DEPARTMENT.FACULTY

photo
Dr. Sudhir Kumar Gupta
DEPARTMENT_STAFF.COMPLETE_CV
DEPARTMENT_STAFF.PROFILE
ABOUT

Dr. Sudhir Kumar Gupta is an Assistant Professor in the Department of Physics with a specialization in Theoretical High Energy Physics. He completed his doctoral studies at the Harish-Chandra Research Institute, Allahabad, India in year 2008. Before moving to the Aligarh Muslim University he worked at the Tata Institute of Fundamental Research (2008), Mumbai, India, Iowa State University, Ames, IA, USA (2008-2011), and, Australian Research Council's Centre of Excellence for Particle Physics, Monash University, Melbourne, Australia (2011-14) as a Postdoctoral Research Fellow.

RESEARCH 

Dr. Gupta's current research interests include Supersymmetry , CP-violation, Heavy-Flavor Physics, particle cosmology and Quantum Field Theory. His published research could be accessed via the web-link "Research Articles".

Research Grants: One 

Student's Supervision/Mentoring: 

1. Doctoral: 02 (Completed = 00, Ongoing =02)
2. Postgraduate: 13 (Completed = 13, Ongoing = 00)

3.Undergraduate: 14 (Completed: 10, Ongoing =04)

TEACHING

Ongoing 

1. Statistical Physics (PHM3002): 2022-23

2. Computational Physics (PHB5P3): 2022-23

Undergraduate

1. Mechanics (PHB152): 2015-16, 2016-17

2. Electricity and Magnetism (PHB252): 2015-16, 2016-17, 2020-21, 21-22

3. Optics (PHB351): 2015-16

4. Thermal Physics (PHB452): 2016-2017, 2017-2018, 2018-2019

5. Classical Mechanics (PHB6002?): (2016-17, 2017-18)

6. Classical Mechanics and Electromagnetic Theory (PHB651): 2018-2019, 2019-20, 2020-21, 2021-22)

7. Nuclear and Particle Physics/Particle and Astrophysics: 2010-2011@Monsh U[Shared]

8. Computational Physics (PHB5P3, PHB6P3): 2015-16, 2016-17, 2017-18, 2018-19, 2019-20, 2020-21, 2021-22 


Postgraduate
1.
Classical Mechanics (PHM1002): 2017-18, 2018-19, 2019-20, 2020-21, 2021-22
2. 
Astrophysics (PHM2005): 2020-21, 2021-22
3. 
Statistical Physics (PHM3002): 2017-18, 2018-19, 2019-20, 2020-21, 2021-22
4. Programming and Computational Physics (PHM3031): 2016-17, 2017-18
5. 
Atomic and Molecular Physics: 2014-15 @CURAJ[Shared]

6. Computational Physics (PHM2072): 2015-16, 2016-17, 2017-18, 2018-19, 2019-20, 2020-21, 2021-22)

Doctoral
1. Research and Methodology (Paper - I): 2016-17, 2017-18, 2018-19, 2019-20, 2020-21, 2021-22 [shared]

Others 
@AMU's RCA, for UGC-CSIR NET (Physical Sciences)/JEST/GATE aspirants 2016
Classical Mechanics - A new Approach (Spring'16): This course involved lots of innovations all over the lectures. The most interesting features of these set of lectures were that the whole course was built only on a single "classical system: The Block". The other interesting features range from problem creation, solving and relating it with the known systems which are generally taught during the standard classroom teaching. With active engagements from the side of students, efficiency and effectiveness, the experiment was a big success as now they should be able to analyze the unknown problems of physics from scratch and should be able to investigate these in depth. Through this course they were also demonstrated on how to have a 'wide-angle view in a given perspective' and how to harness it towards developing a practical sense of the 'physics language'.
Quantum Mechanics - This was also a problem oriented courses specifically designed for competitive programs. 

  1. The anomalous Wtb vertex and top-pair production at the LHC

    Apurba Tiwari, Sudhir Kumar Gupta , 
    Nucl.Phys.B     982 (2022)     115898

  2. Investigating non-minimal flavour-violating CMSSM in the light of Higgs-Boson mass using information theory

     
    Surabhi Gupta, Sudhir Kumar Gupta
    • Nucl.Phys.B 984 (2022) 115942

  3. Higgs information in Split-SUSY at the LHC
  4. t tbar H Interactions and T-odd Correlations at Hadron Colliders
  5. T-odd anomalous interactions of the top-quark at the Large Hadron Collider

    Apurba Tiwari, Sudhir Kumar Gupta, Advances in High Energy Physics, 2021, 
    6676930. 

  6. An Information Theoretic Exploration of Constrained MSSM

    Surabhi Gupta, Sudhir Kumar Gupta, Nucl. Phys. B., 965 (115336), 2021

  7. R-parity violation in split supersymmetry
    Sudhir Kumar Gupta, Partha Konar, Biswarup Mukhopadhyaya
  8. Distinguishing the Littlest Higgs model with T-parity from supersymmetry at the LHC using trileptons

    AseshKrishna Datta, Paramita Dey, Sudhir Kumar Gupta, Biswarup Mukhopadhyaya, Andreas Nyffeler,  Phys. Lett. B 659 (2008) 308-315.

  9. Distinguishing split supersymmetry in Higgs signals at the CERN Large Hadron Collider
    Sudhir Kumar Gupta, Biswarup Mukhopadhyaya, Santosh Kumar Rai, Phys. Rev. D 73, 075006.
  10. Probing Randall-Sundram Model using triphotons at the LHC

    David Atwood, Sudhir Kumar Gupta, ArXiv:1006.4370 [hep-ph].

  11. Detecting Fourth Generation Quarks at Hadron Colliders

    David Atwood, Sudhir Kumar Gupta, Amarjit Soni, JHEP 1206 (2012) 105.

  12. Same sign top-pairs in a non-universal Z' model at the LHC

    Sudhir Kumar Gupta, ArXiv:1011.4960 [hep-ph].

  13. Right sneutrinos and signals of a stable stop at the CERN Large Hadron Collider
    Debajyoti Choudhury, Sudhir Kumar Gupta, Biswarup Mukhopadhyaya, Phys. Rev. D78 (2008) 015023.

  14. Right-Chiral Sneutrino LSP in mSUGRA: Event characteristics of NLSP at the LHC

    Sudhir Kumar Gupta, Biswarup Mukhopadhyaya, Santosh Kumar Rai, SUSY07 proceedings
     
     
    [arXiv:0710.2508 [hep-ph]].

  15. Constraining the flavor changing Higgs couplings to the top-quark at the LHC

     David Atwood, Sudhir Kumar Gupta, Amarjit Soni, JHEP 1410 (2014) 57.

  16. CP violating anomalous couplings in $W\gamma$ and $Z\gamma$ production at the LHC

    Sally Dawson, Sudhir Kumar Gupta, German Valencia, Phys. Rev. D 88 (2013) 3, 035008.

  17. Same-sign Tops: A Powerful Diagnostic Test for Models of New Physics

    David Atwood, Sudhir Kumar Gupta, Amarjit Soni, JHEP 1304 (2013) 035.

  18. Peccei-Quinn violating minimal supergravity and a 126 GeV Higgs boson

    Csaba Balázs, Sudhir Kumar Gupta, Phys. Rev. D 87 (2013) 3, 035023.

  19. Tau lepton charge asymmetry and new physics at the LHC
  20. Flavor changing Z' couplings at the LHC

    Sudhir Kumar Gupta, G. Valencia, Phys. Rev. D 82 (2010) 035017.

  21. CP-odd correlations using jet momenta from $t\bar{t}$ events at the Tevatron

    Sudhir Kumar Gupta, G. Valencia, Phys. Rev. D 81 (2010) 034013.

  22. Distinguishing between SUSY and Littlest Higgs Model using trileptons at the LHC
  23. CP violating anomalous top-quark couplings at the Large Hadron Collider
  24. CP violating anomalous top-quark couplings at the LHC

    Sudhir Kumar Gupta, Alaettin Serhan Mete, G. Valencia, Phys. Rev. D 80 (2009) 034013.

  25. Axion, axino and neutralino dark matter in minimal supergravity
    Csaba Balazs, Sudhir Kumar Gupta, Deutsches Elektronen-Synchrotron, DESY, Notkestrasse 85, 22607, Hamburg, Germany, ISBN/ISSN:978-3-935702-83-6, 4.


  26. B(s) ---> mu+ mu- decay in the R-parity violating minimal supergravity

     Ashutosh Kumar Alok, Sudhir Kumar Gupta, Eur. Phys. J. C 65 (2010) 491-500.

  27. The Impossibility of heavy neutrino dark matter in the Littlest Higgs Model with T-parity: Constraints from direct search

    Paramita Dey, Sudhir Kumar Gupta, Biswarup Mukhopadhyaya, Phys. Lett. B 674 (2009) 188-191.

  28. Right-chiral sneutrinos and long-lived staus: Event characteristics at the large hadron collider

    Sudhir Kumar Gupta, Biswarup Mukhopadhyaya, Santosh Kumar Rai, Phys. Rev. D 75, 075007.

LISTDownloadUPLOADED DATE
MSc Classical Mechanics Chaos and Perturbation Theory
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MSc Classical Mechanics Hamilton-Jacobi Theory
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MSC Classical Mechanics Rigid Body Motion Part 2
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MSC Classical Mechanics Rigid Body Motion
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Lecture Notes on Fortran77
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Statistical Physics PHM3002 U2M4-PART-1
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Statistical Physics PHM3002 U2M4-PART-2
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Statistical Physics PHM3002 U2M5
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Statistical Physics PHM3002 U3M2
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Statistical Physics PHM3002 U3M3
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Statistical Physics PHM3002 U3M4
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Statistical Physics PHM3002 U4M1&2
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Statistical Physics PHM3002 U4M3
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Statistical Physics PHM3002 U4M4
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MSc Classical Mechanics Small Oscillations
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Electricity and Magnetism Unit 1 Part 1
11/10/2021
Electricity and Magentism Unit 1 Part 2
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Electricity and Magnetism Unit 4 Part 1
11/10/2021
Electricity and Magnetism Unit 4 Part 2
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Electricity and Magnetism Unit 4 Part 3
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Astrophysics Unit 1 Part 1
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Astrophysics Unit 1 Part 2
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Astrophysics Unit 2 Part 1
11/10/2021
Astrophysics Unit 2 Part 2
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Astrophysics Unit 3 Part 1
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Astrophysics Unit 3 Part 2
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Astrophysics Unit 4
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C++ Basics
19/05/2022
Discussion Schedule and Book info for BSC Hons Physics (Semester V) Classical Mechanics students of Class 2016
29/09/2016
BSc Hons. Physics (5th Semester) Classical Mechanics Assignment Set 1
08/09/2016
Discussion Schedule and Book info for MSC Physics (Semester III) Programming and Computational Physics - A (PCP-A) students
20/08/2016
Revised schedule and Other details for the B.Sc. S1 Mechanics Class [for Physics Hons. (with Maths and Stats.) and Maths Hons. (with Physics and Stats.) only]
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Study material for the BSc Hons course on Classical Mechanics and Electromagnetic Theory Units 1 and 2
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Some Problems on Thermal Physics for BSc Semester IV (Physics)
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Classical Mechanics and Electromagnetic Theory (PHB 6002) Problem Set 1, due date 20 April 2020.
13/04/2020
Classical Mechanics and Electromagnetic Theory (PHB 6002) Problem Set 2, due date 27 April 2020.
13/04/2020
  • CMET 3.1.2 - EM Potentials and Gauge Transformations
  • CMET 3.1.1 - Maxwell's Equations
  • CMET 3.1.6 - The Maxwell's Stress Tensor
  • CMET 3.1.5 - Poynting Vector for Complex Fields
  • CMET 3.1.4 - Poynting Theorem
  • CMET 3.1.3 - EM Potentials and Gauge Transformations
  • CMET 3.2.1 - Plane EM wave in Non-Conducting Media
  • CMET 3.2.2 - Plane EM wave in Conducting Media
  • CMET 3.2.3 - The Skin effect of a Conductor
  • CMET 3.3.1 - Reflection and Transmission (Normal Incidence)
  • CMET 3.3.2 - Reflection and Transmission (Oblique Incidence) & Fresnel Equations
  • CMET 3.3.3 - Reflection and Transmission (Oblique Incidence) & Fresnel Equations
  • CMET 3.3.4 - Total Internal Reflection (TIR)
  • CMET 3.3.5 - Reflection from a Metallic Surface
  • CMET 3.4.1 - Conductivity of Metals, Drift Velocity
  • CMET 3.4.2 - Propagation of EM wave in Plasma/Earth's Ionosphere
  • CMET 4.1.1 - Parellel Plane Conducting Waveguide
  • CMET 4.2.1 - Hollow Pipe Waveguide
  • CMET 4.2.2 - Hollow Pipe Waveguide
  • CMET 4.2.3 - Hollow Pipe Waveguide
  • CMET 4.3.1 - Rectangular Waveguide
  • CMET 4.4.1 - Optical Fibers
  • CMET 4.4.2 - Optical Fibers
  • STATPHY 1.1.1 - Introduction
  • BSc Experiment Demonstration - Poisson Ratio of Rubber Tube
  • BSc Experiment Demonstration - J by Callender and Barnes Method
  • BSc Experiment Demonstration - Magnetometer
  • CMET 2.4.5 - Scattering Theory
  • CMET 2.4.4 - Scattering Theory
  • CMET 2.4.3 - Scattering Theory
  • CMET 2.4.2 - Scattering Theory
  • CMET 2.4.1 - Scattering Theory
  • CMET 2.3.3 - Central Force Motion
  • CMET 2.3.2 - Central Force Motion
  • CMET 2.3.1 - Central Force Motion