Contact Me: 

 

Dr Madan M. Kaila, Email: m.kaila@unsw.edu.au

School of Physics, University Of New south Wales

Sydney 2052 Australia, Ph. 612-93854561 ( W ), Fx. 612-93856060 ( W )

Ph./Fx. 612-97500731 ( H )

 

Education:

 

BSc Hons ( Physics ) Delhi University

Msc ( Nuclear Physics ) Delhi University

PhD Condensed Matter ( Solid-state Physics ) UNSW

Post doctorate UNSW

 

Experience:

 

Several years of teaching experience at undergraduate and postgraduate levels

in major physics ( medical physics ) and service physics ( optometry, biosciences and engineering ) programs.

 

Present Interests

 

Neuroscience

 

The human model of the brain has progressed significantly over the last decade or so. This is result of accelerated research efforts in neuro-physics and science all over the world over the recent years. The conventional magnetic resonance imaging ( single quantum identity of spins ) using static magnetic fields < 7T has played major role in imaging and its application to the development of brain science. Intermolecular multi-quantum coherence imaging ( iMQCI ) of the brain has helped sort out lots of mysteries of the brain functions. It is because, to acquire the microscopic level ( micron to mm scale ) of imaging details, one is after.  It puts lot of technological constrains on the MRI machine. Nevertheless one can see a systematic progress in that direction in the MRI research. Other than the basic research in the brain science, there are other benefits proceeding from this research. The microscopic imaging allows diagnostics of brain  tumors at the molecular level. This allows better understanding of the physics and chemistry of the events happened at the region of interest ( ROI ) which led to the creation of diseased cells. Thus one can extrapolate its origin and suggest advise for prevention of the tumors. The researcher at present is interested in modeling of the brain using computational techniques ( Mathematics, Metlab, etc ), through quantum nature of events happening in the brain in space and time. Later collaboration with a hospital or a brain ( neuroscience ) research institute is envisioned by the researcher. Unraveling the basics of quantum dynamical, physics, chemistry and mathematic(PCM) of a multi-nuclear spin ensemble like our brain, in its natural state, is the theme of the research and education in vision.

 

Previous Research Interests

 

Renewable Energy Sources, Solar Thermo-Electricity Generation, Thermal Sensors using high temperature superconductors, Thermal Conduction, Climate Science, Environment Science, etc.

Semiconductor materials physics and devices. High temperature superconductor materials and devices.

 


Publications

 

Recent

 

1. Book : Madan Kaila and Rakhi Kaila, ‘ Quantum magnetic Resonance Imaging Diagnostics Of Human Brain Disorders ‘ Published, 2010, Elesevier, ISBN: 978-0-12-384711-9.

 

I have recently published the following book ‘ Quantum Magnetic Resonance Imaging Diagnostic Of Human Brain Disorders ‘ . It highlights the newly emerging area of ‘ Multi-Quantum Magnetic Resonance Imaging ( QMRI )’. Through this approach it is possible to visualize events happening at micron ( micro meter ) level in space, and in shorter than microsecond time events, happening, in real space and time, in our brain. This I am sure, will be of immense scientific and technical value to the research efforts being pursued world wide. A brief summary about the book is as follows.

 

Quantum Magnetic Resonance Imaging Diagnostics of Human Brain Disorders on ScienceDirect(Opens new window)

                                           

 

 

 

 

 

The fundamental, atomic-dipole-magnet, mediates multi-quantum correlations with its neighbors, far and near, and creates,  a metabolic, neuro-communication etc, instant state, which the MRI, with its clever scientific ingenuity, strives to record, to the minutest details possible.

 

 
 

 

 

 

 

 


The book has a theme, to be able to, educate on a wider community scale, the newly emerging, multi-quantum approach, in the area of magnetic resonance imaging (MRI). It lays down, the basics of  the intermolecular-multiple-quantum-coherence (iMQC), with practical imaging illustrations, to correlate with the basics concepts involved. This  new multi-quantum approach makes it possible, to obtain, high-contrast images, at the molecular level. One can access the book as follows. Title: Title: Quantum Magnetic Resonance Imaging Diagnostics Of Human Brain Disorders; The Publisher: http://elsevier.com; View At: www.sciencedirect.com; ISBN: 978-0-12-384711-9

 

 

Summary of The Book:Chapter 1Biomedical Quantum Computer Pages 1-105 Madan Kaila, Rakhi Kaila Chapter 2 Magnetic Resonance Imaging of the Human Brain Magnetic Resonance Imaging, Pages 107-246 Madan Kaila, Rakhi Kaila. Chapter 3 What Is Multiple-Quantum Coherence? Pages 247-248 Madan Kaila, Rakhi Kaila Magnetic Resonance Imaging Diagnostics of Human Brain Disorders Quantum Magnetic Resonance Imaging Diagnostics of Human Brain Disorders, 2010, Pages 249-503 Madan Kaila, Rakhi Kaila

Chapter 1 Biomedical Quantum Computer: In this chapter a parallel is drawn between conventional ( sequential-one way-signal ) electronic ( desktop ), and the reversible ( simultaneous-parallel signal-acquisition ) quantum computer. Biomedical liquid-state quantum mechanical systems are chosen, as the illustrations, to enable understand the practical operational part, of the quantum computer. The liquid state nuclear magnetic resonance ( LS-NMR) technology, operating at room temperature, is used, to manipulate the coherent states, for quantum computation. In the brain situation, the quantum system, is too complex and disordered, over a wider space. But some order, in quantum coherence, can be found in a micron size region, where time dependent activities, e.g., metabolism, neuro-inhibition cut off switches, etc. can be studied, as a way of quantum computation. In the brain imaging situation, one uses, large volumes ( voxels ) of the size of 1 mm3 to 1 cm3. Here one is dealing, with signals, naturally occurring  ( in relatively poorer coherence ) quantum states. Nevertheless they are good enough to coordinate, in the brain space, to produce an MRI picture, which is routinely used, in the diagnostics of brain disorders. Chapter 2 MRI of Human Brain: This chapter outlines the conventional single quantum coherence (SQC) echo planar imaging (EPI) as the base for the various new emerging techniques of imaging. There are included practical illustrations, from various improvements, in conventional MRI and techniques, including diffusions tensor imaging (DTI), the proton magnetic resonance spectroscopic imaging (PMRSI), etc. Chapter 3 MRI (multi-quantum) Diagnostics of Human Brain Disorders: In this chapter, first an explanatory base, is established, for the matrix mechanics technique, for dealing with the angular-momentum quantum algebra, so intimately connected, with the use of RF ( radio frequency ) pulses, for excitation, rotation, inversion, of the signals, from the energy states, among the macromolecules, in the brain. The routine text book style quantum mechanics ( QM ) treatment is not expanded, in this chapter. Standard text books are available in this subject, written at undergraduate and postgraduate levels. It is the intention in this chapter, to see the application of multi quantum coherence ( MQC ) among the molecules, as the source of imaging. Various practical illustrations from real brain imaging ( MQC ) scenarios are included.    

 

1.       Book,  Madan Kaila and Rakhi Kaila, ‘ Brain Science Through The Eyes Of Quantum Magnetic Resonance Imaging ‘ , submitted for publication

 

2.       Book, Madan Kaila and Rakhi Kaila,‘ Sodium Quantum Magnetic Resonance Imaging Diagnostics Of Human  Brain Tumors ‘, under writing

 

 

Publications ( Sole )

 

1. M. M. Kaila, ' Hot Electron Non Equilibrium High Temperature Superconductor

THz Radiation Sensing and The Integrated Electron Cooling ', Chapter in a Book, published, 2006, Nova Science Publishers, Inc., New York, USA.

2. M. M. Kaila, High Temperature Superconductor THz Thermal Sensors and Coolers,              

 J. Superconductivity :incorporating Novel Magnetism, 2005, 18, pp 427-431. .

4. M M. Kaila, A YBaCuo-BiSb Photo-Thermoelectric Sensor: Mathematical Modeling of

Normalised Detectivity of, Physica C, 2004, 406, pp 205-209.

5. M M. Kaila, Simulated Operational Characteristics of A High-Tc Terahertz(THz) Thermal Sensor,

J. Superconductivity, 2004, 17, pp 339-343.

6. M M. Kaila, Computational Analysis of electron-phonon cooling for a high temperature superconductor terhahertz thermal sensor,

Supercond. Sci. Technol. 2004, 17, pp 140-142.

7.M. M. Kaila, A High Temperature Superconductor (HTSC) Hot Electron ( HE) THz Heterodyne Thermal Sensor (HTS) :

Computational Analysis of Conversion gain in, J. Superconductivity, 2002, 15, pp 185-190.

8. M. M. Kaila, Dynamical Theory of responsivity and response time of a high temperature supercondutcor photo-thermolectrical bolometer,

Physica C 382, 2002, pp 298-302.

9. M. M. Kaila, Theoretical Analysis of  A High Temperature Superconductor ( HTSC ) Hot Electron Far Infrared Bolometer ( HEFIB ),

J. Superconductivity, 2001, 14, pp 569-573..

10. M. M. Kaila, Strain Tuned Electronics in Semiconductors and High Temperature

Superconductors, J. Fiz. Mal., 1995, 16, pp 25-28.

11 M. M. Kaila, Dislocation Strain Electron Transport in Superconductors and Superlattice Semiconductors,  J. Fiz. Mal. 14, 1993, pp 61-64.

12. M. M. Kaila, Dislocations in III-V Crystals, Proceedings Fourth Asia Pacific Physics Conference, August 13-17, 1990, Seoul Korea, pp 491-494.

13. M. M. Kaila, Electron Mobility in Dislocated-Molecular InSb and GaAs  Indian Journal of  Pure and Applied Physics, 1989,27, pp 49-511.

4. M. M. Kaila, Energy Transport Across Solid-Solid Interfaces, Proceedings “7th Miami International Conference  on Alternative Energy Source,

9-11 December 1985, pp 139-142, Miami Florida, U.S.A.

15.. M. M. Kaila, Energy Transport Across Solid-Solid Interfaces in Energy Systems, Proceedings, International Congress on Renewable

Energy Sources, May 18-13, 1986, pp 1305-1316, Madrid.

16. M. M. Kaila, Electronics of Dislocated Semiconductors Proceedings of Regional Conference on Semiconductors  and Physics of Materials,

15-19 June, 1987, pp 26-31, Kuala Lumpur, Malaysia.

17  M. M. Kaila, Effect of Magnetic Field on Electrical Effects of Dislocations in InSb, Physica Status Solidi, (a), 1977, 44, 2, 135.

18. Book/Notes : 1990: M. M. Kaila, Optoelectronic Materials Devices and Applications,

Queensland University of Technology, Brisbane.

 

 

Publications ( Joint )

 

1. M. M. Kaila and G. J. Russell, Theory of Noise Equivalent Power of a High Temperature Superconductor  far-infrared bolometer in a

photo-thermoelectrical mode of operation, J. Phys. D. Appl. Phys. , 2000, 33, pp 3107-3111.

2. M. M. Kaila and G. J. Russell, Static Theory of a self-driven photo-thermoelectrical high-temperature superconductor bolometer,

. of  Superconductivity, 2000, 13, pp 497-502.

3. M. M. Kaila and G. J. Russell, Dynamical Theory of a High Temperature Superconductor Photo-Thermoelctrical Bolometer,

J. Superconductivity, 2000, 13, pp 1025-1030.

4.M. M. Kaila and G. J. Russell, Improved Noise characteristics of a High Temperature Superconductor Far Infrared Bolometer using Photo-Thermolectrical Feedback, COMMAD (Conference on Optoelectronics and Microelectronic Materials and Devices), Dec. 5-8, 2000, La Trobe University, Melbourne, Proceedings IEEE(Pittsway NJ 08855-1331, USA), Proceedings, pp 109-112.

5. M. M. Kaila,  J. Cochrane and G. J. Russell,  A Photo-thermoelectrical YBCO: BiSb Thick Film Bolometer, Journal of Physics: D:

App. Phys. 1998, 31, pp 1987-89.

6. M. M. Kaila, J. Cochrane and G. J. Russell, Photo-Thermal Transport Effects in a Thick Film YBCO Bolometer Under Magnetic Fields,

J. of Superconductivity, 1998, 11, 3, pp 463-469.

7. M. M. Kaila, J, cochrane and G. J. Russell,  Photo Thermal Response Of YBCO-Bi Junctions, COMMAD’96,

Australian National University, Canberra, Dec 96, Proceedings IEEE(Pittsway NJ 08855-1331, USA).  pp 109-112.

8. M. M. Kaila and G. J. Russell, Photo-Thermal Electron Transport in YBCO-Bi Junctions, Supercond. Sc. Technol., 1997, 10, pp 763-65.

9. H. J. Goldsmid, M. M. Kaila  and G. L. Paul,  Thermal Conductivity of Amorphous Silicon Films (JP) Physica Status Solidi (a), 1983, 76, pp K31-33.

10. H. J. Goldsmid, and M. M. Kaila, Heat Flow at Pressed Contacts, Australian Journal of Physics, 1980, 22, pp 745-752.

11. H. J. Goldsmid, J. E. Guitronich and M. M. Kaila ,

Solar Thermoelectric Generation using Bismuth Telluride Alloys (JP) Sol. En., 1980, 24, pp  435-440.

12.   M. M. Kaila, L. B. Harris  and H. J. Goldsmid, Thermoelectric and Thermomagnetic Properties of Plastically Bent InSb samples, Physica Status Solidi (a), 1976, 37, pp K43-46.

13.   M. M. Kaila and H. J. Goldsmid, Thermomagnetic Properties of InSb-In Films (JP),

Physica Status Solidi (a), 1975, 26, pp K167-170.

14. J. R. Drabble, M. M. Kaila and H. J. Goldsmid, Measurement of Hall-Coefficient in Short Specimens Using High Resistance Contacts,

J. Phys., D: Applied Physics, 1975, 6, pp  790-799.

 

Papers Conferences / Meetings / Workshops :

 

1.      M. M. Kaila, Presented paper, A simulation for the Effects of Electron and Phonon Specific Heats on the Performance of a HTSC THz Thermal Sensor, Frontiers of Science and Technology Workshop on Soft Condensed Matter and Nanoscale Physics and Thirteenth Gordon Godfrey Workshop on Condensed Matter Theory, 3-4 Dec.03, Coogee, Sydney.

2. M. M. Kaila, Presented paper, Mathematical Modeling of Conversion Gain in a High Temperature Superconductor ( HTSC ) Far Infrared Thermal Detector Operated at 77K, AIP Physics Industry Day, University of Western Sydney, 26/9/01.

3.   M. M. Kaila and G. J. Russell, Presented paper, Thermoelectrical-Electrothermal Feedback enhanced Performance Characteristics of a High Temperature Superconductor Far Infrared Bolometer, 24th Annual Condensed Matter Physics Meeting, Feb. 1-4, 2000, Wagga Wagga, NSW, Australia.

4. M. M. Kaila and G. J. Russell, Presented paper, Application of the New High Temperature Superconductor Materials to Far Infrared Radiation Detection, New Materials Expo, Australian Technology Park, 16th Nov. 1999, Redfern, Sydney.

 5. M. M. Kaila and G. J. Russell, Presented paper Photo-Thermoelectrical mm Wave Bolometer, 23rd Condensed Matter Physics Meeting, Wagga, NSW, Auatralia,  2-5 Feb, 1999.

6. M. M. Kaila and G. J. Russell Presented paper Computations of Responsivity and Response Time of a YBCO:BiSb bolometer under Resistance and Temperature Noise Limit, Presented 22nd AIP & NZIP Condensed Matter Physics Meeting, Feb. 1998, Waga-Waga, NSW, Australia.

7.  M. M. Kaila and G. J. Russell Presented paper Photo-Thermoelectric Contact-Less YBCO-BiSb Thick Film Bolometer: Design Considerations, 21st AIP & NZIP  Condensed Matter Physics Meeting, 3-5 Feb. 1997, Waga-Waga, NSW, Australia.

8. M. M. Kaila and G. J. Russell, Presented paper Optical-Infrared Sensor System Based on A HTSC Bolometer -presented at Meeting on Optical Guided Waves and Devices as well as Novel Applications in Optical Sensing”, Australian National University, 8-11 July, 1997, Canberra.

9. M. M. Kaila and G. J. Russell, Presented paper Optical and Thermal Response of YBCO-Bismuth Junctions’ COMMAD’ (Conference on Optoelectronics and Microelectronic Materials’ and Devices) 96,   ANU, Canberra, 8-11, Dec. 1996.

10. M. M. Kaila Presented paper ‘Thermal Resistance - Electron Phonon Interactions and High Temperature Superconductivity, Workshop on High Temperature superconductivity, October 10-20,1994, National Centre for Theoretical Physics, The Australian National University, Canberra.

 

EXTENDED CV

 

Resume of Madan M. Kaila(Australian National)

Contact : Home:Ph/Fxa:61-2-9750073, 6/22, Moreton Street, Lakemba,                                                              Work : Ph : 61-2-9385-4561, Fax : 61-2-93856060, School of Physics,                                                         University of New South Wales(UNSW), Sydney 2052, Australia,                                                                Email : m.kaila@unsw.edu.au

 

Expertise : Research And Development, Experimental and Mathemtical Modeling, and Teaching/Supervision/Management/Developing Educational Material, In Hard And Soft Condensed Matter /Science/Brain science

 

Computer Skills : Mathematical/Computational Modeling/Use of ‘Mathematica Computational Commercial Package ’ in Science Modeling Research. Use of Microsoft Word/Excel/Corel Draw/PhotoShop in Preparation and Publication of Research Papers/Reports/Books.

 

Career Goal : To accept new challenges in research, advancement and education and excel as Scientist/Researcher/Teacher/Educationist/Consultant/Technologist/Manager.

 

Education/Qualifications:  Ph.D(Condensed Matter Physics) 1977 University Of NSW, Sydney 2052, MSc(Nuclear Physics) 1964, B.Sc.Hons(Physics) 1962 (Delhi), Computer Software Certificate 1993, Management Certificate 1993, South Brisbane TAFE college. Instructional Skills Certificate 1994, Mt. Gravatt TAFE College.

 

Work Experience :  1995 – to date

Honorary/Visiting Fellow(Full Time):School of Physics, University of New South

Wales(UNSW), Sydney 2052, Australia

 

Present: ( 2004- to date ): Soft Condensed Matter Science/Biophysics

Research in the area of Brain Science, Modeling in Quantum Information Science and MRI; MQMRI ( multi-quantum magnetic Resonance Imaging ) in Human Brain, writing educational material/books in the area of ‘Quantum MRI and the Diagnostics of Human Brain Disorders

 

Earlier: ( 1995 – 2003 ): Modeling, Designing, Constructing, Testing, High Temperature Superconductor/Semiconductor Materials/Devices, Teaching First Year Physics Courses/Supervise Student Research/Learning projects

July1995-July-96: Senior Scientist/Consultant: ResMed Pty Ltd, Sydney. Installation and use of Acoustics/Noise Analysis laboratory, in nose analysis of sleep apnea machine.

Feb. 1994-Feb. 95: Visiting Fellow: Griffith University, Brisbane, Research and Teaching.                        

Feb. 1990- Feb. 93: Lecturer: Queensland University of Technology, Brisbane. Teaching undergraduate physics course in medical physics, health science and optometry degree programs. Providing subjects/courses coordination and leadership. Supervision of MSc., Ph.D. research in optoelectronics infrared detectors and devices. Awarded ARC/QUT/Small Seeding Grants for an ‘Infrared Radiation Detection/Imaging’ project.                                             

Feb. 1989- Feb. 90: Tutor: UNSW: Teaching and, Research: High Temperature Superconductor       ( HTSC ) Materials and Devices/Thermal Sensors

Feb 1982- Feb 1989 : Sr Lecturer/Lecturer: PNG university of technology. Lae,

Teaching- 1st. - 3rd year physics courses. Postgraduate Courses - in Statistical Mechanics, Quantum Mechanics, Applied Mathematics, Solid-state Physics courses. Research  in:-Heat Transfer (electron-phonon):solid-solid Interfaces, dislocated materials, preparing research grants applications, awarded grants for Acoustic-Resonance Non-Destructive Analysis/Testing.

1981--82 : Visiting Fellow, Australian National University.

1980-81 : Examiner of Patents, Patent Office Canberra.

1979-81: Post Doctoral Research Associate: University of New South Wales.

Research in (a) Solar Energy: Thermo-Electric Generator: (i) Design and construction (ii) Measurement of its solar characteristics. (b) Heat Transfer Across Pressed Contacts (1) Developed and constructed measurement equipment, (2) Theoretical/Computational Modeling of heat flow, (3) Study of thermo-physical properties of thin (Silicon) films,

1977- 79: Research Officer/Fellow: Low Temperature Superconductors, Delhi University.

1972- 77 : Ph.D. Research Scholar: University of New South Wales, Sydney.
Research in Thermoelectric and Thermo-magnetic properties of Strained InSb and Two Phase (InSb-In) Films. (I) Design and construction of high vacuum systems.                                  (ii) Design and construction of liquid nitrogen cryostat. (iii) Setting up of plastic deformation apparatus. (iv) Setting up of electrical measuring apparatus. (v) Measurement of electronic, thermoelectric / thermo - galvanomagnetic properties of plastically deformed InSb crystals and InSb-In films. (vi) Analysis of data, development of theoretical model of electronics of deformed materials. (vii) Writing and submission of doctoral thesis. Theory Courses: (I) Group theory and applications to solid state physics.(ii) Transport of electrons in solids. (iii) Crystals, imperfections and surfaces. (iv) Advanced quantum mechanics. PhD Thesis Title: Thermoelectric and Thermomagnetic Properties of Strained InSb  and InSb-In.
1966-72: Scientific Officer: Solid State Physics laboratory, Delhi.                                                   
Research in Semiconductor Materials/Devices, Mass-Spectrometer(installation/Commissioning )
 

REFERENCES:

 

Present:  Professor Richard Newbury, Head of School, School of Physics,

UNSW, Sydney 2052, Australia, Ph: 6129385-4557/5329/4553.

FAX: 61293856060, email: r.newbury@unsw.edu.au.

Previous:

2 Emeritus Professor H. J. Goldsmid, University of NSW, Honorary Associate,

University of Tasmania, 40 Osborne Esplande, Kingston Beach, Hobart, Tasmania, 7050, Australia,

Ph:  61-3-62291776, FAX: 61-3-62291828, email: hjgoldsmid@phys.unsw.edu.au.

3 Dr. J. W. Cochrane, Professional/Technical Officer, School Of Physics University of New South Wales, Sydney 2052, Australia,

Ph: 61-2-9385-5329/4555/4561(W), 61-2-42684098(H), FAX: 61-2-93856060, email: j.cochrane@unsw.edu.au.

 

Publications :

 

*Books

1. Dr M. M. Kaila and Rakhi Kaila,  ' Quantum Magnetic Resonance Imaging

Diagnostics Of Human Brain Disorders’ 2010,

Elsevier, published, http://www.elsevier.com, ISBN: 978-0-12-384711-9.

2.  ‘ Brain Science Through The Eyes of Quantum magnetic Resonance Imaging ‘,

under writing.

3. ‘Sodium Quantum Magnetic Resonance Imaging Diagnostics of Human Brain disorders,

under writing.

4. M. M. Kaila, ' Hot Electron Non Equilibrium High Temperature Superconductor

THz Radiation Sensing and The Integrated Electron Cooling ', Chapter in a Book, “New Topics In Superconductivity Research’, ISBN 1-59454-985-0, 2006, Nova Science Publishers, Inc., New York, USA.

 

Research Papers ( Sole Author )

 

1. M. M. Kaila, High Temperature Superconductor THz Thermal Sensors and Coolers,              

 J. Superconductivity :incorporating Novel Magnetism, 2005, 18, 427-431..

2. M M. Kaila, A YBaCuo-BiSb Photo-Thermoelectric Sensor: Mathematical Modeling of

Normalised Detectivity of, Physica C, 2004, 406, pp 205-209.

3. M M. Kaila, Simulated Operational Characteristics of A High-Tc Terahertz(THz) Thermal Sensor,

J. Superconductivity, 2004, 17, pp 339-343.

4. M M. Kaila, Computational Analysis of electron-phonon cooling for a high temperature

superconductor terhahertz thermal sensor,

Supercond. Sci. Technol. 2004, 17, pp 140-142.

5.M. M. Kaila, A High Temperature Superconductor (HTSC) Hot Electron ( HE) THz

Heterodyne Thermal Sensor (HTS) : Computational Analysis of Conversion gain in,

J. Superconductivity, 2002, 15, pp 185-190.

6. M. M. Kaila, Dynamical Theory of responsivity and response time of a high temperature superconductor photo-thermolectrical bolometer,

Physica C 382, 2002, pp 298-302.

7. M. M. Kaila, Theoretical Analysis of  A High Temperature Superconductor ( HTSC ) Hot Electron Far Infrared Bolometer ( HEFIB ),

J. Superconductivity, 2001, 14, pp 569-573..

8. M. M. Kaila, Strain Tuned Electronics in Semiconductors and High Temperature

Superconductors, J. Fiz. Mal., 1995, 16, pp 25-28.

9. M. M. Kaila, Dislocation Strain Electron Transport in Superconductors and Superlattice Semiconductors,  J. Fiz. Mal. 14, 1993, pp 61-64.

10. M. M. Kaila, Dislocations in III-V Crystals, Proceedings Fourth Asia Pacific Physics Conference, August 13-17, 1990, Seoul Korea, pp 491-494.

11. M. M. Kaila, Electron Mobility in Dislocated-Molecular InSb and GaAs  Indian Journal of  Pure and Applied Physics, 1989,27, pp 49-51.

12. M. M. Kaila, Energy Transport Across Solid-Solid Interfaces, Proceedings “7th Miami International Conference  on Alternative Energy Source, 9-11 December 1985, pp 139-142, Miami Florida, U.S.A.

13.. M. M. Kaila, Energy Transport Across Solid-Solid Interfaces in Energy Systems, Proceedings, International Congress on Renewable Energy Sources, May 18-13, 1986, pp 1305-1316, Madrid. 14. M. M. Kaila, Electronics of Dislocated Semiconductors Proceedings of Regional Conference on Semiconductors  and Physics of Materials, 15-19 June, 1987, pp 26-31, Kuala Lumpur, Malaysia.

15.  M. M. Kaila, Effect of Magnetic Field on Electrical Effects of Dislocations in InSb, Physica Status Solidi, (a), 1977, 44, 2, 135.

Book/Notes : 1990: M. M. Kaila, Optoelectronic Materials Devices and Applications,

Queensland University of Technology, Brisbane.

 

 

 

Research Papers ( Joint Author )

 

1. M. M. Kaila and G. J. Russell, Theory of Noise Equivalent Power of a High Temperature Superconductor  far-infrared bolometer in a

photo-thermoelectrical mode of operation, J. Phys. D. Appl. Phys. , 2000, 33, pp 3107-3111.

2. M. M. Kaila and G. J. Russell, Static Theory of a self-driven photo-thermoelectrical high-temperature superconductor bolometer,

J. of  Superconductivity, 2000, 13, pp 497-502. 3. M. M. Kaila and G. J. Russell, Dynamical Theory of a High Temperature Superconductor Photo-Thermoelctrical Bolometer, J. Superconductivity, 2000, 13, pp 1025-1030.

3.M. M. Kaila and G. J. Russell, Improved Noise characteristics of a High Temperature Superconductor Far Infrared Bolometer using

Photo-Thermolectrical Feedback, COMMAD (Conference on Optoelectronics and Microelectronic Materials and Devices), Dec. 5-8, 2000,

La Trobe University, Melbourne, Proceedings IEEE(Pittsway NJ 08855-1331, USA), Proceedings, pp 109-112.

4. M. M. Kaila and G. J. Russell,  A Photo-thermoelectrical YBCO: BiSb Thick Film Bolometer, Journal of Physics: D: App. Phys. 1998, 31, pp 1987-89.

5. M. M. Kaila and G. J. Russell, Photo-Thermal Transport Effects in a Thick Film YBCO Bolometer Under Magnetic Fields,

J. of Superconductivity, 1998, 11, 3, pp 463-69.

6. M. M. Kaila and G. J. Russell,  Photo Thermal Response Of YBCO-Bi Junctions, COMMAD’96, Australian National University, Canberra, Dec 96, Proceedings IEEE(Pittsway NJ 08855-1331, USA).  pp 109-112.

7. M. M. Kaila and G. J. Russell, Photo-Thermal Electron Transport in YBCO-Bi Junctions, Supercond. Sc. Technol., 1997, 10, pp 763-65.

8. H. J. Goldsmid, M. M. Kaila  and G. L. Paul,  Thermal Conductivity of Amorphous Silicon Films (JP) Physica Status Solidi (a), 1983, 76, pp K31-33.

9. H. J. Goldsmid, and M. M. Kaila, Heat Flow at Pressed Contacts, Australian Journal of Physics, 1980, 22, pp 745-752.

10. H. J. Goldsmid, J. E. Guitronich and M. M. Kaila ,

Solar Thermoelectric Generation using Bismuth Telluride Alloys (JP) Sol. En., 1980, 24, pp  435-440. 12. 11. M. M. Kaila, L. B. Harris  and

H. J. Goldsmid, Thermoelectric and Thermomagnetic Properties of Plastically Bent InSb samples, Physica Status Solidi (a), 1976, 37, pp K43-46.

12. M. M. Kaila and H. J. Goldsmid, Thermomagnetic Properties of InSb-In Films (JP),

Physica Status Solidi (a), 1975, 26, pp K167-170.

13. J. R. Drabble, M. M. Kaila and H. J. Goldsmid, Measurement of Hall-Coefficient in Short Specimens Using High Resistance Contacts,

J. Phys., D: Applied Physics, 1975, 8, pp  790-799.

 


Papers Conferences / Meetings / Workshops :

 

1. M. M. Kaila, Presented paper, A simulation for the Effects of Electron and Phonon Specific Heats on the Performance of a HTSC THz Thermal Sensor, Frontiers of Science and Technology Workshop on Soft Condensed Matter and Nanoscale Physics and Thirteenth Gordon Godfrey Workshop on Condensed Matter Theory, 3-4 Dec.03, Coogee, Sydney.

2. M. M. Kaila, (sa), Presented paper, Mathematical Modeling of Conversion Gain in a High Temperature Superconductor ( HTSC ) Far Infrared Thermal Detector Operated at 77K, AIP Physics Industry Day, University of Western Sydney, 26/9/01.

3.   M. M. Kaila and G. J. Russell,  (ja) Presented paper, Thermoelectrical-Electrothermal Feedback enhanced Performance Characteristics of a High

Temperature Superconductor Far Infrared Bolometer, 24th Annual Condensed Matter Physics Meeting, Feb. 1-4, 2000, Wagga Wagga, NSW, Australia.

4. M. M. Kaila and G. J. Russell, Presented paper, Application of the New High

Temperature Superconductor Materials to Far Infrared

5. M. M. Kaila and G. J. Russell, Presented paper Photo-Thermoelectrical mm Wave

Bolometer, 23rd Condensed Matter Physics Meeting,

Wagga, NSW, Auatralia,  2-5 Feb, 1999.

6. M. M. Kaila and G. J. Russell Presented paper Computations of Responsivity and Response Time of a YBCO:BiSb bolometer under Resistance and Temperature Noise Limit, Presented

22nd AIP & NZIP Condensed Matter Physics Meeting, Feb. 1998, Waga-Waga, NSW, Australia.

7.  M. M. Kayla and G. J. Russell Presented paper Photo-Thermoelectric Contact-Less YBCO-BiSb Thick Film Bolometer: Design Considerations, 21st AIP & NZIP  Condensed Matter Physics Meeting, 3-5 Feb. 1997, Waga-Waga, NSW, Australia.

8. M. M. Kaila and G. J. Russell,  Presented paper Optical-Infrared Sensor System Based

on A HTSC Bolometer -presented at Meeting on Optical Guided Waves and Devices as well as Novel Applications in Optical Sensing”, Australian National University, 8-11 July, 1997, Canberra.

9. M. M. Kaila and G. J. Russell, Presented paper Optical and Thermal Response of YBCO-Bismuth Junctions’ COMMAD’ (Conference on Optoelectronics and Microelectronic

Materials’ and Devices) 96,   ANU, Canberra, 8-11, Dec. 1996.

10. M. M. Kaila Presented paper ‘Thermal Resistance - Electron Phonon Interactions

and High Temperature Superconductivity, Workshop on High Temperature Superconductivity, October 10-20,1994, National Centre for Theoretical Physics, The Australian National University, Canberra, Australia.