Publications

As an engineering laboratory, we see our main mission as turning the most exciting science discoveries, particularly in our “bread and butter” fields of electromagnetics, quantum physics and nanomagnetics, into practical applications with revolutionary impacts on society. Through our decades-long experience, we realize that the only way to be successful in fulfilling this ambitious mission is to establish lasting, mutually beneficial, cross-disciplinary collaborations with our colleagues in fields of arts and sciences, healthcare and medicine, and others.  

Accordion Group

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  • PATENTS (41 US Patent granted)

    Granted Patents:

    1. Khizroev, T. Stewart, A. Nagesetti, “3D Navigation of nanoparticles via induction of metastable diamagnetic response,” US Patent 11,110,052, issued on September 7, 2021
    2. Khizroev, R. Guduru, “Rechargeable battery device,” US Patent 10,840,829, issued on November 17, 2020
    3. Khizroev, R. Guduru, D. McDaniel, “Rapid and wireless screening and health monitoring of materials and structures,” US Patent 10,557,763, issued on February 11, 2020
    4. Khizroev, R. Guduru, “Nanoparticle based computing architecture,” US Patent 10,381,466, issued August 13, 2019
    5. Khizroev, T. Stewart, and A. Nagesetti, “3D navigation of nanoparticles via induction of metastable diamagnetic response,” US Patent 10,300,011, issued May 28, 2019
    6. Khizroev, R. Guduru, and D. McDaniel, “Rapid and wireless screening and health monitoring of materials and structures,” US Patent 10,234,347, issued March 19, 2019
    7. Khizroev and R. Guduru, “Instantly rechargeable battery device,” US Patent 10,008,962, issued July 26, 2018
    8. Khizroev, R. Guduru, P. Liang, M. Nair, C. Runowicz, “On-demand drug release using magnetoelectric nanoparticles,” US Patent 9,895,549, issued February 20, 2018
    9. Khizroev, R. Guduru, P. Liang, “On-demand drug release using magnetoelectric nanoparticles,” US patent application 20160030724, kind code A1, Appl. No.: 14/703521, filed, February 4, 2016, US Patent 9,724,503, issued August 8, 2017
    10. Khizroev and M. Nair, “Method for non-invasive brain stimulation,” US Patent application 15/015,760, filed February 14, 2016, US Patent 9,669,232, issued June 6, 2017
    11. Khizroev and M. Nair, “Wireless brain stimulation,” US Patent application 13/900,305, filed 05/22/2013; US Patent 9,272,158, issued March 1, 2016
    12. Khizroev, R. Ikkawi, N. Amos, R. Chomko, A. Balandin, “Near-field optical recording system having negative index of refraction structure,” US Patent 8,345,518, issued Jan 1, 2013; filed July 17, 2009, with the University of California
    13. Amos, S. Khizroev, R. Ikkawi, R. Haddon, R. Fernandez, “Probes for enhanced magnetic force microscopy resolution,” US Patent 8,214,918, issued July 3, 2012; UC Case No 2008-492-1, filed Jan 23, 2008, filed Nov 20, 2009, USPTO application number 12623329, issued July 3, 2012, with the University of California
    14. Khizroev, “Three-dimensional magnetic memory and/or recording device,” US patent 7,969,775, issued June 28, 2011; patent application 12/726,070; 11/197,377, filed Aug 4, 2005, with provisional patent, 60/598,645, filed Aug 4, 2003, with FIU
    15. Khizroev, “Three-dimensional magnetic memory and/or recording device,” US patent 7,706,179, issued April 27, 2010; patent application 20060028766, filed February 9, 2006; 11/197,377, filed Aug 4, 2005, with provisional patent, 60/598,645, filed Aug 4, 2003, with FIU
    16. Crue, E. B. Svedberg, R. E. Rottmayer, D. Litvinov, and S. Khizroev, “Low moment – high moment write pole with non-magnetic layer for establishing a magnetic discontinuity between layers of the write pole,” US patent application 20040066574, April 8, 2004, with Seagate, S/N 7,038, 882, issued to Seagate Technology, May 2, 2006
    17. Litvinov, R. W. Gustafson, and S. Khizroev, “Magnetic recording system which eliminates skew angle effect,” US patent, 60/221,494, filed Jul 26, 2001, with Seagate, S/N 6,987,637, issued to Seagate Technology on Jan 17, 2006
    18. Khizroev, N. Amin, B. Crue, R. Rottmayer, D. Litvinov, “Perpendicular recording head with trackwidth defined by plating thickness,” US patent, 60/161,690, filed Oct 24, 2000, S/N 6,898,053, issued to Seagate Technology on May 24, 2005
    19. Litvinov, N. Shukla, E. B. Svedberg, S. Khizroev, D. K. Weller, “Selective annealing of magnetic recording films,” US patent, 60/334,240, filed Nov 27, 2002, S/N 6,884,328, issued to Seagate Technology on April 26, 2005
    20. Khizroev, D. Litvinov, B. W. Crue, “Perpendicular magnetic recording head,” US patent, filed on Oct 24 2004, S/N 6,876,518, issued to Seagate Technology April 5 2005
    21. Litvinov, and S. Khizroev, “Magnetic recording head including background magnetic field generator,” International and US patents, 60/154,880, filed Sept 19, 2000, S/N 6,876,519, issued to Seagate Technology on April 5 2005
    22. Khizroev, J. A. Bain, M. H. Kryder, D. Litvinov, “Longitudinal magnetic recording heads with variable-length gaps,” International and US patents, 60/157,883, filed Oct 4, 2000, S/N 6,865,057, issued to Seagate Technology on Mar 8 2005
    23. Litvinov, and S. Khizroev, “Perpendicular magnetic recording apparatus for improved playback resolution having flux generating elements proximate the read element,” US patent, 60/306,802, filed Dec 17, 2001, with Seagate, S/N 6,888,700, issued to Seagate on May 3, 2005
    24. Khizroev, E. C. Johns, D. Litvinov, “Gapless longitudinal magnetic recording head with flux cavity,” US patent, 60/174,524 filed on Jan. 5, 2000, 60/175,793 filed Jan 5, 2001, S/N 6,865,056, issued to Seagate Technology on Mar 8 2005
    25. M. Shukh, S. Khizroev, D. Litvinov, E. W. Singleton, “Perpendicular recording medium with antiferromagnetic exchange coupling in soft magnetic underlayers,” US patent, 60/227,943, filed Aug 24, 2001, S/N 6,818,330, issued to Seagate Technology on Nov 16 2004
    26. Litvinov, and S. Khizroev, “Perpendicular recording head with longitudinal magnetic field generator to facilitate magnetic switching,” US patent, 60/175,266, filed Jan 10, 2001, S/N 6,816,339, issued to Seagate Technology on Nov 9, 2004
    27. Litvinov, and S. Khizroev, “Multilayer perpendicular magnetic recording media with exchange decoupled spacer layers,” US patent, 60/192,050, filed Mar 23, 2001, S/N 6,630,255, issued to Seagate Technology on Oct 7 2003
    28. Litvinov, W. Crue, S. Khizroev, “Perpendicular recording head with return poles which reduce flux antenna effect,” US patent, 60/192,053, filed Mar 23, 2001, S/N 6,798,615, issued to Seagate Technology on Sep 28 2004
    29. Khizroev, M. H. Kryder, D. Litvinov, “Perpendicular recording head including concave tip,” US patent, 60/154,973, filed Sept 19, 2000, S/N 6,771,462, issued to Seagate Technology on Aug 3, 2004
    30. Khizroev, R. W. Gustafson, D. Litvinov, N. Shukla, “A perpendicular magnetic recording head with a magnetic shield to reduce side reading,” US patent, 60/257,125, filed Dec 20, 2001, S/N 6,738,233, issued to Seagate Technology on May 18 2004
    31. Litvinov, B. Crue, S. Khizroev, “Composite write pole for a magnetic recording head,” US patent, 60/276,154, filed Nov 29, 2001, S/N 6,721,131, issued to Seagate Technology on Apr 12 2004
    32. Crue, T. M. Crawford, S. Khizroev, D. Litvinov, “Perpendicular magnetic recording head having a flux focusing main pole,” US patent, 60/189,359, filed Mar 15, 2001, S/N 6,693,768, issued to Seagate Technology, Feb 17, 2004
    33. Khizroev, and D. Litvinov, “Perpendicular magnetic recording head with means for suppressing noise from soft magnetic underlayer of recording media,” US patent, 60/175,265, 60/175,271, 60/180,293, 60/189,365, 60/191,974, 60/191,775, filed Jan 10, 2001, S/N 6,667,848, issued to Seagate Technology on Dec 23 2003
    34. Litvinov, R. W. Gustafson, K. J. Howard, S. Khizroev, “Perpendicular magnetic recording media with laminated soft magnetic underlayer,” 60/180,415, filed Feb 2, 2001, S/N 6,660,357, issued to Seagate Technology on Dec 9 2003
    35. Litvinov, K. J. Howard, S. Khizroev, “Multilayer magnetic recording media with columnar microstructure for improved exchange decoupling,” US patent, 60/235,943, filed Sep 27, 2001, S/N 6,656,613, issued to Seagate Technology on Dec 2 2003
    36. Litvinov, and S. Khizroev, “Magnetic recording media including magnetically soft composite layer and method of making same,” US patent, 60/175,858, filed Jan 12, 2001, S/N 6,645,647, issued to Seagate Technology Nov 11, 2003
    37. Khizroev, W. Crue, D. Litvinov, “Perpendicular magnetic recording head with write pole which reduces flux antenna effect,” US patent, 60/175,320, filed Jan 10, 2001, S/N 6,646,827, issued to Seagate Technology on Nov 11, 2003
    38. Litvinov , S. Khizroev, “Perpendicular recording head defining the trackwidth by material deposition thickness,” US patent, 60/167,936 (60,167,952), field Nov 29, 2000, S/N 6,560,069, issued to Seagate Technology on May 6, 2003
    39. Litvinov, S. Khizroev, M. H. Kryder, “Perpendicular magnetic recording media with reduced-noise soft magnetic underlayer,” US patent, 60/168,147, filed Nov 28, 2000, S/N 6,531,202, issued to Seagate Technology on Mar 11, 2003
    40. Khizroev, B. W. Crue, D. Litvinov, “Method for forming a perpendicular recording read/write head,” US patent, 60/174,519, filed Sep 21, 2000, S/N 6,513,228, issued to Seagate Technology on Feb 4, 2003
    41. C. Arnett, D.C. Cheng, S. Khizroev, D. A. Thompson, “Track width control of readback elements via ion implantation in a bonding region of tip portion to selectively deactivate magnetic sensitivity thereof’s,” US patent, S/N 6,483,672, filed 1999, issued to IBM Almaden Research Center on November 19th, 2002

     

    Pending Patents:

    1. Khizroev and Y. Yesha, “Miniaturized Custom-built Quantum AI Nanomagnetic Chips for Operating Small- and Medium-Size Language Models,” patent disclosure filed at the University of Miami, September 4, 2024
    2. Khizroev and P. Ganzer, Wireless targeted neuromodulation using ring-shaped injectrodes for generation of localized and direction-specific electric fields via inducing electromotive force in the low-resistance ring by application of alternating current magnetic fields, July 28, 2024, UMIP-696, provisional patent filed October 8, 2024
    3. Khizroev, “Room-temperature Nanomagnetic Quantum 1- and 2-Qubit Gates,” patent disclosure filed at the University of Miami, June 15, 2024
    4. Khizroev, E. Zhang, M. Shotbolt, P. Liang, “Magnetically-strained ferroelectric nanoparticles and methods of making and use thereof,” U.S. Patent Application No. 63/554243, filed February 16, 2024.
    5. Khizroev, et al., “Nanodevices for rapid screening and signature identification of viruses, bacteria, cancer cells, and other biomolecular structures,” filed 8/10/2015
    6. Khizroev, et al., “High-specificity chemotherapy using field-controlled nano-electroporation by magnetoelectric nanoparticles,” US Patent filed 5/17/2013
    7. Khizroev, “Magneto-electric nanoparticles for selective non-invasive brain stimulation”, 2013
    8. Khizroev, “High-selective treatment of cancer via magneto-electric nanoparticles”, 2013
    9. Khizroev, “Field-controlled drug delivery deep in the brain on demand”, 2013
    10. Khizroev, N. Amos, “Universal Logic Gates for Highly-scalable 3-D Magnetic Computing,” invention disclosure filed May 19, 2010
    11. Khizroev, E. Levister, Jr., “Focused high-field MRI for screening and diagnostics purposes in office environment. Example: Prostate Cancer,” UC Case No. 2010-681-1, filed May 19, 2010
    12. Khizroev, N. Amos, R. Ikkawi, R. Haddon, “Plug-in multilevel three-dimensional magnetic recording drive,” UC Case Nos 2008-425-2 and 2009-265-1, filed October 2008, two provisional patent applications, 61/082,091 (filed 18 July 2008) and 61/115,434 (filed 17 November 2008), a U.S. patent application 12/506,042, also filed as an International patent application (PCT/US2009/004181)  titled “Three-dimensional magnetic recording” on July 20, 2009
    13. Haddon, M. E. Itkis, P. Ramesh, E. Bekyarova, S. Khizroev, J. Hong, “Chemical modulation of electronic and magnetic properties of graphene,” Serial No.: 994678, PCT/US2009/045735, Nov 24, 2010, patent application 20110068290, March 24, 2011
    14. Ikkawi, S. Khizroev, N. Amos, “Nanolasers for ultra-high density multilevel heat-assisted magnetic recording,” UC Case No. 2008-498-1, filed Feb 1, 2008. Provisional patent filed in February, 2008.
    15. Khizroev, N. Amos, R. Ikkawi, “Integrated “Information Storage with Logic” hard drive,” UC Case No 2008-271-1, filed Dec 3, 2007
    16. Krichevsky, S. Khizroev,  A. Lavrenov, I. Dumer, “Magnetic recording medium with a separate mapping/metadata/servo underlayer,” UC Case No. 2008-271-1, filed Oct 2, 2007, provisional patent application 61/057699,  PCT/US09/45740, filed Nov 29, 2010, “Magnetic Recording Medium,” US patent application 20110075288, Kind code Al, March 31, 2011
    17. Khizroev, E. Stefanescu, R. Chomko, R. Haddon, “Carbon nanotube based patterned magnetic media,” UC Case No. 2008-138-1, filed Aug 23, 2007
    18. Khizroev, R. Ikkawi, N. Amos, R. Chomko, “Protein-based recording system for areal densities above 1 terabit/in2,” UC Case No. 2007-781-1, filed June 12, 2007
    19. Litvinov, R. W. Gustafson, and S. Khizroev, “Read element for magnetic storage media having magnetic coupling between itself and its shields,” US patent, 60/208,252, filed May 23, 2001, with Seagate
    20. Litvinov, W. Crue, M.-L. Wu, S. Khizroev, “Magnetic recording heads including boron nitride insulating material,” US patent, 60/191,525, filed Mar 23, 2001, with Seagate
    21. Batra, S. Khizroev, D. Litvinov, “Longitudinal recording head with reduced side fringing,” US patent, 60/180,295, filed Feb 5, 2001, with Seagate
    22. Crue, E. C. Johns, S. Khizroev, D. Litvinov, U. Tran, “Write pole for a magnetic recording head having layered low magnetic moment and high magnetic moment material,” US patent, 60/180,292, filed Feb 2, 2001, with Seagate
    23. Khizroev, and D. Litvinov, “Perpendicular magnetic recording system including recording media with a soft magnetic underlayer having a saturation moment higher than the moment of the recording head,” US patent, 60/175,863, filed Jan 12, 2001, with Seagate
    24. Ikeda, S. Khizroev, K. Rubin, D. A. Thompson, “Write head with modified field gradient and increased current margin for perpendicular magnetic recording,” US patent, filed 1999, with IBM.
    25. Khizroev, D. A. Thompson, “Vortex domain configuration in microscopical cylinders made of magnetically soft materials,” US patent, filed 1999, with IBM

     

  • PEER-REVIEWED PAPERS

    1. Bryant, E. Stimphil, V. Andre, M. Shotbolt, E. Zhang, V. Estrella, K. Husain, J. Weygand, D. Marchion, A. S. Lopez, D. Abrahams, S. Chen, M. Abdel-Mottaleb, S. Conlan, I. Oraiqat, V. Khatri, J. A. Guevara, S. Pilon-Thomas, G. Redler, K. Latifi, N. Raghunand, K. Yamoah, S. Hoffe, J. Cosstello, J. M. Frakes, P. Liang, , R. A. Gatenby, M. Mokenge, and S. Khizroev “ Magnetoelectric nanotherapy achieves complete tumor ablation and prolonged survival in pancreatic cancer murine models,” Advanced Science, e17228, doi.org/10.1002/advs.202517228 (2025).
    2. Shotbolt, J. Bryant, P. Liang, and S. Khizroev, “Mechanism and applications of magnetoelectric nanoparticles in cancer therapy,”  Nanomedicine, 1–13,  doi.org/10.1080/17435889.2025.2545746 (2025).
    3. Shotbolt, J. Bryant, P. Liang, and S. Khizroev, “Physics of selective targeting of cancer cells by magnetoelectric nanoparticles; exploring the role of conductivity and capacitance in tumor-specific attraction,” Advanced Theory and Simulations, doi.org/10.1002/adts.202500739 (2025).
    4. Tian, V. Andre, M. Shotbolt, S. Chen, E. Zhang, E. Zhu, B. Nandakumar, P. Liang, P. Ganzer, and S. Khizroev, “Ultra-high-efficacy wireless neuromodulation using a conductive ring interface,” IEEE Transactions of Neural Systems and Rehabilitation Engineering, under the 2nd revision review step, 2025
    5. Shotbolt, E. Zhang, V. Andre, E. Zhu, I. Duran, J. Bryant, W. El-Rifai, P. Liang, S. Khizroev, “Catalytic Degradation of Organic Dyes Indicates Electroporation Efficiency of Magnetoelectric Nanoparticles,” Journal of Electronic Materials, doi.org/10.1007/s11664-025-11843-5 (2025).
    6. Andre, M. Abdel-Mottaleb, S. Chen, M. Shotbolt, Z. Ramezani, E. Zhang, P. Liang, J. Bryant, P. Liang, R. Chomko, S. Khizroev, “Foundational Insights For Theranostic Applications of MagnetoElectric NanoParticles,” Nanoscale Horizons, 10(4), 699-718 (2025). DOI: 10.1039/d4nh00560k
    7. Zhang, M. Shotbolt, C-Y. Chang, A. Scott-Van Deusen, S. Chen, P. Liang, S. Khizroev, “Wireless non-invasive control of action potentials with magnetoelectric nanoparticles,” Brain Stimulation, 17 (5), 1005-1017 (2024), DOI: 10.1016/j.brs.2024.08.008
    8. Ramezani and S. Khizroev, “Equivalent circuit model of multiferroic and magnetoelectric composite nanoparticles,” Journal of Electronic Materials 53, 6124-6139 (2024)
    9. Ramezani, V. Andre, and S. Khizroev, “Modeling the effect of magnetoelectric nanoparticles on neuronal electrical activity: an analog circuit approach,” AIP Biointerphases 19, 031001 (2024).
    10. Chen, E. Zhang, B. Navarrete, Y. Yildrim, M. Abdel-Mottaleb, M. Alberteris Campos, I. T. Smith, P. Liang, S. Khizroev, “Magnetic Properties of Magnetoelectric Nanoparticles with Varying Core-Shell Ratios and Their Effects on In Vitro Neuron Stimulation,” IEEE Trans Magnetics, 59(11), 1-4 (2023).
    11. T. Smith, E. Zhang, P. Liang, Y. Yildirim, B. Yildirim, M. Abdel-Mottaleb, P. Liang, S. Khizroev, “Medical applications of magnetoelectric nanoparticles,” WIREs Nanomedicine and Nanobiotechnology, e1849 (2023).
    12. Zhang, P. Liang, Y. Yildirim, S. Chen, M. Abdel-Mottaleb, M. Shotbolt, J. Tian, Z. Ramezani, V. Andre, S. Khizroev, “Ab initio considerations in the design of wireless neural recording systems using magnetoelectric nanoparticles,” IEEE Transactions on Magnetics, 59 (10): 5000205:1-5 (2023) DOI:0.1109/TMAG.2023.3300791.
    13. Zhang, M. Abdel-Mottaleb, P. Liang, B. Navarrete, Y. Akin Yildirim, M. Alberteris Campos, I. T. Smith, P. Wang, B. Yildirim, L. Yang, S. Chen, I. Smith, G. Lur, B. T. Nguyen, X. Jin, B. Noga, P. Ganzer, S. Khizroev, “Magnetic-field-synchronized wireless modulation of neural activity by magnetoelectric nanoparticles,” Brain Stimulation 15 (6): 1451-1462 (2022).
    14. Pardo, S. Khizroev, “Where do we stand now regarding treatment of psychiatric and neurodegenerative disorders? Considerations in using magnetoelectric nanoparticles as innovative approach,” WIREs Nanomedicine and Nanobiotechnology 14 (3): e1781 (2022).
    15. Guduru, P. Liang, A. Hadjikhani, P. Wang, V. Musaramthota, A. Franco Hernandez, B. Arkook, J. Hong, S. Khizroev, “Magnetically controlled crystallographic properties of graphite sheets with self-assembled periodic arrays of magnetoelectric nanoparticles,” Appl. Surf. Science 573: 151455 (2021).
    16. Nguyen, J. Gao, P. Wang, A. Nagesetti, P. Andrews, S. Masood, Z. Vriesman, P. Liang, S. Khizroev, X. Jin, “In vivo wireless brain stimulation via non-invasive and targeted delivery of magnetoelectric nanoparticles,” Neurotherapeutics 18 (3): 2091-2106 (2021); doi: 10.1007/s13311-021-01071-0.
    17. Pardo, E. Roberts, K. Pimentel, Y. Yildirim, B. Navarrete, P. Wang, E. Zhang, P. Liang, S. Khizroev, “Size-dependent intranasal administration of magnetoelectric nanoparticles for targeted brain localization,” Nanomedicine: NBM 32: 102337 (2021).
    18. Hong, X. Li, N. Xu, H. Chen, S. Cabrini, S. Khizroev, J. Bokor, L. You, “A dual magnetic tunnel junction-based neuromorphic device,” Advanced Intelligent Systems: 2000143 (2020).
    19. Wang, E. Zhang, D. Toledo, I.T. Smith, B. Navarrete, N. Furman, A.F. Hernandez, M. Telusma, D. McDaniel, P. Liang, and S. Khizroev, “Colossal magnetoelectric effect in coreshell magnetoelectric nanoparticles,” Nano Letters 20 (8): 5765-5772 (2020).
    20. Wang, D. Toledo, E. Zhang, M. Telusma, D. McDaniel, P. Liang, S. Khizroev, “Scanning probe microcopy study of cobalt ferrite-barrium titanate coreshell magnetoelectric nanoparticles,” JMMM 516: 167329 (2020).
    21. Toledo, B. Navarrete, M. Stone, K. Luongo, P. Wang, P. Liang, and S. Khizroev, “A theoretical study of switching energy efficiency in sub-10-nm spintronic devices,” J. Magnetism and Magnetic Materials 494: 165776 (2020).
    22. Khizroev and P. Liang, “Engineering future medicines with magnetoelectric nanoparticles: wirelessly controlled, targeted therapies,” IEEE Nanotechnology Magazine 14 (1): 23-29 (2020).
    23. Navarrete, M. Stone, K. Luongo, D. Toledo, A. Hadjikhani, P. Wang, J. Hong, P. Liang, J. Bokor, S. Khizroev, “Nanomagnetic particle-based information processing,” IEEE Transactions on Nanotechnology (IEEE T-Nano) 18: 983-988 (2019), DOI: 10.1109/TNANO.2019.2939009.
    24. Hong, X. Li, O. Lee, W. Tian, S. Khizroev, J. Bokor, L. You, “Demonstration of spin transfer torque (STT) magnetic recording,” Applied Physics Letters 114: 243101 (2019).
    25. Hong, Q. Luo, S. Jung, S. Je, Y. Kim, M. Im, C. Hwang, S. Khizroev, S . Chung, L. You, “Shape transformation and self-alignment of Fe based nanoparticles,” Nanoscale Advances 1(7): 2523-2528 (2019), DOI: 10.1039/C9NA00146H.
    26. Khizroev, “Technobiology’s Wireless Messenger: The Nanoparticle,” Cold Spring Harbor Perspectives in Medicine 9, a034207, 1-15 (2019); doi: 10.1101/cshperspect.a034207.
    27. Hong, M. Stone, B. Navarrete, K. Luongo, J. Bokor, S. Khizroev, “Multilevel three-dimensional spin computer,” Applied Physics Letters 112, 112402-4 (2018).
    28. Guduru, P. Liang, M. Yousef, J. Horstmyer, and S. Khizroev, “Electric field mapping of the brain with magnetoelectric nanoparticles,” Bioelectronic Medicine 4 (10): s42234-018-0012-9 (2018).
    29. Stewart, A. Nagesetti, R. Guduru, E. Stimphil, A. Hadjikhani, L. Salgueiro, P. Liang, J. Horstmyer, A. Schally, and S. Khizroev, “Magnetoelectric nanoparticles to deliver and release anti-tumor peptide into glioblastoma cells across blood-brain barrier via external application of d.c. and a.c. magnetic fields,” Nanomedicine (London) 13 (4): 423-438 (2018); doi/org/10.2217/nnm-2017-0300.
    30. Hadjikhani, A. Rodzinski, P. Wang, A. Nagesetti, R. Guduru, P. Liang, C. Runowicz, S. Shahbazmohamadi, and S. Khizroev,”Biodistribution and clearance of magnetoelectric nanoparticles for nanomedical applications using energy dispersive spectroscopy,” Nanomedicine (London) 12 (15); 1801-1822 (2017); doi.org/10.2217/nnm-2017-0080.
    31. Nagesetti, A. Rodzinski, E. Stimphil, T. Stewart, C. Khanal, P. Wang, R. Guduru, P. Liang, I. Agoulnik, J. Horstmyer, and S. Khizroev, “Multiferroic coreshell magnetoelectric nanoparticles as NMR sensitive nanoprobes for cancer cell detection,” Scientific Reports 7, 1610 (2017).
    32. Stimphil, A. Nagasetti, R. Guduru, T. Stewart, A. Rodzinski, P. Liang, and S. Khizroev, “Physics considerations in targeted anticancer drug delivery by magnetoelectric nanoparticles,” Appl. Phys. Rev., 4 (2), 021101 (2017).
    33. Hong, A. Hadjikhani, M. Stone, F. Allen, V. Safonov, P. Liang, J. Bokor, and S. Khizroev, “The physics of spin-transfer torque switching in magnetic tunneling junctions in sub-10-nm size range,” IEEE Trans. Magn. 52 (7), 1400504 (2016).
    34. Rodzinski, R. Guduru, P. Liang, A. Hadjikhani, T. Stewart, E. Stimphil, C. Runowicz, R. Cote, N. Altman, R. Datar, and S. Khizroev, “Targeted and controlled anticancer drug delivery and release with magnetoelectric nanoparticles,” Scientific Reports 6, 20867 (2016); Cancer Research 76 (14 S), 2204 (2016).
    35. Guduru, P. Liang, J. Hong, A. Rodzinski, A. Hadjikhani, J. Horstmyer, E. Levister, and S. Khizroev, “Magnetoelectric “spin” on stimulating the brain,” Nanomedicine (London) 10 (13), 2051-2061 (2015).
    36. Hong, X. Li, N. Xu, H. Chen, S. Cabrini, S. Khizroev, J. Bokor, L. You, “A dual magnetic tunnel junction-based neuromorphic device,” Advanced Intelligent Systems: 2000143 (2020).
    37. Guduru and S. Khizroev, “Magnetic-field-controlled release of paclitaxel drug from functionalized magneto-electric nanoparticles,” Particle and Particle Systems Characterization 31 (5), 605-611 (2014).
    38. Cheng, S. Khizroev, P. Liang, “3-Terminal pMTJ reduces critical current and switching time,” JMMM 358, 5-10 (2014).
    39. Hong, E. Bekyarova, W. de Heer, R. Haddon, and S. Khizroev, “Chemically engineered graphene-based 2-D organic molecular magnet,” ACS Nano 7(11), Article ASAP 10011-10022 (2013).
    40. Guduru, P. Liang, C. Runowicz, M. Nair, V. Alturi, and S. Khizroev, “Magnetoelectric nanoparticles to enable field-controlled high-specificity drug delivery to eradicate ovarian cancer cells,” Scientific Reports 3, 2953 (2013).
    41. Zheng, L. Chang, I. Nekrashevich, P. Ruchoeft, S. Khizroev, and D. Litvinov, “Fabrication of dense non-circular nanomagnetic device arrays using self-limiting low-energy glow-discharge processing,” PL0S ONE 8(8), e73083 (2013).
    42. Lee, J. Hong, N. Amos, D. Litvinov, and S. Khizroev, “Electron-beam lithography to fabricate magnetic bit patterned media suitable for areal densities above 1 terabit/in2,” J. Nanoparticle Research 15, 1665-72 (2013).
    43. Nair, R. Guduru, P. Liang, J. Hong, V. Sagar, and S. Khizroev, “Externally-controlled on-demand release of anti-HIV drug AZTTP using magneto-electric nanoparticles as carriers,” Nature Communications 4, 1707 (2013).
    44. Hong, P. Liang, V. Safonov, and S. Khizroev, “Energy-efficient spin-transfer-torque based sub-10-nm magnetic tunneling junctions,”  J. Nanoparticle Research 15 (4), 1599 (2013).
    45. Stefanescu, J. Hong, R. Guduru, A. Lavrenov, D. Litvinov, and S. Khizroev, “Magneto-resistive nanojunctions fabricated via focused ion beam implantation,” J. Nanoparticle Research 15 (1), 1387-1390 (2013).
    46. Hong, E. Bekyarova, P. Liang, W. de Heer, R. Haddon, and S. Khizroev, “Room-temperature magnetic-order in functionalized graphene,” Scientific Reports 2, 624 (2012).
    47. Yue, R. Guduru, J. Hong, P. Liang, M. Nair, and S. Khizroev, “Magneto-electric nanoparticles for non-invasive brain stimulation,” PLoS ONE 7(9), e44040 (2012).
    48. V. Chang, A. Nasruallah, P. Ruchoeft, S. Khizroev, D. Litvinov, “Graded bit patterned magnetic array fabricated via angled low-energy H ion irradiation,” Nanotechnology 23 (27), 275705 (2012).
    49. Hong, E. Stefanescu, P. Liang, N. Joshi, S. Xu, and S. Khizroev, “Carbon nanotube based 3-D matrix for enabling three-dimensional nano-magneto-electronics,” PLoS ONE 7 (7), e40554, (2012).
    50. Amos, J. Butler, B. Lee, M. Scachar, B. Hu, Y. Tian, J. Hong, D. Garcia, R. Ikkawi, R. Haddon, D. Litvinov, and S. Khizroev, “Multilevel-3D bit patterned magnetic media with 8 signal levels per nanocolumn,” PLoS ONE 7 (7), e401234 (2012).
    51. Hong, S. Niyogi, E. Bekyarova, M. Itkis, P. Ramesh, R. C. Haddon, C. Berger, W. A. DeHeer, and S. Khizroev, “Effect of functionalization on the electrostatic charging, tunneling, and Raman spectroscopy of epitaxial graphene,” JVST BMicroelectronics and Nanometer Structures 30 (3), 1-5 (2012).
    52. Kaganovskiy, S. Khizroev, D. Litvinov, “Influence of low anisotropy inclusions on magnetization reversal in bit-patterned arrays”, J. Appl. Phys. 111, 033924  (2012).
    53. Chang, R. Veerdonk, S. Khizroev, D. Litvinov, “Scanning magnetoresistance microscopy analysis of bit patterned media playback,” IEEE Trans. Magn. 47 (10), 2548-2550 (2011).
    54. Amos, E. Stefanescu, J. Butler, B. Lee, Y. Tian, R. Ikkawi, R. Chomko, V. L. Safonov, R. Haddon, D. Litvinov, and S. Khizroev, “Three-dimensional non-volatile magnetic universal logic gates,” JNO 6 (2), 138-43 (2011).
    55. Sandip, E. Bekyarova, H. Jeongmin, S. Khizroev, C. Berger, W. De Heer, R. Haddon, “Covalent chemistry for graphene electronics,” J. Phys. Chem. Lett. 2 (19), 2487-98 (2011).
    56. Tian, L. Kaganovskiy, N. Amos, B. Hu, D. Litvinov, and S. Khizroev, “Effects of crystalline anisotropy on nanomagnetic computer logic channels,” JNO 6 (2), 87-94 (2011).
    57. Kaganovskiy, D. Litvinov, S. Khizroev, and S. Wilcox, “Investigation of the switching wave propagation in linear chains of magnetic elements,” J. Appl. Phys. 110, 043901 (2011).
    58. R. Morales, N. Amos, S. Khizroev, J.E.Garay, “Magneto-optical Faraday effect in nanocrystalline oxides,” J. Appl. Phys. 109 (9), 093110 (2011).
    59. Fernandez, D. Teweldebrham, C.Zhang, N.Amos, A. Balandin, and S. Khizroev, “A comparative analysis of Ag and Cu heat sink layers in L10-FePt films for the high-density heat-assisted magnetic recording,” J. Appl.Phys. 109, 07B763 (2011).
    60. Hong, E. Bekyarova, M. Itkis, P. Ramesh, N. Amos, D. Litvinov, C. Berger, W. A. De Heer, S. Khizroev, R. C. Haddon, , “Effect of nitrophenyl functionalization on the magnetic properties of epitaxial graphene,” SMALL 7 (9), 1175-80 (2011).
    61. Hudgins, S. Khizroev, “Considerations for the implementation of 2D protein memory,” J. Nanoscience and Nanotechnology 11 (3), 2520-3 (2011).
    62. Hu, N. Amos, Y. Tian, J. Butler, D. Litvinov, S. Khizroev, “Study of Co/Pd multilayers as a candidate material for next generation magnetic media,” J. Appl. Phys. 109 (3), 034314 (2011).
    63. Hijazi, E. B. Svedberg, T. Heinrich, S. Khizroev, “Comparative corrosion study of binary oxide and nitride overcoats using in-situ fluid-cell AFM,” Materials Characterization 62 (1), 76-80 (2011).
    64. Fernandez, N. Amos, C. Zhang, M. Hudgins, and S. Khizroev, “Microstructural enhancement of high coercivity L10 FePt films for next-generation magnetic recording media,” J. Nanoscience and Nanotechnology 11 (5), 3889-93 (2011).
    65. Hudgins, J. Butler, R. Fernandez, M. J. Ranaghan, R. Birge, R. Haddon, S. Khizroev, “Photo-response of electrostatically deposited bacteriorhodopsin monolayer films for protein-based disk recording beyond 10 terabit/in2,” JNO 5 (3), 287-9 (2010).
    66. Amos, R. Fernandez, R. Ikkawi, M. Shachar, J. Hong, B. Lee, D. Litvinov, and S. Khizroev, “Ultra-high coercivity magnetic force microscopy probes to analyze high-moment magnetic structures and devices,” IEEE Magnetics Letters 1, 6500104 (2010).
    67. Zhang, N. Amos, R. Fernandez, J. Hong, B. Hu, S. Khizroev, “Magnetic properties optimization for amorphous soft underlayers,” Journal of Nanoelectronics and Optoelectronics, 5 (1), 13-19 (2010).
    68. Gomez, R. Fernandez, N. Amos, S. Khizroev, C. Lopez, “A mathematical algorithm and custom nanoprobes to improve the resolution of magnetic force microscopy (MFM) images,” Journal of Nanoelectronics and Optoelectronics, 5 (1), 20-26 (2010).
    69. Smith, L. Chang, J. Rantschler, V. Kalatsky, P. Ruchoeft, S. Khizroev, D. Litvinov, “Size distribution and anisotropy effects on the switching field distribution of Co/Pd multilayered nanostructure arrays,” IEEE Trans. Magn. 45 (10), 3554-7 (2009).
    70. Amos, A. Lavrenov, R. Fernandez, R. Ikkawi, D. Litvinov, and S. Khizroev, “High-resolution and high-coercivity FePt L10 magnetic force microscopy nanoprobes to study next-generation magnetic recording media,” J. Appl. Phys. 105, 07D526 (2009).
    71. Krichevsky, A. Lavrenov, N. Amos, B. Hu, K. Taylor, and S. Khizroev, “The effect of ion implantation on magnetic properties of Co/Pd multilayer structures possessing perpendicular anisotropy,” J. Nanoelectronics and Optoelectronics 3 (3), 274-6 (2008).
    72. Amos, R. Ikkawi, R. Haddon, D. Litvinov, and S. Khizroev, “Controlling multi-domain states to enable sub-10-nm magnetic force microscopy,” Appl. Phys. Lett. 93, 203116 (2008); Editor’s choice for inclusion in the December 8, 2008 issue of Virtual Journal of Nanoscale Science and Technology.
    73. E., J. Rantschler, S. Khizroev, D. Litvinov, “Micromagnetic study of domain wall dynamics in bit-patterned nanodots,” J. Appl. Phys. 103, 113910 (2008).
    74. Stefanescu, N. Amos, R. Ikkawi, B. Lee, R. Chomko, D. Litvinov, S. Khizroev, “Perpendicular recording with reduced skew angle sensitivity,” J. Nanoelectronics and Optoelectronics 3 (4), 270-3 (2008).
    75. E, J. Rantschler, S. Khizroev, D. Litvinov, “Micromagnetics of signal propagation in magnetic cellular logic data channels,” J. Appl. Phys. 104, 054311 (2008).
    76. Litvinov, V. Parekh, C. E, D. Smith, J. Rantschler, P. Ruchhoeft, D. Weller, and S. Khizroev, “Nanoscale bit-patterned media for next-generation data storage systems,” J. Nanoelectronics and Optoelectronics 3 (2), 93-112 (2008).
    77. Gomez, D. Litvinov, and S. Khizroev, “A nanoscale nuclear magnetic resonance system for signature-based detection of biomolecules,” J. Nanoelectronics and Optoelectronics 3 (2), 123-32 (2008).
    78. Litvinov, V. Parekh, C. E, D. Smith, J. Rantschler, P. Ruchhoeft, D. Weller, and S. Khizroev, “Recording physics, design considerations, and fabrication of nanoscale bit-patterned media,” IEEE Trans. Nanotechnology 7 (4), 463-76 (2008).
    79. Khizroev, R. Ikkawi, N. Amos, R. Chomko, R. Haddon, D. Litvinov, “Protein-based memory,” Materials Research Society (MRS) Bulletin 33 (9), 864-71 (2008).
    80. Ikkawi, A. Krichevsky, A. Lavrenov, N. Amos, D. Litvinov, S. Khizroev, “Exploiting far- and near-field optics to develop energy efficient transducer for HAMR,” IEEE Trans. Magn. 44 (11), 3364-7 (2008).
    81. Gomez, D. Litvinov, S. Khizroev, “Minimum parameters required to enable low-field low-size nano nuclear magnetic resonance (NanoNMR),” IEEE Trans. Magn. 44 (11), 4464-7 (2008).
    82. E, J. Rantschler, S. Zhang, S. Khizroev, T. R. Lee, D. Litvinov, “Low-temperature vacuum annealing study of (Co/Pd)n magnetic multilayers,” J. Appl. Phys. 103, 07B510 (2008).
    83. Smith, V. Parekh, C. E, S. Zhang, W. Donner, T. R. Lee, S. Khizroev, D. Litvinov, “Magnetization reversal and magnetic anisotropy in patterned Co/Pd multilayer thin films,” J. Appl. Phys. 103, (2008).
    84. Hernandez, E. Stefanescu, S. Khizroev, N. Myung, “Electrodeposition of iron-palladium thin films,” Electrochimica Acta 53 (18), 5621-27 (2008).
    85. Ikkawi, A. Lavrenov, A. Krichevsky, D. Teweldebrhan, S. Ghosh, A. A. Balandin, D. Litvinov, and S. Khizroev, “Near-field optical transducer for heat-assisted magnetic recording for beyond 10-terabit/in2 densities, J. Nanoelectronics and Optoelectronics 3, 44-54 (2008).
    86. Amos, R. Fernandez, R. Ikkawi, B. Lee, A. Lavrenov, A. Krichevsky, D. Litvinov, S. Khizroev, “Magnetic force microscopy study of magnetic stripe domains in sputter deposited Permalloy thin films, “ J. Appl. Phys. 103 (7), 07E732 (2008).
    87. Amos, R. Ikkawi, A. Krichevsky, R. Fernandez, E. Stefanescu, I. Dumer, D. Litvinov, S. Khizroev, “Multilevel three-dimensional nanomagnetic recording,” J. Nanoelectronics and Optoelectronics 2, 257-68 (2007).
    88. Litvinov, Ch. E, V. Parekh, D. Smith, J. Rantschler, S. Zhang, W. Donner, T. R. Lee, P. Ruchhoeft, D. Weller, and S. Khizroev, “Design and fabrication of high anisotropy nanoscale bit-patterned magnetic recording medium for data storage applications, ECS Transactions 3 (25), 249-58 (2007).
    89. Ikkawi, N. Amos, A. Krichevsky, R. Chomko, D. Litvinov, S. Khizroev, “Nanolasers to enable data storage beyond 10 terabit/in2, “Appl. Phys. Lett. 91 (15), 3115-6 (2007); Editor's choice for the Virtual Journal of Nanoscale Science & Technology, October 19 (2007).
    90. S. Martirosyan, L. Chang, J. Rantschler, S. Khizroev, D. Luss, D. Litvinov, “Carbon combustion synthesis and magnetic properties of cobalt ferrite nanoparticles,” IEEE Trans. Magn. 43 (6), 3118-20 (2007).
    91. Parekh, D. Smith, Chunsheng E, J. Rantschler, S. Khizroev, D. Litvinov, “He+ ion irradiation study of continuous and patterned Co/Pd multilyaers,” J. Appl. Phys. 101, 083904 (2007).
    92. Gomez, D. Litvinov, and S. Khizroev, “A method to design high SNR nanoscale magnetic sensors using an array of tunneling magneto-resistive (TMR) devices,” Journal of Physics D: Applied Physics 40, 4396-404 (2007).
    93. Chunsheng E, J. Rantschler, S. Zhang, D. Smith, V. Parekh, Khizroev, D. Litvinov, “Integranular interactions of low temperature atmosphere annealed Co/Pd magnetic multilayers,” J. Appl. Phys. 101, 09D108 (2007).
    94. Renugopalakrishnan, S. Khizroev, H. Anand, L. Pingzuo, L. Lindvold, “Future memory storage technology: protein-based memory devices may facilitate surpassing Moore’s Law,” IEEE Trans. Magn. 43 (2), 773-5 (2007).
    95. Khizroev, Y. Hijazi, N. Amos, E. Felissaint, N. Joshi, R. Ikkawi, R. Chomko, and D. Litvinov, “Physics of Perpendicular Recording with a Patterned Soft Underlayer,” special information technologies issue, J. Nanoscience and Nanotechnology 7, 243-54 (2007).
    96. Amos, R. Ikkawi, A. Lavrenov, P. Gomez, R. Chomko, F. Candocia, D. Litvinov, S. Khizroev “Nanomagnetic probes to image patterned media for information densities above ten terabit-per-square-inch,” J. Nanoelectronics and Optoelectronics 2, 1-3 (2007).
    97. Smith, Chunsheng E., S. Khizroev, D. Litvinov, “The influence of bit patterned medium design and imperfections on magnetoresistive playback,” IEEE Trans. Magn. 42 (10), 2285-7 (2006).
    98. Hijazi, R. Ikkawi, N. Amos, A. Lavrenov, N. Joshi, D. Doria, R. Chomko, D. Litvinov, and S. Khizroev, “Patterned soft underlayers for perpendicular media,” IEEE Trans. Magn. 42 (10), 2375-7 (2006).
    99. Chunsheng E, D. Smith, E. Svedberg, Khizroev, D. Litvinov, “Combinatorial synthesis of Co/Pd magnetic multilayers,” J. Appl. Phys. 99, 113901 (2006).
    100. Khizroev, Y. Hijazi, N. Amos, D. Doria, A. Lavrenov, R. Chomko, T.-M. Lu, D. Litvinov, “Three-dimensional magnetic recording – an emerging nanoelectronic technology,” J. Nanoelectronics and Optoelectronics 1, 1-18 (2006).
    101. Smith, Chunsheng E, S. Khizroev, D. Litvinov, “Magnetoresistive playback heads for bit-patterned medium recording applications,” J. Appl. Phys. 99, 014503 (2006).
    102. Parekh, Chunsheng E, D. Smith, A. Ruiz, P. Ruchoeft, E. Svedberg, S. Khizroev, D. Litvinov, “Fabrication of a high-anisotropy nanoscale patterned magnetic recording medium for data storage applications,” Nanotechnology 17, 2079 (2006).
    103. Khizroev, Y. Hijazi, N. Amos, R. Chomko, and D. Litvinov, “Considerations in the design of three-dimensional and multi-level magnetic recording,” J. Appl. Phys. 100, 63907 (2006).
    104. Chomko, D. Litvinov, and S. Khizroev, “A nanoscale transducer for perpendicular magnetic recording,” Appl. Phys. Lett. 87, 162503 (2005).
    105. Chunsheng E, D. Smith, J. Wolfe, D. Weller, Khizroev, D. Litvinov, “Physics of patterned magnetic medium recording: design considerations,” J. Appl. Phys. 98 , 024505 (2005).
    106. Khizroev, R. Chomko, Y. Hijazi, S. Mukherjee, R. Chantrell, X. Wu, R. Carley, D. Litvinov, “FIB-fabricated nanoscale magnetoresistive sensor,” Appl. Phys. Lett. 86, 42502 (2005).
    107. Litvinov, S. Khizroev, “Perpendicular recording: playback,” Appl. Phys. Reviews – Focused Review, JAP 97, 071101 (2005).
    108. Candocia, E. Svedberg, D. Litvinov, S. Khizroev, “Deconvolution processing for increasing the resolution of magnetic force microscopy measurements,” Nanotechnology 15, S575-84 (2004).
    109. Khizroev, D. Litvinov, “Physics of perpendicular recording: writing process,” Appl. Phys. Reviews – Focused Review, JAP 95 (9), 4521 (2004).
    110. Khizroev, D. Litvinov, “Focused-ion-beam-based rapid prototyping of Nanoscale magnetic devices,” Review in Nanotechnology 14, R7-15 (2004).
    111. Mukherjee, D. Litvinov, and S. Khizroev, “Atomic-scale modeling of nanoconstrictions,” IEEE Trans. Magn. 40 (4), 2143-5 (2004).
    112. Litvinov, E. Svedberg, T. Ambrose, F. Chen, E. Schlesinger, J. Bain, and S. Khizroev, “Ion implantation of magnetic thin-films and nanostructures,” JMMM 283 (1), 128-32 (2004).
    113. Litvinov, M.H. Kryder, and S. Khizroev, "Physics of Perpendicular Recording: Playback," Journal of Applied Physics 93 (11), 9155-64 (2003).
    114. Litvinov, S. Khizroev, “Overview of magneto-resistive probes heads for Nanoscale magnetic recording applications,” J. Magn. Magn. Mat. 264 (2-3), 275-83 (2003).
    115. Lyberatos, D. Litvinov, and S. Khizroev, "Thermal effects in the high-speed switching of the magnetization of fine grains," Japanese J. Appl. Phys. 42 (4A Part I), 1598-602 (2003).
    116. Khizroev and D. Litvinov, "Parallels between playback in perpendicular and longitudinal recording," J. Magn. Magn. Mat. 257 (1), 126-31 (2003).
    117. Svedberg, D. Litvinov, R. Gustafson, and S. Khizroev, "Magnetic force microscopy of skew angle dependencies in perpendicular magnetic recording," J. Appl. Phys. 93 (3), 2828-33 (2003).
    118. Khizroev, J. Bain, and D. Litvinov, "Focused ion beam fabrication of nanomagnetic probes," Nanotechnology 13, 619-22 (2002).
    119. Khizroev, D. A. Thompson, M. H. Kryder, and D. Litvinov, "Direct observation of magnetization switching in focused-ion-beam-fabricated magnetic nanotubes," Appl. Phys. Lett. 81 (12), 2256 (2002); Editor's choice for the Virtual Journal of Nanoscale Science & Technology, September 23rd (2002).
    120. B. Svedberg, S. Khizroev, C. H. Chang, and D. Litvinov, "Signal-to-noise deterioration in perpendicular storage media by thermal and magnetic field aging as determined by magnetic force microscopy," J. Appl. Phys. 92 (11), 6714-20 (2002).
    121. Khizroev, R. W. Gustafson, J. K. Howard, M. H. Kryder, and D. Litvinov, "Multiple magnetic image reflection in perpendicular recording," IEEE Trans. Magn. 38 (5), 2066-8 (2002).
    122. Litvinov, J. Wolfson, J. A. Bain, R. W. Gustafson, M. H. Kryder, and S. Khizroev, "Narrow-gap single pole heads," IEEE Trans. Magn. 38 (5), 2252-4 (2002).
    123. Litvinov, A. Lyberatos, M. H. Kryder, J. Wolfson, J. A. Bain, and S. Khizroev, "Recording layer influence on the dynamics of perpendicular recording," IEEE Trans. Magn 38 (5), 1994-6 (2002).
    124. Khizroev, A. Lyberatos, M. H. Kryder, and D. Litvinov, "Physics of perpendicular recording: effects of magnetic "charge" distribution," Japanese J. Appl. Phys., Part 2 Letters 41 (7A), L758-60 (2002).
    125. Litvinov and S. Khizroev, "Orientation-sensitive magnetic force microscopy in future probe storage applications," Appl. Phys. Lett. 81 (10), 1878 (2002); Editor's choice for the Virtual Journal of Nanoscale Science & Technology, September 9th (2002).
    126. Litvinov and S. Khizroev, "Perpendicular Recording: A Future Technology or a Temporary Solution," Proceedings of the 10th NASA Goddard Space Flight Center Conference on Mass Data Storage Systems and Technologies, 1-19 (2002).
    127. Khizroev, Y. Liu, K. Mountfield, M. Kryder, D. Litvinov, “Physics of perpendicular magnetic recording: writing process,” JMMM 246 (1-2), 335-44 (2002).
    128. Litvinov and S. Khizroev, “Focused ion beam (FIB) in future probe storage industry,” Nanotechnology 13, 179-84 (2002).
    129. Khizroev, D. Litvinov, “Response to Comment on `On the mechanism of the cubic phase formation in the boron nitride thin-film systems,'' Appl. Phys. Lett. 80 (7), 1308-9 (2002).
    130. Litvinov, J. Wolfson, J. Bain, R. Gustafson, M. H. Kryder, S. Khizroev, “The role of the gap in single pole heads in perpendicular recording, “IEEE Trans. Magn. 38 (4), 1658-63 (2002).
    131. Wu, L. Holloway, H. Laidler, K. O’Grady, S. Khizroev, D. Litvinov, J.K. Howard, R.W. Gustafson, “Magnetic characterization of perpendicular recording,” IEEE Trans. Magn. 38 (4), 1682-6 (2002).
    132. B. Svedberg, S. Khizroev, and D. Litvinov, “Magnetic force microscopy study of perpendicular media,” J. Appl. Phys. 91 (8), 5365-5370 (2002).
    133. Wolfson, J. Bain, S. Khizroev, D. Litvinov, “Dynamic Kerr imaging of soft underlayers (SUL’s) for perpendicular magnetic recording applications,” J. Appl. Phys. 91(10), 8665-9 (2002).
    134. Litvinov, M. Kryder, and S. Khizroev, “Recording physics of perpendicular media: recording layers,” J. Magn. Magn. Mat. 241(2-3), 453-465 (2002).
    135. Litvinov, T. Roscamp, Mei-Ling Wu, T. Klemmer, J. K. Howard, and S. Khizroev, “CoB/Pd multilayer based recording layers for perpendicular media,” 2001 MRS Proceedings 674, T3.9 (2001).
    136. Roy, D. Laughlin, T. Klemmer, K. Howard, S. Khizroev, and D. Litvinov, “Seed-layer effect on microstructure and magnetic properties of Co/Pd multilayers,” J. Appl. Phys. 89 (11), 7531-3 (2001).
    137. Lu, T. Klemmer, S. Khizroev, J. K. Howard, and D. Litvinov, “CoCrPtTa/Ti perpendicular media deposited at high sputtering rate,” IEEE Trans. Magn. 37 (4), 1319-21 (2001).
    138. Litvinov, J. Wolfson, J. Bain, R. White, R. Chomko, R. Chantrell, and S. Khizroev, “Dynamics of perpendicular recording heads,” IEEE Trans. Magn. 37 (4), 1376-8 ( 2001).
    139. Lyberatos, S. Khizroev, and D. Litvinov, “High speed coherent switching of longitudinal recording media,” IEEE Trans. Magn. 37 (4), 1369-71 (2001).
    140. Khizroev, M. Kryder, and D. Litvinov, “Next generation perpendicular systems,” IEEE Trans. Magn., 37 (4), 1922-4 (2001).
    141. Khizroev, D. Litvinov, “On the mechanism of the cubic phase formation in the boron nitride thin film systems,” Appl. Phys. Lett. 79 (3), 353-5 (2001).
    142. Litvinov, M. Kryder, and S. Khizroev, “Recording physics of perpendicular media: soft underlayers,” JMMM 232 (1-2), 84-90 (2001).
    143. Litvinov, R. Chomko, G. Chen, L. Abelmann, K. Ramstock, S. Khizroev, "Micromagnetics of a Soft Underlayer," IEEE Trans. Magn., 36 (5), 2483-5 (2001).
    144. Litvinov, H. Gong, D. Lambeth, S. Khizroev, K. Howard, “RHEED based texture determination: magnetic thin films for perpendicular media,” J. Appl. Phys., 87 (9), 5693-5 (2000).
    145. Abelmann, S. Khizroev, D. Litvinov, J. A. Bain, J. Zhu, M. H. Kryder, K. Ramstock, C. Lodder, “Micromagnetic simulation of ultra‑small single pole perpendicular heads,” J. Appl. Phys., 87 (9), 6636-8 (2000).
    146. Litvinov, R. Chomko and S. Khizroev, “Color based thin film quality characterization,” to be published in IEEE Trans. Measurements and Instruments (2002).
    147. Khizroev, M. H. Kryder, Y. Ikeda, K. Rubin, P. Arnett, M. Best, D. A. Thompson, “Recording heads with trackwidths suitable for 100 Gbit/in2 density, “IEEE Trans. Magn., 35 (5), 2544-6 (1999).
    148. P. Jayasekara, S. Khizroev, M. H. Kryder, W. Weresin, P. Kasiraj, Fleming, “Inductive write heads using high moment FeAlN pole,” IEEE Trans. Magn. , 35 (2) pt.1, 613-8 (1999).
    149. Khizroev, W. Jayasekara, J. A. Bain, R. E. Jones, Jr., M. H. Kryder, “MFM quantification of magnetic fields generated by ultra‑small single pole perpendicular heads,” IEEE Trans. Magn., 34 (4), pt.1, 2030-2 (1998).
    150. Khizroev, J. A. Bain, M. H. Kryder, “Considerations in the design of probe heads for 100 Gbit/in2 recording density,” IEEE Trans. Magn., 33 (5), pt.1, 2893-5 (1997).
    151. Khizroev, F. Zuo, G. C. Alexandrakis, J. A. Schlueter, U. Geiser, J. M. Williams, “Vortex pinning in layered organic superconductors: kappa-(BEDT-TTF)/sub 2/Cu[N(CN)/sub 2/]Br,“ J. Appl. Phys., 79 (8), pt.2B, 6586-8 (1996).
    152. Zuo, S. Khizroev, G. C. Alexandrakis, J. A. Schlueter, U. Geiser, J. M. Williams, ” Anomalous magnetization in single-crystal kappa‑[bis(ethylenedithiotetrathiafulvalene)]/sub2/Cu[N(CN)/sub2/]Br superconductors,” Physical Review B (Condensed Matter), 52 (18), R13126-9 (1995).
    153. Zuo, S. Khizroev, G. C. Alexandrakis, V. N. Kopylov, “Anomalous magnetization in single-crystal Tl/sub 2/Ba/sub2/CuO/sub 6/: Evidence of dimensional crossover, “Physical Review B (Condensed Matter), 52 (2), R755-8 (1995).
    154. Zuo, S. Khizroev, V. N. Kopylov, N. N. Kolesnikov, “Pinning of Josephson vortices in single crystals of Tl/sub2/Ba/sub 2/CuO/sub 6+ delta / superconductors, “Physica C, 243 (1-2), 117-22 (1995).
    155. Zuo, S. Khizroev, S. Voss, A. M. Hermann, “Vortex penetration in single-crystal Tl/sub 2/Ba/2/CuO/sub 6/ superconductors,” Physical Review B (Condensed Matter), 49 (13), 9252-5 (1994).
    156. Fontcuberta, L. Fabrega, X. Obradors, F. Zuo, S. Khizroev, X. Jiang; J. L. Peng, R. L. Greene, “Josephson decoupling in Nd/sub 1.85/Ce/sub 0.15/CuO/sub 4/ revisited, “Physical Review Letters, 73 (24), 3327-8 (1994).
    157. Zuo, S. Khizroev, X. Jiang; J. L. Peng, R. L. Greene, “Surface barriers and two-dimensional-collective pinning in single crystal Nd/sub 1.85/Ce/sub 0.15/CuO/sub 4- delta / superconductors, “Journal of Applied Physics, 76 (10), pt.2, 6953-5 (1994).
    158. Zuo, S. Khizroev, X. Jiang, J. L. Peng, R. L. Greene, “Evidence of thermal nucleation of two- dimensional point vortices in single-crystal Nd/sub 1.85/Ce/sub 0.15/Cu/sub2/O/sub 4-y/ superconductors, “Physical Review B (Condensed Matter), 49 (17) 12326-9 (1994).
    159. Zuo, S. Khizroev, X. Jiang; J. L. Peng, R. L. Greene, “Josephson decoupling in single crystal Nd/sub 1.85/Ce/0.15/Cu/sub2/O/sub 4-y/ superconductors, “Physical Review Letters, 72 (11), 1746-9 (1994).

  • CONFERENCE PRESENTATIONS

    1. Hadi Mokhtari Dowlatabad, Steven Walston, University of Southern California; Elric Zhang, Vitaly Pustovalov, Salvador Pane, ETH Zurich; Kimberly Gokoffski, University of Southern California, University of California Irvine; Sakhrat Khizroev, University of Miami; Mark Humayun, Gianluca Lazzi, University of Southern California, “Magnetoelectric NanoParticle based wireless retinal stimulation,” 12th International IEEE IMBS Conference on Neural Engineering, TH3.R2.10 presentation, San Diego, CA, 11-13 November, 2025.
    2. Pardo, S. Gimenez, A. Colomina, S. Barber, C. Cos, V. Costumero, S. Khizroev, “Toward Non-Invasive Precision Neuromodulation: Functional Impact of Magnetoelectric Nanoparticles In Vivo,” Poster and oral presentation, BBI2025. London, 2025
    3. Marta Pardo, Victoria Andre, Silvia Gimenez, Alvaro Colomina, Sonia Barber, Sakhrat Khizroev, “Effect of intracerebral Magnetoelectric nanoparticles on behavioral outcomes,” The 1st International Online Conference on Diseases, Section: Neuropsychiatric Disorders, sciforum-127470, September 3, 2025.
    4. Mokhtari Dowlatabad, V. Pustovalov, E. Zhang, S. T. Ege Iseri, K.K. Gokoffski, M.S. Humayun, S. Khizroev, S. Pane, G. Lazzi, “Wireless retina stimulation with magnetoelectric nanoparticles,” International Conference on Electromagnetics inn Advanced Applications (ICEAA), IEEE-APS Topical Conference on Antennas and Propagation in Wireless Communications, September 8-12, 2025, Palermo, Italy.
    5. (invited) S. Khizroev, “Brain-machine interface through nanotechnology,” Congressi Stefano Franscini “Advancements in Nanotechnologies for Precision Brain Interfacing,” Symposium at the Monte Verita Centre, March 30 – April 3, 2025, Ascona, Switzerland (a highly selective conference in the field of neurotechnology)
    6. (invited) S. Khizroev, “MagnetoElectric NanoParticles for Precision Biomedical Applications,” NanoFlorida International Conference, March 14-16, 2025, Miami, FL, U.S.A.
    7. Chen, E. Zhang, C.Y. Chang, P. Liang, D. Radu, S. Khizroev, “Physics of neuromodulation with magnetoelectric nanoparticles,” 6th International Brain Stimulation Conference, February 23-26, 2025, Kobe, Japan.
    8. (invited) S. Khizroev, “Enabling a Wireless Non-invasive Two-Way Brain-Machine Interface with MagnetoElectric NanoParticles,” 2025 Joint Intermag-MMM, January 13-17, 2025, New Orleans, U.S.A. (highly selective invitation to talk at the most prestigious biennial conference in the field of magnetism, magnetic devices and materials)
    9. (invited) S. Khizroev, “MagnetoElectric NanoParticles for Precision Biomedical Applications,” International Symposium on Integrated Magnetics 2025 (iSIM 2025), January 12-13, 2025, New Orleans, U.S.A.
    10. Zhang, M. Shotbolt, M. Abdel-Mottaleb, M. Campos, B. Navarrete, Y. Yildirim, V. Andre, P. Liang, B. Noga, S. Khizroev, “Cellular manipulation on the magnetoelectric nanoparticle platform,” International Conference on Magnetism (ICM), June 30 – July 5, 2024, Bologna, Italy
    11. (invited) S. Khizroev, “Enabling wireless non-invasive two-way brain-machine interface with magnetoelectric nanoparticles,” plenary talk at the 2024 Applied Computational Electromagnetics Society (ACES) Conference, May 19-22, 2024, Orlando, FL.
    12. (invited) S. Khizroev, “CG-01: Wireless non-invasive brain stimulation with magnetoelectric nanoparticles” The 68th Annual Magnetism and Magnetic Materials (MMM) Conference by American Institute of Physics (AIP), CG-01, October 30-November 3, 2023, Dallas, TX.
    13. Zhang, M. Abdel-Mottaleb, M. Alberteris, B. Navarrete, V. Andre, M. Shotbolt, I. Smith, B. Noga, P. Liang, S. Khizroev, “CG-02: Wireless multi-channel control over motor cortex with magnetoelectric nanoparticles,” The 68th Annual Magnetism and Magnetic Materials (MMM) Conference by American Institute of Physics (AIP), CG-01, October 30-November 3, 2023, Dallas, TX.
    14. (invited) S. Khizroev, “Magnetoelectric nanoparticles as a wireless brain-machine interface,” The 4th International Symposium on 3D Power Electronics and Manufacturing (PEIM), February 1-3, 2023, Miami, FL.
    15. Zhang, M. Abdel-Mottaleb, M. Campos, B. Navarrete, Y. Yildirim, V. Andre, M. Shotbolt, I. Smith, P. Liang, B. R. Noga, S. Khizroev, “Wireless multi-channel motor cortex stimulation with magnetoelectric neural interfaces,” PSTR057.03/VV49, The 2023 Annual Society for Neuroscience (SfN) Conference, November 10-15, 2023, Washington, DC.
    16. Andre, M. Abdel-Mottaleb, Y. Akin, S. Chen, E. Zhang, M. Shotbolt, X. Jin, P. D. Ganzer, B. R. Noga, P. Liang, S. Khizroev, “Antibody conjugated magnetoelectric nanoparticles for enhanced wireless brain stimulation, PSTR379.07/XX27, The 2023 Annual Society for Neuroscience (SfN) Conference, November 10-15, 2023, Washington, DC.
    17. Zhang, M. Abdel-Mottaleb, J. Shulgach, M. Murphy, B. Navarrete, M. Alberteris, V. Andre, M. Shotbolt, Y. Akin, I. Smith, B. Noga, D. Griffin, D. Webber, P. Liang, and S. Khizroev, “Magnetoelectric nanoparticles as a platform for wireless brain machine interface,” PuzzleX, an annual MRS meeting, November, 2022, Barcelona, Spain.
    18. Zhang, M. Abdel-Mottaleb, Y. Akin, B. Navarrete, M. Alberteris, I. Smith, B. Yildirim, V. Andre, M. Shotbolt, P. Liang, S. Khizroev, “Core-shell magnetoelectric nanoparticles as wireless, nanoscale alternatives to electrodes for direct neural stimulation,” The MMM 2022 Annual Conference, October 31 – November 4, 2022, Minneapolis, MN.
    19. Jonathan Shulgach, Max Murphy, Elric Zhang, Mostafa Abdel-Mottaleb, Manuel Campos, Shawnus Chen, Sakhrat Khizroev, Ping Liang, Douglas Weber, Darcy Griffin, “Distinctive motor neuron recruitment with intracortical microstimulation and wireless cortical stimulation using targeted delivery of magnetoelectric nanotransducers,” 31st Annual Meeting of Society for the Neural Control of Movement (NCM), Dubin, Ireland, July 26-29, 2022.
    20. Sakhrat Khizroev, “Intelligent Materials for Medical Applications,” invited talk at Florida Memorial University (FMU), Miami, FL, April 12, 2022.
    21. Khizroev, “Intelligent materials for wireless brain-machine interface,” Invited Speaker at the #xTechBOLT Accelerated Learning Symposium at the Association of United States Army (AUSA) 2022 Annual Meeting in Washington, DC, October 10-12, 2022.
    22. Khizroev, “Intelligent materials for wireless brain-machine interface,” Invited Speaker at the 2021 Winter BeMagic Materials Workshop, ETH-Zurich, Zurich, Switzerland, October 2021.
    23. Nguyen, Z. Vriesman, P. Andrews, S. Masood, M. Stewart, S. Khizroev, X. Jin, “Magneto-electric nanoparticles (MENs) cobalt ferrite-barrium titanate for non-invasive neuromodulation,” J. Clinical and Translational Science 4 (s1), 11, 2020.
    24. Liang, E. Zhang, S. Chen, I. Smith, A. Fung, M. A. Campos, B. Navarrete, I.T. Smith, T. Nguyen, X. Jin, S. Khizroev, “Magnetoelectric nanoparticles – based wireless in vitro neuron stimulation with sub-100-um spatial differentiation,” IEEE Brain Workshop on Advanced NeuroTechnologies, October 22-23, 2020
    25. Khizroev (invited), “Multiferroic nanoparticles to enable technobiology paradigm in nanomedical applications,” Cambridge Healthtech Institute’s Conference, Biosensors 2018, Medical Sensors for Integrated Healthcare Applications, Aloft Boston Seaport Hotel, May 16-17, 2018, Boston, MA
    26. Khizroev (invited) “Understanding the Mind with Technobiology,” invited colloquium in Indiana University Purdue University – Indianapolis (IUPUI), Stark Neuroscience Institute, April 24, 2018, Indianapolis, IN
    27. Khizroev (recommendation by NAE members J. Tien and D. Berg) “Technobiology,” BIONIUM Monthly Seminar, Joint Seminar between University of Miami College of Engineering and College of Medicine, April 18, 2018, Coral Gables, FL
    28. Khizroev (keynote speaker), Technobiology, FIU STEMCon 2018, stemcon.fiu.edu, Undergraduate Student Success Conference, February 12th, 2018, Miami, FL
    29. Khizroev, TEDxCoconutGrove talk “Meet Technobiology’s Wireless Messenger: The Nanoparticle”: https://www.youtube.com/watch?v=qcDnFK7iOoY, March 2, 2018, Miami, FL
    30. Khizroev (invited), “Technobiology Paradigm Shift in Precision Medicine,” invited talk at Biological and Chemical Sensors Summit 2017, December 5-7, San Diego, CA
    31. Khizroev, “Technobiology to treat neurodenerative diseases,” Society for Brain Mapping and Therapeutics 14th Annual Congress, March 17-20, 2017, Los Angeles, CA
    32. Khizroev (invited) “Technobiology paradigm shift in nanomedicine,” Robert Haddon Symposium, University of California – Riverside, April 16, 2017, Riverside, CA
    33. Stimphil, A. Nagesetti, A. Rodzinski, C. Runowicz, P. Liang, and S. Khizroev, “Magnetoelectric nanoparticles for treatment of cancer,” AACR Annual Meeting, Session PO.CH01.03 – Drug Delivery, April 1-5, 2017, Washingon, D.C.
    34. Khizroev (invited), “3D Navigation of magnetic nanoparticles via metastable physics,” Feinstein Institute for Medical Research Symposium, March 29-30, 2017, Notre Dame, IN
    35. Khizroev (invited), “Technobiology Paradigm Shift in Medicine,” an invited talk at the monthly colloquium, University of Connecticut, January 20, 2017, Storrs, CT
    36. Khizroe (invited), “Magnetoelectric nanoparticles for enabling nanomedicine,” an invited colloquium at the 17th IEEE Biennial Conference on Electromagnetic Field Computation (CEFC), November 13-16, 2016, Miami, FL
    37. Stewart, E. Stimphil, R. Guduru, A. Rodzinski, P. Liang, C. Runowicz, L. Salgueiro, A. Schally, and S. Khizroev, “Magnetoelectric nanoparticles cross blood-brain barrier to delivery anti-tumor peptide to glioblastoma cells with on-demand release,” American Association of Cancer Research (AACR), April 16-20, 2016, New Orleans, LA
    38. Rodzinski, R. Guduru, E. Stimphil, T. Stewart, P. Liang, C. Runowicz, and S. Khizroev, “Targeted, controlled anticancer drug delivery and release with magnetoelectric nanoparticles,” American Association of Cancer Research (AACR), April 16-20, 2016, New Orleans, LA
    39. Hong and S. Khizroev, “3D Self-assembled shape transformation of iron oxide nanoparticles for the applications to biological systems,” ER-9, 13th Joint MMM-Intermag Conference, January 11-15, 2016, San Diego, CA
    40. Hong, E. Santos, E. Bekyarova, A. T. N. N’Diaye, A. Scholl, G. Chen, M. Nowakowski, A. Young, E. Arenholz, W. de heer, S. Khizroev, C. Hwang, R. C. Haddon, J. Bokor, “Chemically engineered ferromagnetism in graphene,” FI-02, 13th Joint MMM-Intermag Conference, January 11-15, 2016, San Diego, CA
    41. Hong, A. Hadjikhani, F. Allen, M. Stone, R. Guduru, V. Safonov, J. Bokor, and S. Khizroev, “The physics of spin-transfer torque switching in magnetic tunneling junctions in sub-10-nm size range,” GT-12, 13th Joint MMM-Intermag Conference, January 11-15, 2016, San Diego, CA
    42. Khizroev and C. Runowicz, “Using smart particles to treat cancer,” TEDxFIU talk, November 5, 2015, Miami, FL
    43. Rodzinski, T. Stewart, …, C. Runowicz, and S. Khizroev, “A novel mechanism for field-controlled high-specificity targeted anticancer drug delivery and on-demand release using magnetoelectric nanoparticles,” October 23-26, 2015, Fourth American Association of Cancer Research (AACR) International Conference on Frontiers in Basic Cancer Research, Philadelphia, PA
    44. Stone, …, and S. Khizroev, “Anomalous properties of sub-10-nm magnetic tunneling junctions,” October 1-2, 2015, 4th Berkeley Symposium on Energy Efficient Electronics Systems, Berkeley, CA
    45. Khizroev, “A magnetic spin on cancer treatment,” May 21, 2014, IEEE Miami Section Distinguished Lecture, Miami, FL
    46. Khizroev, “Treating cancer with nanotechnology,” March 28, 2014, Houston, TX
    47. Khizroev, “Breaking barriers in understanding the brain,” FAU/Max Planck Institute, Florida, November 21, 2013, FL
    48. Khizroev, “Personalized Nanomedicine,” April 22, 2013, USC, Los Angeles, CA
    49. Khizroev, “Considerations of superconducting states in bacteriorhodopsin based nanoelectronic devices,” IEEE Miami Section Distinguished Lecture Series, June 1, 2012, Miami, FL
    50. Khizroev, “Focused ion beam based rapid prototyping of nanoscale devices,” invited lecture at UT Austin Condensed Matter Physics/Complex Quantum Systems Seminar Series, April 12, 2012, Austin, TX
    51. Guduru and S. Khizroev, “Bacteriorhodopsin based nanoelectronics,” 2012 MRS Spring Meeting, April 9-12, 2012
    52. Khizroev, “Future of Nanomedicine,” Forefront Summit 2011, December 12-13, Mumbai, India
    53. Khizroev, “Nanotechnology in Medicine,” October 30, 2011, Florida Atlantic University, Boca Raton, FL
    54. Khizroev, “Protein-based Molecular Nanoelectronics,” 2010 National Science Foundation (NSF) Grantees’ Conference, Honolulu, Hawaii, December 2, 2010
    55. Khizroev, D. Litvinov, “GOALI: Dynamics and Manipulation of Logic States in Coupled Nanomagnetic Systems,” 2010 National Science Foundation (NSF) Grantees’ Conference, Honolulu, Hawaii, Dec 2, 2010
    56. Litvinov and S. Khizroev, “Recent advances and issues in nanoscale magnetic recording,” 2010 Workshop on Innovative Devices and Systems (WINDS), December 5-10, 2010, Honolulu, Hawaii
    57. Tian, N. Amos, B. Hu, D. Litvinov, and S. Khizroev, “Considerations in the design of a highly scalable magnetic logic channel,” BP-12, The 55th Magnetism and Magnetic Materials (MMM) Conference, November 14-18, 2010, Atlanta, Georgia
    58. Fernandez, D. Teweldebrhan, C. Zhang, N. Amos, A. A. Balandin, and S. Khizroev, “A comparative analysis between Ag and Cu heat sink layers in L1FePt films for heat-assisted magnetic recording,” FW-13, The 55th Magnetism and Magnetic Materials (MMM) Conference, November 14-18, 2010, Atlanta, Georgia
    59. Lee, N. Amos, D. Litvinov, and S. Khizroev, “Terabit-per-square-inch magnetic bit patterned media with a 26-nm pitch and a 9-nm square bit,” The 54th International Conference on Electron, Ion, and Photon Beam Technology and Nanofabrication, June 1-4, 2010, Anchorage, Alaska
    60. Amos, B. Lee, M. H. Shachar, R. M. Ikkawi, B. Hu, J. Hong, R. Fernandez, C. Zhang, S. Chen, M. Hudgins, D. Litvinov, S. Khizroev, “Multilevel three-dimensional bit patterned media for next-generation magnetic recording devices,” C-14, 11th Joint MMM-Intermag Conference, 18-22 January, 2010, Washington, DC
    61. Chang, M. Green, V. Kalatsky, P. Ruchhoeft, S. Khizroev, D. Litvinov, “Effects of low magnetic anisotropy inclusions on switching field distribution in patterned magnetic arrays,” 11th Joint MMM-Intermag Conference, 18-22 January, 2010, Washington, DC
    62. Khizroev, “Engineering for Medicine,” Colloquium, School of Medicine, UC Riverside, November, 2009
    63. Khizroev, “Multilevel 3D Magnetic Recording,” Annual Industry Colloquium of CMMR at UCSD, October 28, 2009
    64. Khizroev, “From Magnetic Recording to Protein Memory,” Colloquium Series, Department of Electrical Engineering, April 6, 2009, University of California, Los Angeles, CA
    65. Khizroev, “Molecular Electronics,” Mini Nanotechnology Conference, April 2-3, 2009, California State University, San Bernandino, CA
    66. Amos, A. Lavrenov, R. Fernandez, R. Ikkawi, D. Litvinov, and S. Khizroev, “High-resolution and high-coercivity FePt L10 Magnetic Force Microscopy nanoprobes to study next-generation magnetic recording media,” presented at 53rd annual Magnetism and Magnetic Materials (MMM) Conference, November 10-14, 2008, Austin, Texas
    67. Khizroev, “Protein-based recording for areal density beyond 1 Terabit/in2,” School of Engineering Seminar, University of California, Irvine, May 28, 2008, Irvine, CA
    68. Khizroev, N. Amos, “Overview of Multilevel 3D Magnetic Recording,” IEEE/TMRC Workshop on Next Generation Magnetic Recording Technologies, the most selective and prestigious meeting in the IEEE Magnetics Society, Houston, TX, March, 2008
    69. Amos, R. Fernandez, R. Ikkawi, A. Lavrenov, A. Krichevsky, Dmitri Litvinov, and S. Khizroev, “Plateau probes to enhance the capabilities of magnetic force microscopy,” presented at the annual IEEE International Magnetic Intermag 2008, Madrid, Spain, May 4-8, 2008
    70. Ikkawi, N.Amos, A.Balandin, D. Litvinov, S.Khizroev, “Numerical Analysis of Heat Transfer Mechanisms Induced by Laser Heating in Far- and Near- Field HAMR Systems,” presented at the annual IEEE International Magnetic Intermag 2008, Madrid, Spain, May 4-8, 2008
    71. Ikkawi, A. Krichevsky, A. Lavrenov, N.Amos, D. Litvinov, S.Khizroev, “ Exploiting far- and near-field optics to develop energy efficient transducer for HAMR,” presented at the annual IEEE International Magnetic Intermag 2008, Madrid, Spain, May 4-8, 2008
    72. Gomez, D. Litvinov, S. Khizroev, “Minimum parameters required to enable low-field low-size nano nuclear magnetic resonance (NanoNMR),” presented at the annual IEEE International Magnetic Intermag 2008, Madrid, Spain, May 4-8, 2008
    73. Ikkawi, N. Amos, A. Lavrenov, R. Chomko, D. Litvinov, S. Khizroev, “Design, fabrication, and characterization of a near-field optical transducer for heat-assisted magnetic recording for areal densities above 10 terabit/in2,” presented at 52nd annual Magnetism and Magnetic Materials (MMM) Conference, November 5-9, 2007, Tampa, Florida
    74. Amos, R. Fernandez, R. Ikkawi, B. Lee, A. Lavrenov, A. Krichevsky, D. Litvinov, S. Khizroev, “Magnetic force microscopy study of magnetic stripe domains in sputter deposited Permalloy thin films,” presented at 52nd annual Magnetism and Magnetic Materials (MMM) Conference, November 5-9, 2007, Tampa, Florida
    75. Amos, A. Krichevsky, K. Taylor, A. Lavrenov, B. Lee, E. Stefanescu, D. Litvinov, S. Khizroev, “Study of FIB-fabricated patterned media for next-generation magnetic recording devices,” presented at 52nd annual Magnetism and Magnetic Materials (MMM) Conference, November 5-9, 2007, Tampa, Florida
    76. (invited) Khizroev, “Nanoscale Information Storage and Memory,” presented at Colloquium, Electrical Engineering and Computer Science, The University of California, Irvine, October 10, 2007
    77. (invited) Khizroev, “Three-dimensional Magnetic Memory,” U.S. AFOSR 2007 Annual Nanoelectronics Review, Purdue University, West Laffayette, IN, May 21-24, 2007
    78. Amos, R. Ikkawi, A. Lavrenov, R. Chomko, S. Khizroev, “Multilevel magnetic recording devices,” presented at 10th Joint MMM-Intermag,Baltimore, MD, January 7-11, 2007
    79. Ikkawi, N. Amos, A. Lavrenov, R. Chomko, S. Khizroev, “Ferromagnetic resonance based memory devices,” presented at 10th Joint MMM-Intermag,Baltimore, MD, January 7-11, 2007
    80. Khizroev, N. Amos, R. Ikkawi, R. Chomko, “Nanomagnetic logic,” Semiannual DMEA-CNID Review, Riverside, CA, December 12, 2006
    81. (invited), Khizroev, A. Lavrenov, N. Amos, R. Chomko, D. Litvinov, “Focused ion beam as a nanofabrication tool for rapid prototyping of nanomagnetic devices,” Microscopy and Microanalysis 2006 Meeting, Chicago, IL, July 30 – August 3, 2006
    82. (invited) Khizroev, “Three-dimensional Magnetic Memory,” US Air Force Office of Scientific Research (AFOSR) annual Nanoelectronics program review, Carnegie Mellon University, Pittsburgh, PA, August 7-9, 2006
    83. (invited) D. Litvinov, V. Parekh, Chunsheng E, D. Smith, A. Ruiz, P. Ruchhoeft, J. Rantschler, and Khizroev, “Design and fabrication of high anisotropy nanoscale patterned magnetic recording medium for data storage applications,” 210th Meet. Electrochem. Soc. 602, 1684 (2006), Cancun, Mexico, October 29 – November 3, 2006
    84. Renugopalakrishnan, S. Khizroev, L. Lindvold, P. Li, H. Anand, “Protein-based memory,” Nanoscience and Nanotechnology, 2006, ICONN’06, Intern. Conf. on Nanoscience and Nanotechnology, July 3-7, 2006, ISBN: 1-4244-0453-3
    85. Hijazi, N. Amos, A. Lavrenov, D. Doria, E. Felissaint, R. Chomko, D. Litvinov, S. Khizroev, IEEE Intermag Conference, San Diego, May 7-12, 2006
    86. Khizroev, Y. Hijazi, N. Amos, D. Doria, A. Lavrenov, R. Ikkawi, R. Chomko, D. Litvinov, S. Khizroev, “Nanoscale information systems,” 2006 Nanomaterials for Defense Applications Symposium, Virginia Beach, VA, May 1-4, 2006
    87. (invited) Khizroev, R. Chomko, Y. Hijazi, N. Amos, R. Ikkawi, E. Felissaint, “Future Data Storage Technologies,” International Nano/Bio Forum, Milan, Italy, September 28-29, 2005
    88. (invited) Khizroev, Y. Hijazi, N. Amos, F. Candocia, R. Chomko, “Nanoscale Memory Devices,” presented at US Air Force Office of Scientific Research (AFOSR) annual program review in Nanoelectronics, UC San Diego, La Jolla, California, July 26-28, 2005.
    89. (invited) N. Amos, R. Ikkawi, R. Chomko, V. Renugopalakrishnan, D. Litvinov, Khizroev, “Magnetic and Protein Memory Systems for Areal Densities Beyond 1 Terabit/in2,” 2nd IEEE Conference on Nanoscale Devices and System Integration (NDSI-2005), Houston, Texas, April 4-6, 2005
    90. (invited) Khizroev, “Next-generation Memory Devices,” NASA Center for Data Imaging, Florida Atlantic University, Boca Raton, December 8, 2004
    91. (invited) Khizroev, “Nanoscale Memory Devices,” Solid State Technology and Devices Seminar at the University of California at Berkeley, October 22, 2004
    92. (invited) V. Renugopalakrishnan, R. Nair, R. Chomko, P. Li, A. Strzelczyk, H. Arjomandi, D. Litvinov, Khizroev, “Nanoscale transducer for writing and reading from protein-based storage media,” presented at an annual conference on Nano and Giga Challenges in Microelectronics, Cracow, Poland, September 13-17, 2004, to be published in Microelectronic Engineering
    93. (invited) Khizroev, N. Amos, R. Chomko, “Three-dimensional Magnetic Memory,” presented at US Air Force Office of Sponsored Research (AFOSR) annual meeting Quantum Electronics and Nanotechnology Workshop, Lakeview Golf Resort, Morgantown, West Virginia, August 4-6, 2004
    94. (invited) R. Nair, H. Arjomandi, V. Renugopalakrishnan, R. Chomko, D. Litvinov, and Khizroev, “Write/read mechanisms for protein-based data storage,” IEEE Conference on Nanoscale Devices and System Integration (NDSI-2004), Miami, Florida, February 15-19 2004
    95. Lavrenov, R. Chomko, D. Litvinov, and S. Khizroev, “Near-field optical recording systems for heat-assisted magnetic recording,” IEEE Conference on Nanoscale Devices and System Integration (NDSI-2004), Miami, Florida, February 15-19 2004
    96. Mukherjee, D. Litvinov, and S. Khizroev, “Geometrically confined magnetic nanoconstrictions,” 2004 Joint MMM-Intermag Conference, Anaheim, California, January 5-9 2004
    97. (invited) Khizroev and D. Litvinov, “FIB-based Rapid Prototyping of Nanoscale Devices,” University of Alcala, Madrid, Spain, September 11 2003
    98. (invited) D. Litvinov and Khizroev, “Next generation magnetic nanotransducers,” Nano-Vivo Summit, Houston, Texas, July 2003
    99. (invited) D. Litvinov and Khizroev, “Nanotechnology applications in magnetic data storage,” 10th International Conference on Composite Engineering, New Orleans, Louisiana, July 2003
    100. (invited) Khizroev and D. Litvinov, “Nanoscale magnetic recording,” Rensellaer Polytechnic Institute, March 27 2003
    101. (invited) Khizroev and D. Litvinov, “Focused ion beam for Nanoscale magnetic applications,” 47th Biophysical Society Annual meeting, San Antonio, Texas, March 1-5 2003
    102. (invited) Khizroev and D. Litvinov, “FIB and Nanoscale magnetic applications,” 2003 NNUN Japan-US Symposium, Tools and Metrology for Nanotechnology, Cornell University, Ithaca, NY, January 21-24 2003
    103. Khizroev, J. A. Bain, D. Litvinov, “Focused ion beam fabrication of nanomagnetic probes,” 47th Annual MMM Conference, Tampa. Florida, November 11-15th, 2002
    104. Khizroev, D. Litvinov, “Orientation-sensitive magnetic force microscopy for future probe storage applications,” 47th Annual MMM Conference, Tampa. Florida, November 11-15th, 2002
    105. (invited) D. Litvinov and Khizroev, “Fundamental challenges facing perpendicular recording," 47th Annual MMM Conference, Tampa. Florida, November 11-15th 2002
    106. Khizroev, R. W. Chantrell, T. Roscamp, R. W. Gustafson, D. Litvinov, “Fundamentals of Soft Underlayer during playback,” 47th Annual MMM Conference, Tampa. Florida, November 11-15th 2002
    107. B. Svedberg, R. W. Chantrell, D. Litvinov, S. Khizroev, “Skew angle dependent bit shape for various bit densities in a perpendicular medium for data storage, ” 47th Annual MMM Conference, Tampa. Florida, November 11-15th 2002
    108. Khizroev, D. A. Thompson, M. H. Kryder, D. Litvinov, “Direct observation of magnetization switching in focused-ion-beam-fabricated magnetic nanotubes,” 47th Annual MMM Conference, Tampa. Florida, November 11-15th 2002
    109. Litvinov and S. Khizroev, “Magneto-resistive probe heads design considerations for nanoscale magnetic recording applications,” 47th Annual MMM Conference, Tampa. Florida, November 11-15th 2002
    110. Ridley, G. W. Roberts, R. Chantrell, S. Khizroev, D. Litvinov, “Effects of a soft underlayer on perpendicular magnetic recording,” 47th Annual MMM Conference, Tampa. Florida, November 11-15th 2002
    111. B. Svedberg, S. Khizroev, C. H. Chang, and D. Litvinov, "Signal-to-noise deterioration in perpendicular storage media by thermal and magnetic field aging as determined by magnetic force microscopy," Intermag 2002, Amsterdam, April 28th - May 2nd 2002
    112. Litvinov, J. Wolfson, J. A. Bain, R. W. Gustafson, M. H. Kryder, and S. Khizroev, "Narrow-gap single pole heads," Intermag 2002, Amsterdam, April 28th - May 2nd 2002
    113. Lyberatos, D. Litvinov, and Khizroev, "Thermal effects in the high-speed switching of the magnetization of fine grains," Intermag 2002, Amsterdam, April 28th - May 2nd 2002
    114. Khizroev, R. W. Gustafson, J. K. Howard, M. H. Kryder, and D. Litvinov, "Multiple magnetic image reflection in perpendicular recording," Intermag 2002, Amsterdam, April 28th - May 2nd 2002
    115. Litvinov, A. Lyberatos, M. H. Kryder, J. Wolfson, J. A. Bain, and Khizroev, "Recording layer influence on the dynamics of perpendicular recording," Intermag 2002, Amsterdam, April 28th - May 2nd 2002
    116. Khizroev and D. Litvinov, "Physics of perpendicular recording: effects of magnetic "charge" distribution," Intermag 2002, Amsterdam, April 28th - May 2nd 2002
    117. Khizroev and D. Litvinov, "Parallels between playback in perpendicular and longitudinal recording," Intermag 2002, Amsterdam, April 28th - May 2nd 2002
    118. (invited) D. Litvinov and Khizroev, "Perpendicular recording: the future or just a temporary solution?" NASA Goddard Conference on Mass Data Storage Systems and Technologies, Baltimore, MD, April 15-18th 2002
    119. (invited) J. Wu, L. Holloway, H. Laidler, K. O’Grady, Khizroev, G. W. Gustafson, J. K. Howard, D. Litvinov, “Magnetic characterization of perpendicular media,” the 1st NAPMRC in Coral Gables, January 2002
    120. (invited) D. Litvinov, J. Wolfson, J. Bain, R. Gustafson, K. Howard, M. Kryder, Khizroev, "The role of the gap in single pole heads in perpendicular recording," the 1st NAPMRC in Coral Gables, January 2002
    121. Khizroev, A. Lyberatos, M. Kryder, D. Litvinov, “Effects of charge distribution in a perpendicular medium,” presented at the MMM’2001 conference, Seattle, Washington, November 12-16, 2001
    122. (invited) J. Wolfson, J. Bain, Khizroev, D. Litvinov, “Dynamic Kerr imaging of soft underlayers (SUL’s) for perpendicular magnetic recording applications,” presented at the MMM’2001 conference, Seattle, Washington, November 12-16, 2001
    123. Lavrenov, D. Litvinov, Khizroev, “Study of the pinning nature in high-temperature superconductors via direct sensing of individual magnetic vortices,” presented at the MMM’2001 conference, Seattle, Washington, November 12-16, 2001
    124. Litvinov, Mei-Ling Wu, T. Klemmer, J. K. Howard, and S. Khizroev, “CoB/Pd multilayer based recording layers for perpendicular media,” 2001 MRS Spring Meeting, San Francisco, CA, April 16-20, 2001
    125. Roy, D. Laughlin, T. Klemmer, K. Howard, S. Khizroev, and D. Litvinov, “Seed-layer effect on microstructure and magnetic properties of Co/Pd multilayers,” presented at the 8th Joint MMM-Intermag Conference, San Antonio, Texas, January 7-11, 2001
    126. Lu, T. Klemmer, Khizroev, J. K. Howard, and D. Litvinov, “CoCrPtTa/Ti perpendicular media deposited at high sputtering rate,” presented at the 8th Joint MMM-Intermag Conference, San Antonio, Texas, January 7-11, 2001
    127. Litvinov, J. Wolfson, J. Bain, R. White, P. Riddley, R. Chantrell, and Khizroev, “Dynamics of perpendicular recording,” presented at the 8th Joint MMM-Intermag Conference, San Antonio, Texas, January 7-11, 2001
    128. Lyberatos, Khizroev, and D. Litvinov, “High speed coherent switching of longitudinal recording media,” presented at the 8th Joint MMM-Intermag Conference, San Antonio, Texas, January 7-11, 2001
    129. Litvinov, M. Kryder, and Khizroev, “Recording physics of perpendicular media,” presented at the 8th Joint MMM-Intermag Conference, San Antonio, Texas, U.S.A., January 7-11, 2001
    130. Khizroev, M. Kryder, and D. Litvinov, “Perpendicular recording beyond 100 Gbit/in2 density,” presented at the 8th Joint MMM-Intermag Conference, San Antonio, Texas, January 7-11, 2001
    131. Svedberg, S. Khizroev, and D. Litvinov, “Magnetic force microscopy study of perpendicular media,” presented at the 8th Joint MMM-Intermag Conference, San Antonio, Texas, January 7-11, 2001
    132. (invited) D. Litvinov, M. Kryder, and Khizroev, “Perpendicular recording,” presented at the Annual Lake Arrowhead conference 2000 (only 25 top industry leaders of the world are invited to attend the conference)
    133. Khizroev, R. M. Chomko, Y. Liu, K. Mountfield, M. H. Kryder, D. Litvinov, “Perpendicular systems above 100 Gbit/in2 density,” presentation at Intermag’2000, Toronto, Canada, April 9-13, 2000
    134. Litvinov, R. M. Chomko, L. Abelmann, K. Ramstöck, and Khizroev, “Micromagnetic of a soft underlayer,” Intermag’2000, Toronto, Canada, April 9-13, 2000
    135. Khizroev and D. Litvinov, “Vertical recording,” tutorial presented at the NSF DSSC Seminar, Carnegie Mellon University, Pittsburgh, PA, December 3rd, 1999, videotape of the presentation is available upon request, see http://www.ece.cmu.edu/research/dssc/education/oldseminars.shtml
    136. Litvinov, H. Gong, D. Lambeth, Khizroev, K. Howard, “RHEED based texture determination: magnetic thin films for perpendicular media,” presented at MMM’99, San Jose, CA, November 15-19, 1999
    137. Abelmann, S. Khizroev, D. Litvinov, J. A. Bain, J. Zhu, M. H. Kryder, K. Ramstock, C. Lodder, “Micromagnetic simulation of ultra‑small single pole perpendicular heads,” presented at MMM’99, November 1999
    138. Gan-Soo Park (Korea Maritime University, S. Korea), Khizroev, J. Bain, “New algorithm for magnetic recording head field considering head saturation,” Conference on the computation of the Electromagnetic fields, Sapporo, Japan, October 24-28, 1999
    139. Leon Abelmann, Klaus Ramstöck, Jim Bain, Jimmy Zhu, Rick Carley, Sakhrat Khizroev "If It’s Small, Is It Still Soft?" NSF DSSC Seminar, Carnegie Mellon University, Pittsburgh, USA, September 17th 1999, videotape of the presentation is available upon request, see http://www.ece.cmu.edu/research/dssc/education/oldseminars.shtml
    140. Khizroev, M. H. Kryder, Y. Ikeda, K. Rubin, P. Arnett, M. Best, D. A. Thompson, “Recording at 100 Gbit/in2 density,” presented at NSF DSSC Spring 1999 Technical Review, Carnegie Mellon University, Pittsburgh, PA, USA, 1999
    141. Khizroev, M. H. Kryder, Y. Ikeda, K. Rubin, P. Arnett, M. Best, D. A. Thompson, “Recording heads with trackwidths suitable for 100 Gbit/in2 density, “ presented at Intermag’99, International Magnetics Conference in Kyoungju, South Korea, talk (FB-08) on May 20th, 1999
    142. Khizroev, J. M. Schare, K. Mountfield, D. Cuthbert, S. Tamaru, J. A. Bain, R. E. Jones, Jr., M. H. Kryder, “A novel head structure for ultra-high density perpendicular recording,” was presented at the 43rd Annual Magnetism and Magnetic Materials - International Magnetics Conference in Miami, Florida, talk on November 12th, 1998
    143. Khizroev and M. H. Kryder, “FIB trimmed recording heads,” presented at NSF DSSC Fall 1998 Technical Review, Pittsburgh, PA, USA, October 20th, 1998
    144. (invited) W. P. Jayasekara, Khizroev, M. H. Kryder, W. Weresin, P. Kasiraj, Fleming, “Inductive write heads using high moment FeAlN pole,” was presented at the 9th Annual Magnetic Recording Conference on Magnetic Recording Heads (TRMC’98) in Boulder, Colorado, talk on August 17th, 1998
    145. Park, S. Khizroev, J. A. Bain, S. Charap, “Verification of head field by MFM quantification,” presented at the 8th Biennial Conference on Electromagnetic Field Computation, Tucson, Arizona, USA, June 1998
    146. Khizroev and M. H. Kryder, “Magnetic probe heads for densities approaching 100 Gbit/in2 ,” presented at NSF DSSC 8th year NSF Site Review, Pittsburgh, PA, USA, March 3rd , 1998
    147. Khizroev, W. Jayasekara, J. A. Bain, R. E. Jones, Jr., M. H. Kryder, “MFM Quantification of magnetic fields generated by ultra-small single pole perpendicular heads,” was presented at the 7th Joint Magnetism and Magnetic Materials – International Magnetics Conference in San Francisco, California, January 5-9, 1998
    148. Khizroev, M. H. Kryder, “MFM study of ultra-small single pole heads,” presented at NSF DSSC Fall 1997 Technical Review, Carnegie Mellon University, Pittsburgh, PA, USA, September 18th, 1997
    149. Khizroev, J.A. Bain, M. H. Kryder, “Considerations in the design of probe heads for 100 Gbit2 recording density,” presented at Intermag’97, International Magnetics Conference in New Orleans, Louisiana, April 1997
    150. Khizroev, J. A. Bain & M. H. Kryder, “Probe heads for 100 Gbit/in2 recording density,” at NSF DSSC Spring 1997 Technical Review, Carnegie Mellon University, Pittsburgh, PA, March 4th, 1997
    151. A number of presentations on superconductivity at MMM conferences before 1997
    152. A number of presentations at APS meetings

     

     

  • BOOKS & BOOK CHAPTERS

    • Opris, N. Preza, M.A. Lebedev, B.R. Noga, S.J. Chang, M.F. Casanova, M. Lupusoru, V.M. Pulgar, S. Khizroev, J. Bohorquez, A.I. Popescu, Augmentation of Brain Functions by Nanotechnology, chapter in Modern Approaches to Augmentation of Brain Function, p. 233-259, Springer, Cham, 2021
    • Bokor, J. Chatterjee, S. Khizroev, X.S. Li, B.R. Navarrete, A. Pattabi, S. Sayed, S. Salahuddin, D. Toledo, I. Torres, S.X. Wang, “E3S Theme IV: Nanomagnetics eBook,” Published by NanoHub, July, 2020, https://nanohub.org/resources/33846
    • Chapter in a book edited by I. Weinberg, “Image-guided placement of magnetic neuroparticles as a potential high-resolution brain machine interface,” book title: Evolving BCI Therapy-Engaging Brain State Dynamics, Infotec Publishers, 2018/2017
    • Eschaghian-Wilner, G. Sarkar, U. Sharma, R. Guduru, and S. Khizroev, Chapter 11: Nanomedicine using magnetoelectric nanoparticles, Wireless Computing in Medicine, O’Wiley, 2016.
    • Khizroev, R. Chomko, I. Dumer, D. Litvinov, “Multilevel and Three-dimensional Nanomagnetic Recording,” Chapter 6, Nano-scale and Bio-inspired Integrated Computing, edited by Mary M. Eshaghian-Wilner, Wiley Publishers, 2008
    • Candocia and S. Khizroev, chapter in “Nanophysics, Nanoclusters and Nanodevices,” Nova Science Publishers, 2006, ISBN: 1-59454-852-8
    • Khizroev, R. Chomko, and D. Litvinov, chapter “Nanoscale Magnetic Devices” in Handbook of Semiconductor Nanostructures and Nanodevices, edited by A.A. Balandin and K.L. Wang, American Scientific Publishers, 2005; ISBN 1-58883-073-X
    • Litvinov and S. Khizroev, chapter “Nanomaterials and Nanodevices Synthesized by Ion-beam Technology,” Dekker Encyclopedia in Nanoscience and Nanotechnology, 2005; ISBN 0-8247-4797-6
    • Khizroev and D. Litvinov, Perpendicular Magnetic Recording, (Kluwer Academic Publishers, 2004; ISBN 1-4020-2662-5) Currently, Springer ISBN 978-1-4020-2723-9 (Hard-cover Book) and 1-4020-2723-0 (e-book)

     

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