Publications of A. W. Hood

A list of publications authored or co-authored by A. W. Hood, derived from the SAO/NASA Astrophysics Data System (ADS). The number in brackets after each title indicates the number of citations that the paper has received.

Orcid ID: 0000-0003-2620-2068

List of publications ordered by citations
Number of papers: 155 (refereed: 149)
No. of citations: 4931
First author papers: 28 (refereed: 27)

2025

1. Heating and cooling at a coronal magnetic null [0]
   Cargill, P. J., Hood, A. W. & Johnson, D., MNRAS, 542, 3385

2024

1. Helicity-Conserving Relaxation in Unstable and Merging Twisted Magnetic Flux Ropes [0]
   Browning, Philippa K., Gordovskyy, Mykola & Hood, Alan W., Helicities in Geophysics, Astrophysics, and Beyond (Editors: Kuzanyan, Kirill, Yokoi, Nobumitsu, Georgoulis, Manolis K. & Stepanov, Rodion), 283, p. 189
2. Coronal energy release by MHD avalanches: II. EUV line emission from a multi-threaded coronal loop [9]
   Cozzo, G., Reid, J., Pagano, P., Reale, F., Testa, P., Hood, A. W., Argiroffi, C., Petralia, A., Alaimo, E., D'Anca, F., Sciortino, L., Todaro, M., Lo Cicero, U., Barbera, M., de Pontieu, B. & Martinez-Sykora, J., A&A, 689, A184
3. The thermodynamic response of heating at coronal null points [3]
   Johnson, D., Hood, A. W., Cargill, P. J., Reid, J. & Johnston, C. D., MNRAS, 532, 4261
4. Multithermal apparent damping of slow waves due to strands with a Gaussian temperature distribution [2]
   Van Doorsselaere, T., Krishna Prasad, S., Pant, V., Banerjee, D. & Hood, A., A&A, 683, A109

2023

1. Coronal energy release by MHD avalanches. Effects on a structured, active region, multi-threaded coronal loop [12]
   Cozzo, G., Reid, J., Pagano, P., Reale, F. & Hood, A. W., A&A, 678, A40
2. Self-consistent nanoflare heating in model active regions: MHD avalanches [7]
   Reid, J., Threlfall, J. & Hood, A. W., MNRAS, 518, 1584
3. Self-consistent nanoflare heating in model active regions: MHD avalanches in curved coronal arcades [0]
   Reid, J., Threlfall, J. & Hood, A. W., The Era of Multi-Messenger Solar Physics (Editors: Cauzzi, Gianna & Tritschler, Alexandra), IAU Symposium, 372, p. 116

2022

1. Ambipolar diffusion: Self-similar solutions and MHD code testing. Cylindrical symmetry [4]
   Moreno-Insertis, F., Nóbrega-Siverio, D., Priest, E. R. & Hood, A. W., A&A, 662, A42
2. MHD avalanches in magnetized solar plasma: proliferation and heating in coronal arcades [0]
   Reid, Jack, Threlfall, James & Hood, Alan W., 48th EPS Conference on Plasma Physics, p. E1

2021

1. A fast multi-dimensional magnetohydrodynamic formulation of the transition region adaptive conduction (TRAC) method [20]
   Johnston, C. D., Hood, A. W., De Moortel, I., Pagano, P. & Howson, T. A., A&A, 654, A2
2. Line-tied Boundary Conditions Can Cause Resonant Absorption Models to Generate Unphysically Large Boundary Layers [1]
   Prokopyszyn, A. P. K., Wright, A. N. & Hood, A. W., ApJ, 914, 15
3. Linking computational models to follow the evolution of heated coronal plasma [3]
   Reid, J., Cargill, P. J., Johnston, C. D. & Hood, A. W., MNRAS, 505, 4141
4. Can Multi-threaded Flux Tubes in Coronal Arcades Support a Magnetohydrodynamic Avalanche? [4]
   Threlfall, J., Reid, J. & Hood, A. W., Solar Physics, 296, 120

2020

1. Modelling the solar transition region using an adaptive conduction method [27]
   Johnston, C. D., Cargill, P. J., Hood, A. W., De Moortel, I., Bradshaw, S. J. & Vaseekar, A. C., A&A, 635, A168
2. Coronal energy release by MHD avalanches: Heating mechanisms [24]
   Reid, J., Cargill, P. J., Hood, A. W., Parnell, C. E. & Arber, T. D., A&A, 633, A158
3. Determining whether the squashing factor, Q, would be a good indicator of reconnection in a resistive MHD experiment devoid of null points [12]
   Reid, J., Parnell, C. E., Hood, A. W. & Browning, P. K., A&A, 633, A92
4. How Is Helicity (and Twist) Partitioned in Magnetohydrodynamic Simulations of Reconnecting Magnetic Flux Tubes? [3]
   Threlfall, James, Wright, Andrew N. & Hood, Alan W., ApJ, 898, 1

2019

1. Magnetohydrodynamic waves in braided magnetic fields [14]
   Howson, T. A., De Moortel, I., Reid, J. & Hood, A. W., A&A, 629, A60
2. The effects of numerical resolution, heating timescales and background heating on thermal non-equilibrium in coronal loops [45]
   Johnston, C. D., Cargill, P. J., Antolin, P., Hood, A. W., De Moortel, I. & Bradshaw, S. J., A&A, 625, A149
3. Coronal loop seismology using standing kink oscillations with a lookup table [29]
   Pascoe, David J., Hood, Alan W. & Van Doorsselaere, Tom, Frontiers in Astronomy and Space Sciences, 6, 22
4. Investigating the damping rate of phase-mixed Alfvén waves [11]
   Prokopyszyn, A. P. K. & Hood, A. W., A&A, 632, A93
5. Phase mixing of nonlinear Alfvén waves [22]
   Prokopyszyn, A. P. K., Hood, A. W. & De Moortel, I., A&A, 624, A90
6. Successful and Failed Flux Tube Emergence in the Solar Interior [9]
   Syntelis, P., Archontis, V. & Hood, A., ApJ, 874, 15
7. Eruptions and flaring activity in emerging quadrupolar regions [12]
   Syntelis, P., Lee, E. J., Fairbairn, C. W., Archontis, V. & Hood, A. W., A&A, 630, A134

2018

1. Comparison of methods for modelling coronal magnetic fields [5]
   Goldstraw, E. E., Hood, A. W., Browning, P. K. & Cargill, P. J., A&A, 610, A48
2. Coronal energy release by MHD avalanches: continuous driving [38]
   Reid, J., Hood, A. W., Parnell, C. E., Browning, P. K. & Cargill, P. J., A&A, 615, A84
3. Flux Rope Formation Due to Shearing and Zipper Reconnection [13]
   Threlfall, J., Hood, A. W. & Priest, E. R., Solar Physics, 293, 98
4. Flare particle acceleration in the interaction of twisted coronal flux ropes [16]
   Threlfall, J., Hood, A. W. & Browning, P. K., A&A, 611, A40

2017

1. A relaxation model of coronal heating in multiple interacting flux ropes [3]
   Hussain, A. S., Browning, P. K. & Hood, A. W., A&A, 600, A5
2. A new approach for modelling chromospheric evaporation in response to enhanced coronal heating. II. Non-uniform heating [18]
   Johnston, C. D., Hood, A. W., Cargill, P. J. & De Moortel, I., A&A, 605, A8
3. A new approach for modelling chromospheric evaporation in response to enhanced coronal heating. I. The method [30]
   Johnston, C. D., Hood, A. W., Cargill, P. J. & De Moortel, I., A&A, 597, A81

2016

1. Energy Release in Driven Twisted Coronal Loops [14]
   Bareford, M. R., Gordovskyy, M., Browning, P. K. & Hood, A. W., Solar Physics, 291, 187
2. An MHD Avalanche in a Multi-threaded Coronal Loop. [54]
   Hood, A. W., Cargill, P. J., Browning, P. K. & Tam, K. V., ApJ, 817, 5
3. 3D MHD modeling of twisted coronal loops [40]
   Reale, F., Orlando, S., Guarrasi, M., Mignone, A., Peres, G., Hood, A. W. & Priest, E. R., ApJ, 830, 21
4. Sunspot rotation. II. Effects of varying the field strength and twist of an emerging flux tube [13]
   Sturrock, Z. & Hood, A. W., A&A, 593, A63

2015

1. Shock heating in numerical simulations of kink-unstable coronal loops [21]
   Bareford, M. R. & Hood, A. W., Philosophical Transactions of the Royal Society of London Series A, 373, 20140266
2. Helical Blowout Jets in the Sun: Untwisting and Propagation of Waves [46]
   Lee, E. J., Archontis, V. & Hood, A. W., ApJ, 798, L10
3. Excitation and damping of broadband kink waves in the solar corona [25]
   Pascoe, D. J., Wright, A. N., De Moortel, I. & Hood, A. W., A&A, 578, A99
4. Sunspot rotation. I. A consequence of flux emergence [31]
   Sturrock, Z., Hood, A. W., Archontis, V. & McNeill, C. M., A&A, 582, A76
5. Coronal heating in multiple magnetic threads [20]
   Tam, K. V., Hood, A. W., Browning, P. K. & Cargill, P. J., A&A, 580, A122

2014

1. Recurrent Explosive Eruptions and the "Sigmoid-to-arcade" Transformation in the Sun Driven by Dynamical Magnetic Flux Emergence [34]
   Archontis, V., Hood, A. W. & Tsinganos, K., ApJ, 786, L21

2013

1. The Emergence of Weakly Twisted Magnetic Fields in the Sun [30]
   Archontis, V., Hood, A. W. & Tsinganos, K., ApJ, 778, 42
2. A Numerical Model of Standard to Blowout Jets [112]
   Archontis, V. & Hood, A. W., ApJ, 769, L21
3. Coronal heating by the partial relaxation of twisted loops [29]
   Bareford, M. R., Hood, A. W. & Browning, P. K., A&A, 550, A40
4. Coronal heating and nanoflares: current sheet formation and heating [21]
   Bowness, R., Hood, A. W. & Parnell, C. E., A&A, 560, A89
5. Damping of kink waves by mode coupling. I. Analytical treatment [76]
   Hood, A. W., Ruderman, M., Pascoe, D. J., De Moortel, I., Terradas, J. & Wright, A. N., A&A, 551, A39
6. Damping of kink waves by mode coupling. II. Parametric study and seismology [76]
   Pascoe, D. J., Hood, A. W., De Moortel, I. & Wright, A. N., A&A, 551, A40

2012

1. Magnetic flux emergence: a precursor of solar plasma expulsion [69]
   Archontis, V. & Hood, A. W., A&A, 537, A62
2. Consequences of spontaneous reconnection at a two-dimensional non-force-free current layer [10]
   Fuentes-Fernández, J., Parnell, C. E., Hood, A. W., Priest, E. R. & Longcope, D. W., Physics of Plasmas, 19, 022901
3. 3D MHD Flux Emergence Experiments: Idealised Models and Coronal Interactions [51]
   Hood, A. W., Archontis, V. & MacTaggart, D., Solar Physics, 278, 3
4. Spatial damping of propagating kink waves due to mode coupling [95]
   Pascoe, D. J., Hood, A. W., de Moortel, I. & Wright, A. N., A&A, 539, A37

2011

1. Thermal conduction effects on the kink instability in coronal loops [28]
   Botha, G. J. J., Arber, T. D. & Hood, A. W., A&A, 525, A96
2. Flare particle acceleration and magnetohydrodynamic instabilities [2]
   Browning, P. K., Gordovskyy, M., Stanier, A., Hood, A. W. & Dalla, S., Plasma Physics and Controlled Fusion, 53, 124030
3. Magnetohydrodynamics dynamical relaxation of coronal magnetic fields. II. 2D magnetic X-points [11]
   Fuentes-Fernández, J., Parnell, C. E. & Hood, A. W., A&A, 536, A32
4. Solar magnetic fields [11]
   Hood, Alan W. & Hughes, David W., Physics of the Earth and Planetary Interiors, 187, 78
5. Phase mixing of nonlinear visco-resistive Alfvén waves [43]
   McLaughlin, J. A., de Moortel, I. & Hood, A. W., A&A, 527, A149

2010

1. Flux emergence and coronal eruption [58]
   Archontis, V. & Hood, A. W., A&A, 514, A56
2. Magnetohydrodynamics dynamical relaxation of coronal magnetic fields . I. Parallel untwisted magnetic fields in 2D [12]
   Fuentes-Fernández, J., Parnell, C. E. & Hood, A. W., A&A, 514, A90
3. Simulating the "Sliding Doors" Effect Through Magnetic Flux Emergence [29]
   MacTaggart, David & Hood, Alan W., ApJ, 716, L219
4. Propagating magneto-hydrodynamic waves in a cooling homogenous coronal plasma [35]
   Morton, R. J., Hood, A. W. & Erdélyi, R., A&A, 512, A23
5. Self-consistent ionospheric plasma density modifications by field-aligned currents: Steady state solutions [9]
   Russell, A. J. B., Wright, A. N. & Hood, A. W., Journal of Geophysical Research (Space Physics), 115, A04216

2009

1. On the Structure and Evolution of Complexity in Sigmoids: A Flux Emergence Model [74]
   Archontis, V., Hood, A. W., Savcheva, A., Golub, L. & Deluca, E., ApJ, 691, 1276
2. Formation of Ellerman bombs due to 3D flux emergence [98]
   Archontis, V. & Hood, A. W., A&A, 508, 1469
3. Coronal heating by magnetic reconnection in loops with zero net current [101]
   Hood, A. W., Browning, P. K. & van der Linden, R. A. M., A&A, 506, 913
4. The emergence of toroidal flux tubes from beneath the solar photosphere [72]
   Hood, A. W., Archontis, V., Galsgaard, K. & Moreno-Insertis, F., A&A, 503, 999
5. On the emergence of toroidal flux tubes: general dynamics and comparisons with the cylinder model [44]
   MacTaggart, D. & Hood, A. W., A&A, 507, 995
6. Multiple eruptions from magnetic flux emergence [33]
   MacTaggart, D. & Hood, A. W., A&A, 508, 445
7. MHD Mode Conversion around a 2D Magnetic Null Point [1]
   McDougall, A. M. D. & Hood, A. W., 15th Cambridge Workshop on Cool Stars, Stellar Systems, and the Sun (Editors: Stempels, Eric), American Institute of Physics Conference Series, 1094, p. 752
8. Nonlinear fast magnetoacoustic wave propagation in the neighbourhood of a 2D magnetic X-point: oscillatory reconnection [128]
   McLaughlin, J. A., De Moortel, I., Hood, A. W. & Brady, C. S., A&A, 493, 227
9. Forward modelling to determine the observational signatures of propagating slow waves for TRACE, SoHO/CDS, and Hinode/EIS [36]
   Owen, N. R., De Moortel, I. & Hood, A. W., A&A, 494, 339

2008

1. Heating the corona by nanoflares: simulations of energy release triggered by a kink instability [102]
   Browning, P. K., Gerrard, C., Hood, A. W., Kevis, R. & van der Linden, R. A. M., A&A, 485, 837
2. Emerging flux tubes from the solar interior into the atmosphere: effects of non-constant twist [28]
   Murray, M. J. & Hood, A. W., A&A, 479, 567

2007

1. The Effect of the Relative Orientation between the Coronal Field and New Emerging Flux. I. Global Properties [83]
   Galsgaard, K., Archontis, V., Moreno-Insertis, F. & Hood, A. W., ApJ, 666, 516

2006

1. Flux emergence and interaction with a coronal field: 3D MHD simulations [1]
   Archontis, V., Moreno-Insertis, F., Galsgaard, K. & Hood, A. W., Solar Activity and its Magnetic Origin (Editors: Bothmer, Volker & Hady, Ahmed Abdel), IAU Symposium, 233, p. 53
2. Magnetohydrodynamics wave propagation in the neighbourhood of two dipoles [33]
   McLaughlin, J. A. & Hood, A. W., A&A, 452, 603
3. 3D simulations identifying the effects of varying the twist and field strength of an emerging flux tube [104]
   Murray, M. J., Hood, A. W., Moreno-Insertis, F., Galsgaard, K. & Archontis, V., A&A, 460, 909

2005

1. Phase mixing of Alfvén pulses and wavetrains propagating in coronal holes [10]
   Hood, A. W., Brooks, S. J. & Wright, A. N., Proceedings of the Royal Society of London Series A, 461, 237
2. The Excitation and Damping of Transversal Coronal Loop Oscillations [24]
   Terradas, J., Oliver, R. & Ballester, J. L., ApJ, 618, L149

2004

1. The damping of slow MHD waves in solar coronal magnetic fields. III. The effect of mode coupling [40]
   De Moortel, I., Hood, A. W., Gerrard, C. L. & Brooks, S. J., A&A, 425, 741
2. The damping of slow MHD waves in solar coronal magnetic fields. II. The effect of gravitational stratification and field line divergence [112]
   De Moortel, I. & Hood, A. W., A&A, 415, 705
3. MHD wave propagation in the neighbourhood of a two-dimensional null point [90]
   McLaughlin, J. A. & Hood, A. W., A&A, 420, 1129

2003

1. The damping of slow MHD waves in solar coronal magnetic fields [158]
   De Moortel, I. & Hood, A. W., A&A, 408, 755
2. Field-aligned electron acceleration in Alfvén waves [11]
   Wright, Andrew N. & Hood, Alan W., Journal of Geophysical Research (Space Physics), 108, 1135

2002

1. Coronal heating by the phase mixing of individual pulses propagating in coronal holes [43]
   Hood, A. W., Brooks, S. J. & Wright, A. N., Proceedings of the Royal Society of London Series A, 458, 2307

1999

1. Working Group 2 Report: Energy Input, Heating, and Solar Wind Acceleration in Coronal Holes [1]
   Hood, A. W., Space Science Reviews, 87, 79

1997

1. Phase-mixing poloidal alfvén wave polarisations [3]
   Mann, I. R., Wright, A. N. & Hood, A. W., Advances in Space Research, 20, 489

1996

1. The nonlinear MHD evolution of axisymmetric line-tied loops in the solar corona [7]
   Longbottom, A. W., Hood, A. W. & Rickard, G. J., Plasma Physics and Controlled Fusion, 38, 193
2. Magnetohydrodynamic Waves in Solar Coronal Arcades [27]
   Oliver, R., Hood, A. W. & Priest, E. R., ApJ, 461, 424
3. Validity of the Isobaric Assumption to the Solar Corona [9]
   Walsh, R. W., Bell, G. E. & Hood, A. W., Solar Physics, 169, 33

1995

1. Magnetothermal instabilities in coronal arcades [4]
   Ireland, R. C., Hood, A. W. & Van Der Linden, R. A. M., Solar Physics, 160, 303
2. Current Sheet Models for Inverse Polarity Prominences in Twisted Flux Tubes [10]
   Schonfelder, A. O. & Hood, A. W., Solar Physics, 157, 223
3. Time-Dependent Heating of the Solar Corona [22]
   Walsh, R. W., Bell, G. E. & Hood, A. W., Solar Physics, 161, 83

1994

1. WKB Estimates for the Onset of Ideal Magnetohydrodynamic Instabilities in Solar Coronal Loops [8]
   Hood, A. W., de Bruyne, P., van der Linden, R. A. M. & Goossens, M., Solar Physics, 150, 99
2. The Effect of Magnetic Shear on the Magnetohydrodynamic Stability of a Prominence Model [3]
   Longbottom, A. W. & Hood, A. W., Solar Physics, 155, 267
3. The Magnetohydrodynamic Stability of a Twisted Flux Tube Prominence Model [3]
   Longbottom, A. W. & Hood, A. W., Solar Physics, 154, 51
4. The Stability of 2d Current Sheet Models of Prominences [4]
   Longbottom, A. W., Melville, J. P. & Hood, A. W., Solar Physics, 149, 73
5. A Necessary Condition for the Stability of a Class of Three-dimensional Laminated Equilibria [1]
   Longbottom, A. W., Melville, J. P. & Hood, A. W., ApJ, 423, 496
6. The Influence of Line-Tying on Coronal Perturbations in a Gravitationally Stratified Equilibrium [18]
   van der Linden, R. A. M., Hood, A. W. & Goedbloed, J. P., Solar Physics, 154, 69

1993

1. External and internal solutions for the twisted, flux-tube, prominence model [5]
   Cartledge, N. & Hood, A. W., Solar Physics, 148, 253
2. The Effect of Shear on Numerical Models of Quiescent Normal Polarity Prominences [11]
   Fiedler, R. A. S. & Hood, A. W., Solar Physics, 146, 297
3. The stability of line-tied coronal loops and an extended Suydam criterion [1]
   Hood, A. W., Advances in Space Research, 13, 105
4. Bounds on the Stability of 3-DIMENSIONAL Magnetic Equilibria in the Solar Corona [8]
   Longbottom, A. W., Melville, J. P. & Hood, A. W., Solar Physics, 146, 93
5. Oscillations of a Quiescent Solar Prominence Embedded in a Hot Corona [59]
   Oliver, R., Ballester, J. L., Hood, A. W. & Priest, E. R., ApJ, 409, 809
6. MHD Waves in a Solar Prominence [0]
   Oliver, R., Ballester, J. L., Hood, A. W. & Priest, E. R., Physics of Solar and Stellar Coronae (Editors: Linsky, Jeffrey L. & Serio, Salvatore), Astrophysics and Space Science Library, 183, p. 191
7. The Stability of Two Classes of Solar Quiescent Prominences [13]
   de Bruyne, P. & Hood, A. W., Solar Physics, 147, 97

1992

1. Numerical Models of Quiescent Normal Polarity Prominences [10]
   Fiedler, R. A. S. & Hood, A. W., Solar Physics, 141, 75
2. The Fibril Structure of Prominences [9]
   Hood, A. W., Priest, E. R. & Anzer, U., Solar Physics, 138, 331
3. The Thermal Continuum in Coronal Loops - the Influence of Finite Resistivity on the Continuous Spectrum [10]
   Ireland, R. C., van der Linden, R. A. M., Hood, A. W. & Goossens, M., Solar Physics, 142, 265
4. Loss of Equilibrium in Coronal Loops [3]
   Lothian, R. M. & Hood, A. W., Solar Physics, 137, 105
5. Magnetohydrodynamic Waves in a Solar Prominence [36]
   Oliver, R., Ballester, J. L., Hood, A. W. & Priest, E. R., ApJ, 400, 369
6. The Evolution of Twisted Coronal Loops [18]
   Robertson, J. A., Hood, A. W. & Lothian, R. M., Solar Physics, 137, 273
7. Stability of Line-Tied 1-D Coronal Loops - Significance of an Extended Suydam Criterion [10]
   de Bruyne, P. & Hood, A. W., Solar Physics, 142, 87
8. The relevance of the ballooning approximation for magnetic, thermal, and coalesced magnetothermal instabilities [10]
   van der Linden, R. A. M., Goossens, M. & Hood, A. W., Solar Physics, 140, 317

1991

1. Resistive Ballooning Line-Tied Boundary Conditions [2]
   Hardie, I. S., Hood, A. W. & Allen, H. R., Solar Physics, 133, 313
2. The Fibril Structure of Prominences [13]
   Priest, E. R., Hood, A. W. & Anzer, U., Solar Physics, 132, 199

1990

1. A Model for Quiescent Solar Prominences with Normal Polarity [45]
   Hood, A. W. & Anzer, U., Solar Physics, 126, 117
2. Ideal Kink Instabilities in Line-tied Coronal Loops: Growth Rates and Geometrical Properties [59]
   Velli, M., Einaudi, G. & Hood, A. W., ApJ, 350, 428
3. Boundary Effects on the Magnetohydrodynamic Stability of a Resistive Plasma [36]
   Velli, M., Einaudi, G. & Hood, A. W., ApJ, 350, 419
4. Magnetohydrodynamic Stability of Line-Tied Prominence Magnetic Fields [0]
   de Bruyne, P. & Hood, A. W., IAU Colloquium 117: Dynamics of Quiescent Prominences (Editors: Ruzdjak, Vladimir & Tandberg-Hanssen, Einar), p.270
5. The ideal MHD stability of line-tied coronal loops: A truncated Fourier series approach [4]
   de Bruyne, P., Velli, M. & Hood, A. W., Computer Physics Communications, 59, 55

1989

1. The shape of twisted, line-tied coronal loops [35]
   Browning, P. K. & Hood, A. W., Solar Physics, 124, 271
2. Magnetic and Boundary Effects on Thermal Instabilities in Solar Magnetic Fields - Localized Modes in a Slab Geometry [12]
   Cargill, P. J. & Hood, A. W., Solar Physics, 124, 101
3. Stability and eruption of prominences [2]
   Hood, A. W., Dynamics and Structure of Quiescent Solar Prominences (Editors: Priest, Eric Ronald), Astrophysics and Space Science Library, 150, p. 167
4. A formulation of non-ideal localized (or ballooning) modes in the solar corona [19]
   Hood, A. W., van der Linden, R. & Goossens, M., Solar Physics, 120, 261
5. Twisted Magnetic Flux Tubes - Effect of Small Twist [33]
   Lothian, R. M. & Hood, A. W., Solar Physics, 122, 227
6. A Twisted Flux-Tube Model for Solar Prominences. I. General Properties [210]
   Priest, E. R., Hood, A. W. & Anzer, U., ApJ, 344, 1010
7. Non-equilibrium of a cylindrical magnetic arcade [2]
   Steele, C. D. C., Hood, A. W., Priest, E. R. & Amari, T., Solar Physics, 123, 127
8. Resistive Tearing in Line-Tied Magnetic Fields - Slab Geometry [30]
   Velli, M. & Hood, A. W., Solar Physics, 119, 107
9. Bounds on the Ideal Magnetohydrodynamic Stability of Line-Tied 2-D Coronal Magnetic Fields [24]
   de Bruyne, P. & Hood, A. W., Solar Physics, 123, 241
10. Simple Tests for the Ideal Magnetohydrodynamic Stability of Line-Tied Coronal Magnetic Fields [19]
    de Bruyne, P. & Hood, A. W., Solar Physics, 119, 87

1988

1. Thermal Condensations in Coronal Magnetic Fields [19]
   Hood, A. & Anzer, U., Solar Physics, 115, 61
2. The Effects of Parallel and Perpendicular Viscosity on Resistive Ballooning Modes in Line-Tied Coronal Magnetic Fields [10]
   van der Linden, R., Goossens, M. & Hood, A. W., Solar Physics, 115, 235

1987

1. The stability of line tied force-free cylindrical arcades: Is an active region filament a requirement for a two-ribbon flare? [19]
   Hood, A. & Anzer, U., Solar Physics, 111, 333
2. The effect of gravity on the stability of a line-tied coronal magnetohydrostatic equilibrium [6]
   Melville, J. P., Hood, A. W. & Priest, E. R., Geophysical and Astrophysical Fluid Dynamics, 39, 83
3. Resistive Ballooning Modes in Line-Tied Coronal Fields - Part Two [12]
   Velli, M. & Hood, A. W., Solar Physics, 109, 351

1986

1. The Magnetohydrodynamic Stability of Coronal Arcades. III. Sheared Equilibrium Fields [32]
   Cargill, P. J., Hood, A. W. & Migliuolo, S., ApJ, 309, 402
2. Photospheric Line-Tying Conditions for the Magnetohydrodynamic Stability of Coronal Magnetic Fields [43]
   Hood, A. W., Solar Physics, 105, 307
3. Ballooning Instabilities in the Solar Corona - Conditions for Stability [47]
   Hood, A. W., Solar Physics, 103, 329
4. Criteria for the stability of a line-tied magnetohydrostatic equilibrium in the solar corona [2]
   Melville, J., Hood, A. & Priest, E. R., Advances in Space Research, 6, 49
5. The Ideal Magnetohydrodynamic Stability of a Line-Tied Coronal Magnetohydrostatic Equilibrium [12]
   Melville, J. P., Hood, A. W. & Priest, E. R., Solar Physics, 105, 291
6. Resistive Ballooning Modes in Line-Tied Coronal Fields - Part One - Arcades [27]
   Velli, M. & Hood, A. W., Solar Physics, 106, 353

1984

1. An energy method for the stability of solar magneto hydrostatic atmospheres [23]
   Hood, A. W., Geophysical and Astrophysical Fluid Dynamics, 28, 223
2. The stability of magnetic fields relevant to two-ribbon flares [4]
   Hood, A. W., Advances in Space Research, 4, 49
3. Magnetohydrostatic Structures in the Solar Atmosphere [14]
   Melville, J. P., Hood, A. W. & Priest, E. R., Solar Physics, 92, 15
4. Magnetohydrodynamic stability of line-tied coronal arcades. II - Shearless magnetic fields [11]
   Migliuolo, S., Cargill, P. J. & Hood, A. W., ApJ, 281, 413

1983

1. The Stability of Magnetohydrostatic Atmospheres [12]
   Hood, A. W., Solar Physics, 89, 235
2. Magnetic stability of coronal arcades relevant to two-ribbon flares. [29]
   Hood, A. W., Solar Physics, 87, 279
3. Magnetic equilibrium in coronal arcades. [13]
   Melville, J. P., Hood, A. W. & Priest, E. R., Solar Physics, 87, 301

1982

1. Evolution of current sheets following the onset of enhanced resistivity [11]
   Forbes, T. G., Priest, E. R. & Hood, A. W., Journal of Plasma Physics, 27, 157
2. Effect of pressure gradients and line-tying on the magnetic stability of coronal loops [11]
   Hood, A. W., Priest, E. R. & Einaudi, G., Geophysical and Astrophysical Fluid Dynamics, 20, 247

1981

1. Thermal Nonequilibrium - a Trigger for Solar Flares [23]
   Hood, A. W. & Priest, E. R., Solar Physics, 73, 289
2. Critical conditions for magnetic instabilities in force-free coronal loops [275]
   Hood, A. W. & Priest, E. R., Geophysical and Astrophysical Fluid Dynamics, 17, 297

1980

1. Magnetic instability of coronal arcades as the origin of two-ribbon flares [103]
   Hood, A. W. & Priest, E. R., Solar Physics, 66, 113

1979

1. Kink Instability of Solar Coronal Loops as the Cause of Solar Flares [378]
   Hood, A. W. & Priest, E. R., Solar Physics, 64, 303