto-Mechanical Oscillator Device for Tuning and
`Characterization of Bandgap Response Behaviors,” Dec. 2016. (initial/current position: Staff
`Scientist, Pall Aerospace)
`12. William C. Patterson, “Of Magnetic Imaging System Experiments and Micro Electro-Mechanical
`Systems (Of MISE and MEMS),” Dec. 2015. (initial position: Senior Engineer, Sandia National
`Lab; current position: VP Operations, IC2)
`11. Ololade D. Oniku, “Electroplated Thick-Film Cobalt Platinum Permanent Magnets,” Dec. 2015.
`(initial/current position: PTD Module and Device Engineer, Intel)
`10. Shashank Sawant, “Design, Fabrication, and Characterization of Micro-Electrodynamic-Zero-Net-
`Mass-Flux Actuators,” Aug. 2015 (initial position: Senior MEMS Validation Engineer, Invensense;
`current position: Test Engineer, Google)
`Justin C. Zito, “Investigation of Microscale Dielectric Barrier Discharge Plasma Devices,” Aug.
`2013 (initial/current position: Process Module Engineer, Intel)
`8. Yuan Rao, “Input-Powered Interface Circuits for Electrodynamic Vibrational Energy Harvesting
`Systems,” Aug. 2013. (initial/current position: Design Engineer, Texas Instruments)
`7. Christopher D. Meyer, “Micromachined Inductors and Transformers for Miniaturized Power
`Converters,” May 2012. (initial/current position: Research Engineer, U.S. Army Research
`Laboratory)
`Shuo Cheng, “Theory, Design and Application of Electrodynamic Transformers,” Dec. 2011.
`(initial/ position: Post-Doc, University of Florida; current position: Engineer, Johns Hopkins
`University Applied Physics Laboratory)
`Jeremy Sells, “Passive Wireless Wall Shear Stress Sensors,” May 2011. (initial/current position:
`Hardware Engineer, Hewlett Packard)
`4. Naigang Wang, “Fabrication and Integration of Permanent Magnet Materials into MEMS
`Transducers,” May 2010. (initial/current position: Research Scientist, IBM Watson Research
`Center)
`Israel Boniche, “Silicon-Micromachined Thermoelectric Generators for Power Generation from Hot
`Gas Streams,” May 2010. (initial/current position: Research Engineer, Intel)
`Sheetal B. Shetye, “Magnetic Self-Assembly of Small Parts,” Aug. 2009. (initial/current position:
`BAW Development Engineer, Qorvo)
`
`3.
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`2.
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`9.
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`5.
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`Page 007
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`DAVID P. ARNOLD
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`1.
`
`Janhavi S. Agashe, “Modeling, Design And Optimization of Electrodynamic Zero-Net Mass-Flux
`(ZNMF) Actuators,” May 2009. (initial position: Post-Doc, U. Colorado at Boulder, current
`position: Hardware Engineer, Tesla)
`Graduated M.S. Thesis Students
`1.
`Sivaraman Masilamani, “Design, Fabrication, and Characterization of a Micromachined Heat
`Exchanger Platform for Thermoelectric Power Generation,” Aug. 2008. (initial/current position:
`Analog Engineer, Intel)
`Current/Former Postdocs
`8. Leili Hayati, Ph.D. graduate of Northeastern University, supervised Mar. 2021 – present.
`7. Keisha Castillo-Torres, Ph.D. graduate of University of Florida, supervised May 2020 – present.
`6. Adrian A. Rendon-Hernandez, Ph.D. graduate of Université Grenoble Alpes (France), supervised
`Oct. 2019 – present.
`5. Md Abdul Halim Miah, Ph.D. graduate of Kwangwoon University (South Korea), supervised Mar.
`2019 – present.
`4. Bin Qi, Ph.D. graduate of Clemson University, supervised Aug. 2013 – Mar. 2014. (initial/current
`position: Sr. Engineer, MultiDimension Technology)
`3. Alexandra Garraud, Ph.D. graduate of University of Montpellier 2 (France), supervised June 2012 –
`Aug. 2015 (initial position: Research Assistant Professor, University of Florida, current position:
`Researcher, Enerbee, France).
`Shuo Cheng, Ph.D. graduate of University of Florida, supervised Jan. 2012 – Aug. 2012. (initial
`position: Post-Doc, Massachusetts Institute of Technology, current position: Engineer, Johns
`Hopkins University Applied Physics Laboratory)
`1. Vinod R. Challa, Ph.D. graduate of Stevens Institute of Technology, supervised Jan. 2011 - Dec
`2012. (initial position: Research Scientist, Oscillapower Inc.; current position: Sr. Function
`Development Engineer, Philips)
`
`2.
`
`PUBLICATIONS
`Summary:
`4 book chapters
`
`
`98 refereed journal publications
`
`
`117 refereed conference publications
`
`
`99 abstract/presentations at meetings (without proceedings)
`
`
`citations=4171, h-index=32, i10-index=90 (Google Scholar)
`
`Book Chapters
`4. D. Arnold, Z. Kaufman, and A. Garraud, “Magnetic Needle Development,” in Nanomagnetic
`Actuation in Biomedicine—Basic Principles and Applications, J. Dobson and C. Rinaldi, Eds. Boca
`Raton, Florida:CRC Press, 2018, pp. 93-122.
`S. Cheng, C. Cepnik, and D. P. Arnold, “Electrodynamic Vibrational Energy Harvesting,” in Micro
`Energy Harvesting, D. Briand, E. Yeatman, and S. Roundy, Eds. Weinheim, Germany:Wiley-VCH,
`2015, pp. 175-200.
`2. D. P. Arnold, M. Saumer, and Y.-K. Yoon, “Additive Processes for Metals,” in Handbook of MEMS
`Materials and Processes, R. Ghodssi and P. Lin, Eds. New York: Springer, 2011, pp. 137-191.
`
`3.
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`1. D. P. Arnold and M. G. Allen, “Fabrication of Microscale Rotating Magnetic Machines,” in Multi-
`Wafer Rotating MEMS Machines: Turbines, Generators, and Engines, J. H. Lang, Ed. New York:
`Springer, 2009, pp. 157-190.
`Refereed Journal Publications
`98. S. E. Smith, M. A. Halim, S. T. Chyczewski, A. A. Rendon-Hernandez, and D. P. Arnold, “A
`wirelessly rechargeable AA battery using electrodynamic wireless power transmission,” Energies,
`vol. 14, no. 9, 2368, 14 pages, Apr. 2021.
`97. O. L. Lanier, C. Velez, D. P. Arnold, and J. Dobson, “Model of magnetic particle capture under
`physiological flow rates for cytokine removal during cardiopulmonary bypass,” IEEE Trans.
`Biomed. Eng., vol. 68, no. 4, pp. 1198-1207, Apr. 2021.
`96. M. A. Halim, A. A. Rendon-Hernandez, S. E. Smith, J. M. Samman, N. Garraud, and D. P. Arnold
`“A chip-sized piezoelectric receiver for low-frequency, near-field wireless power transfer: design,
`modeling and experimental validation,” Smart Mat. Syst., vol. 30, no. 4, 045011, 11 pages, Mar.
`2021.
`95. M. A. Halim, A. A. Rendon-Hernandez, S. E. Smith, J. M. Samman, N. Garraud, and D. P. Arnold
`“Miniature electrodynamic wireless power transmission receiver using a micromachined silicon
`suspension,” J. Microelectromech. Syst., vol. 30, no. 1, pp. 144-155, Feb. 2021.
`94. R. Bowrothu, H. Kim, C. S. Smith, D. P. Arnold, and Y. K. Yoon, “35-GHz barium
`hexaferrite/PDMS composite-based millimeter-wave circulators for 5G applications,” IEEE Trans.
`Microw. Theory Techn., vol. 68, no. 12, pp. 5065-5071, Dec. 2020.
`93. C. S. Smith, K. Sondhi, S. C. Mills, J. S. Andrew, Z. H. Fan, T. Nishida, and D. P. Arnold, “Screen-
`printable and stretchable hard magnetic ink formulated from barium hexaferrite nanoparticles,” J.
`Mater. Chem. C, vol. 8, no. 35, pp. 12133-12139, Sept. 2020.
`92. M. J. Bauer, A. Thomas, B. Isenberg, J. Varela, A. Faria, D. P. Arnold, and J. S. Andrew, “Ultra-
`low-power current sensor utilizing magnetoelectric nanowires,” IEEE Sensors J., vol. 20, no. 10, pp.
`5139-5145, May 2020.
`91. Z. Zhao, N. Garraud, D. P. Arnold, and C. Rinaldi, “Effects of particle diameter and
`magnetocrystalline anisotropy on magnetic relaxation and magnetic particle imaging performance of
`spherical nanoparticles,” Phys. Med. Biol., vol. 65, no. 2, 025014, 16 pages, Jan. 2020.
`90. S. Mills, C. S. Smith, D. P. Arnold, and J. S. Andrew, “Electrophoretic deposition of iron-oxide
`nanoparticles to achieve thick nickel/iron-oxide magnetic nanocomposite films,” AIP Adv., vol. 10,
`no. 1, 015308, 5 pages, Jan. 2020.
`89. C. S. Smith, S. Savliwala, C. Rinaldi, and D. P. Arnold, “Electro-infiltrated nickel/iron-oxide and
`permalloy/iron-oxide nanocomposites for integrated power inductors,” J. Magn. Magn. Mat., vol.
`493, 165718, 8 pages, Jan. 2020.
`88. K. Castillo-Torres, E. S. McLamore, and D. P. Arnold, “A high-throughput microfluidic magnetic
`separation (μFMS) platform for water quality monitoring,” Micromachines, vol. 11, no. 16, 13
`pages, Jan. 2020.
`87. C. S. Smith, S. C. Mills, S. Savliwala, C. Rinaldi, J. Andrew, and D. P. Arnold, “Nanoscale
`structural evaluation of 0-3 magnetic nanocomposites fabricated by electro-infiltration,” AIP Adv.,
`vol. 9, no 12, 4 pages, Dec. 2019.
`86. Y. Wang, R. Bowrothu, Y.-K. Yoon, and D. P. Arnold, “Patterning of thick electroplated CoPt
`magnets using SU-8 micromoulds,” Micro Nano Lett., vol. 14, no. 14, pp. 1393-1396, Dec. 2019.
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`85. C. Velez, S. Hwangbo, S. Chyczewski, J. Ewing, R. Bowrothu, C. Smith, Y.-K. Yoon, and D. P.
`Arnold, “Investigation of ferromagnetic resonance shift in screen-printed barium ferrite/samarium
`cobalt composites,” IEEE Trans. Microw. Theory Techn., vol. 67, no. 8, pp. 3230-3236, Aug. 2019.
`84. K. Castillo-Torres, D. P. Arnold, and E. S. McLamore, “Rapid isolation of Escherichia coli from
`water samples using magnetic microdiscs,” Sensors & Actuators B: Chemical, vol. 291, pp. 58-66,
`July 2019.
`83. K. Sondhi, N. Garraud, D. J. Alabi, D. P. Arnold, A. Garraud, S. Avuthu, Z. H. Fan, T. Nishida,
`“Flexible screen-printed coils for wireless power transfer using low-frequency magnetic fields,” J.
`Micromech. Microeng., vol. 29, no. 8, 084006, 10 pages, June 2019.
`82. A. P. Taylor, C. V. Cuervo, D. P. Arnold, and L. F. Velásquez–García, “Fully 3D-printed,
`monolithic mini magnetic actuators for low-cost, compact systems,” J. Microelectromech. Syst., vol.
`28, no. 3, pp. 481-493, June 2019
`81. Y. Wang, J. Ewing, and D. P. Arnold, “Ultra-thick electroplated CoPt magnets for MEMS” J.
`Microelectromech. Syst., vol. 28, no. 2, pp. 311-320, Apr. 2019.
`80. S. Chyczewski, S. Hwangbo, Y.-K. Yoon, and D. P. Arnold, “Experimental demonstration of multi-
`watt wireless power transmission to ferrite core receivers at 6.78 MHz,” Wireless Power Transfer,
`vol. 6, no. 1, Mar. 2019.
`79. N. Garraud, A. Garraud, D. Munzer, M. Althar, and D. P. Arnold, “Modeling and experimental
`analysis of rotating magnet receivers for electrodynamic wireless power transmission,” J. Phys. D:
`Appl. Phys., vol. 52, no. 18, 185501, 12 pages, Feb. 2019.
`78. M. J. Bauer, X. Wen, P. Tiwari, D. P. Arnold, and J. S. Andrew, “Magnetic field sensors using
`arrays of electrospun magnetoelectric Janus nanowires,” Microsyst. & Nanoeng., vol. 4, 37, 12
`pages, Dec. 2018.
`77. H. C. Burch, A. Garraud, M. F. Mitchell, R. C. Moore, and D. P. Arnold, “Experimental generation
`of ELF radio signals using a rotating magnet,” IEEE Trans. Antennas Propag., vol. 6, no. 11, pp.
`6265-6272, Nov. 2018.
`76. G. Petrov, J. Davis, W. Schumaker, M. Vargas, V. Chvykov, B. Hou, A. Maksimchuk, V.
`Yanovsky, A. G. R. Thomas, K. Krushelnick, A. Garraud, D. P. Arnold, B. A. Peterson, and M. G.
`Allen, “Development of mini-undulators for a table-top free-electron laser,” Laser and Particle
`Beams, vol. 36, no. 3, pp.396-404, Sept. 2018.
`75. J. Ewing, Y. Wang, D. P. Arnold, “High-current-density electrodeposition using pulsed and constant
`currents to produce thick CoPt magnetic films on silicon substrates,” AIP Adv., vol. 8, no. 5,
`056711, 5 pages, May 2018.
`74. S. G. Sawant, B. George, L. S. Ukeiley, and D. P. Arnold, “Microfabricated electrodynamic
`synthetic jet actuators,” J. Microelectromech. Syst., vol. 27, no. 1, Feb. 2018.
`73. N. Garraud, R. Dhavalikar, M. Unni, S. Savliwala, C. Rinaldi, and D. P. Arnold, “Benchtop
`magnetic particle
`relaxometer
`for detection, characterization and analysis of magnetic
`nanoparticles,” Phys. Med. Biol., vol. 63, no. 17, 175016, 13 pages, Sept. 2017.
`72. C. Velez, R. E. Carroll, and D. P. Arnold, “Direct measurement and microscale mapping of
`nanoNewton to milliNewton magnetic forces,” AIP Adv., vol. 7, no.5, 056809, 6 pages, May 2017.
`71. N. Garraud, R. Dhavalikar, L. Maldonado-Camargo, D. P. Arnold, and C. Rinaldi, “Design and
`validation of magnetic particle spectrometer for characterization of magnetic nanoparticle relaxation
`dynamics,” AIP Adv., vol. 7, no. 5, 056730, 6 pages, May 2017.
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`70. X. Wen and D. P. Arnold, “Exchange-coupled hard magnetic Fe-Co/CoPt nanocomposite films
`fabricated by electro-infiltration,” AIP Adv., vol. 7, no. 5, 056225, 4 pages, May 2017.
`69. B. Qi, J. S. Andrew, and D. P. Arnold, “Calcium-assisted reduction of cobalt ferrite nanoparticles
`for nanostructured iron cobalt with enhanced magnetic performance,” J. Nanopart. Res., vol. 19, no.
`3, 89, 8 pages, Mar. 2017.
`68. M. Unni, A. Uhl, S. Savliwala, B. Savitzky, R. Dhavalikar, N. Garraud, D. P. Arnold, L. Kourkoutis,
`J. S. Andrew, and C. Rinaldi, “Thermal decomposition synthesis of iron oxide nanoparticles with
`diminished magnetic dead layer by controlled addition of oxygen,” ACS Nano, vol. 11, no. 2, pp.
`2284-2303, Feb. 2017.
`67. Z. Zhao, I. Torres-Diaz, C. Velez, D. P. Arnold, and C. Rinaldi, “Brownian dynamics simulations of
`magnetic nanoparticles captured in strong magnetic field gradients,” J. Phys. Chem. C, vol. 121, no.
`1, pp. 801-810, Dec. 2016.
`66. O. D. Oniku, B. Qi, and D. P. Arnold, “Electroplated thick-film cobalt platinum permanent
`magnets,” J. Magn. Magn. Mat., vol. 416, pp. 417-428, Oct. 2016.
`65. E. G. Yarmola, Y. Shah, D. P. Arnold, J. Dobson, and K. D. Allen, “Magnetic capture of a
`molecular biomarker from synovial fluid in a rat model of knee osteoarthritis,” Annals Biomed.
`Eng., vol. 44, no. 4, pp. 1159-1169, Apr. 2016.
`64. X. Wen, S. J. Kelly, J. S. Andrew, and D. P. Arnold, “Nickel-zinc ferrite/permalloy
`(Ni0.5Zn0.5Fe2O4/Ni-Fe) soft magnetic nanocomposites fabricated by electro-infiltration,” AIP Adv.,
`vol. 6, 056111, 6 pages, Feb. 2016.
`63. S. J. Kelly, X. Wen, D. P. Arnold, and J. S. Andrew, “Electrophoretic deposition of nickel zinc
`ferrite nanoparticles into microstructured patterns,” AIP Adv., vol. 6, 056105, 8 pages, Feb. 2016.
`62. A. Garraud, C. Velez, Y. Shah, N. Garraud, B. Kozissnik, E. G. Yarmola, K. D. Allen, J. Dobson,
`and D. P. Arnold, “Investigation of the capture of magnetic particles from high-viscosity fluids
`using permanent magnets,” IEEE Trans. Biomed. Eng., vol. 63, no. 2, pp. 372-378, Feb. 2016.
`61. C. Velez, I. Torres-Díaz, L. Maldonado-Camargo, C. Rinaldi, and D. P. Arnold, “Magnetic
`assembly and cros