John Collins

Distinguished Professor Emeritus of Physics

John Collins

Research Summary

Algorithms of neural computation for learning and memory; relationship between neuronal and behavioral phenomena.

Huck Affiliations

Links

Publication Tags

Transverse Momentum Factorization Neurons Partons Inelastic Scattering Formalism Kinematics Theorems Neuron Population Temporal Lobe Fragmentation Lobes Memory Population Model Hadrons Hippocampus Cell Stimuli Cells Physics Distribution Functions Direction Compound Concepts Model

Most Recent Publications

`Do fragmentation functions in factorization theorems correctly treat non-perturbative effects?

John Collins, on p. 003 (10 pages)

TMD Evolution at Moderate Hard Scales

Ted Rogers, John Collins, PoS on p. 028

Kinematics of current region fragmentation in semi-inclusive deeply inelastic scattering

M. Boglione, J. Collins, L. Gamberg, J. O. Gonzalez-Hernandez, T. C. Rogers, N. Sato, 2017, Physics Letters, Section B: Nuclear, Elementary Particle and High-Energy Physics on p. 245-253

Relating transverse-momentum-dependent and collinear factorization theorems in a generalized formalism

J. Collins, L. Gamberg, A. Prokudin, T. C. Rogers, N. Sato, B. Wang, 2016, Physical Review D

Memory for a single object has differently variable precisions for relevant and irrelevant features

Garrett Swan, John Collins, Brad Wyble, 2016, Journal of Vision

Two-population model for medial temporal lobe neurons: The vast majority are almost silent

Andrew Magyar, John Collins, 2015, Physical Review E

Understanding the large-distance behavior of transverse-momentum-dependent parton densities and the Collins-Soper evolution kernel

John Collins, Ted Rogers, 2015, Physical Review D

Overview of TMD Factorization and Evolution

John Collins, 2015, Int. J. Mod. Phys. Conf. Ser. on p. 1560021

Different approaches to TMD Evolution with scale

John Collins, 2015, on p. 01002

TMD factorization and evolution at large b_T

John Collins, Ted Rogers, 2015,

Most-Cited Papers

A large hadron electron collider at CERN

J. L. Abelleira Fernandez, C. Adolphsen, A. N. Akay, H. Aksakal, J. L. Albacete, S. Alekhin, P. Allport, V. Andreev, R. B. Appleby, E. Arikan, N. Armesto, G. Azuelos, M. Bai, D. Barber, J. Bartels, O. Behnke, J. Behr, A. S. Belyaev, I. Ben-Zvi, N. Bernard, S. Bertolucci, S. Bettoni, S. Biswal, J. Blümlein, H. Böttcher, A. Bogacz, C. Bracco, G. Brandt, H. Braun, S. Brodsky, O. Brüning, E. Bulyak, A. Buniatyan, H. Burkhardt, I. T. Cakir, O. Cakir, R. Calaga, V. Cetinkaya, E. Ciapala, R. Ciftci, A. K. Ciftci, B. A. Cole, J. C. Collins, O. Dadoun, J. Dainton, A. De. Roeck, D. D'Enterria, A. Dudarev, A. Eide, R. Enberg, E. Eroglu, K. J. Eskola, L. Favart, M. Fitterer, S. Forte, A. Gaddi, P. Gambino, H. García Morales, T. Gehrmann, P. Gladkikh, C. Glasman, R. Godbole, B. Goddard, T. Greenshaw, A. Guffanti, V. Guzey, C. Gwenlan, T. Han, Y. Hao, F. Haug, W. Herr, A. Hervé, B. J. Holzer, M. Ishitsuka, M. Jacquet, B. Jeanneret, J. M. Jimenez, J. M. Jowett, H. Jung, H. Karadeniz, D. Kayran, A. Kilic, K. Kimura, M. Klein, U. Klein, T. Kluge, F. Kocak, M. Korostelev, A. Kosmicki, P. Kostka, H. Kowalski, G. Kramer, D. Kuchler, M. Kuze, T. Lappi, P. Laycock, E. Levichev, S. Levonian, V. N. Litvinenko, A. Lombardi, J. Maeda, C. Marquet, B. Mellado, K. H. Mess, A. Milanese, S. Moch, I. I. Morozov, Y. Muttoni, S. Myers, S. Nandi, Z. Nergiz, P. R. Newman, T. Omori, J. Osborne, E. Paoloni, Y. Papaphilippou, C. Pascaud, H. Paukkunen, E. Perez, T. Pieloni, E. Pilicer, B. Pire, R. Placakyte, A. Polini, V. Ptitsyn, Y. Pupkov, V. Radescu, S. Raychaudhuri, L. Rinolfi, R. Rohini, J. Rojo, S. Russenschuck, M. Sahin, C. A. Salgado, K. Sampei, R. Sassot, E. Sauvan, U. Schneekloth, T. Schörner-Sadenius, D. Schulte, A. Senol, A. Seryi, P. Sievers, A. N. Skrinsky, W. Smith, H. Spiesberger, A. M. Stasto, M. Strikman, M. Sullivan, S. Sultansoy, Y. P. Sun, B. Surrow, L. Szymanowski, P. Taels, I. Tapan, T. Tasci, E. Tassi, H. Ten. Kate, J. Terron, H. Thiesen, L. Thompson, K. Tokushuku, R. Tomás García, D. Tommasini, D. Trbojevic, N. Tsoupas, J. Tuckmantel, S. Turkoz, T. N. Trinh, K. Tywoniuk, G. Unel, J. Urakawa, P. Van Mechelen, A. Variola, R. Veness, A. Vivoli, P. Vobly, J. Wagner, R. Wallny, S. Wallon, G. Watt, C. Weiss, U. A. Wiedemann, U. Wienands, F. Willeke, B. W. Xiao, V. Yakimenko, A. F. Zarnecki, Z. Zhang, F. Zimmermann, R. Zlebcik, F. Zomer, 2012, Journal of Physics G: Nuclear and Particle Physics

Understanding the large-distance behavior of transverse-momentum-dependent parton densities and the Collins-Soper evolution kernel

John Collins, Ted Rogers, 2015, Physical Review D

Relating transverse-momentum-dependent and collinear factorization theorems in a generalized formalism

J. Collins, L. Gamberg, A. Prokudin, T. C. Rogers, N. Sato, B. Wang, 2016, Physical Review D

Equality of two definitions for transverse momentum dependent parton distribution functions

John Collins, Ted Rogers, 2013, Physical Review D

Kinematics of current region fragmentation in semi-inclusive deeply inelastic scattering

M. Boglione, J. Collins, L. Gamberg, J. O. Gonzalez-Hernandez, T. C. Rogers, N. Sato, 2017, Physics Letters, Section B: Nuclear, Elementary Particle and High-Energy Physics on p. 245-253

Memory for a single object has differently variable precisions for relevant and irrelevant features

Garrett Swan, John Collins, Brad Wyble, 2016, Journal of Vision

Two-population model for medial temporal lobe neurons: The vast majority are almost silent

Andrew Magyar, John Collins, 2015, Physical Review E

TMD factorization and evolution at large b_T

John Collins, Ted Rogers, 2015,

Overview of TMD Factorization and Evolution

John Collins, 2015, Int. J. Mod. Phys. Conf. Ser. on p. 1560021

Different approaches to TMD Evolution with scale

John Collins, 2015, on p. 01002