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35 results on '"Heikkinen, P. J."'

1. Chiral superfluidity of helium-3 in the quasi-two-dimensional limit

Author

Heikkinen, Petri J., Levitin, Lev V., Rojas, Xavier, Singh, Angadjit, Eng, Nathan, Casey, Andrew, Saunders, John, Vorontsov, Anton, Zhelev, Nikolay, Sebastian, Abhilash Thanniyil, and Parpia, Jeevak M.

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases
Abstract

Anisotropic pair breaking close to surfaces favors chiral superfluid $^3$He-A over time-reversal invariant $^3$He-B. Confining superfluid $^3$He into a cavity of height $D$ of the order of the Cooper pair size characterized by the coherence length $\xi_0$ -- ranging between 16 nm (34 bar) and 77 nm (0 bar) -- extends the surface effects over the whole sample volume, thus allowing stabilization of the A phase at pressures $P$ and temperatures $T$ where otherwise the B phase would be stable. In this work the surfaces of such a confined sample are covered with a superfluid $^4$He film to create specular quasiparticle scattering boundary conditions, preventing the suppression of the superfluid order parameter. We show that the chiral A phase is the stable superfluid phase under strong confinement over the full $P-T$ phase diagram down to a quasi-two-dimensional limit $D/\xi_0 = 1$. The planar phase, which is degenerate with the chiral A phase in the weak-coupling limit, is not observed. The gap inferred from measurements over the wide pressure range from 0.2 to 21.0 bar leads to an empirical ansatz for temperature-dependent strong-coupling effects. We discuss how these results pave the way for the realization of the fully-gapped two-dimensional $p_x + ip_y$ superfluid under more extreme confinement., Comment: 11 pages, 8 figures, including the Supplemental Material

Published
2024

2. QUEST-DMC: Background Modelling and Resulting Heat Deposit for a Superfluid Helium-3 Bolometer

Author

Autti, S., Casey, A., Eng, N., Darvishi, N., Franchini, P., Haley, R. P., Heikkinen, P. J., Kemp, A., Leason, E., Levitin, L. V., Monroe, J., March-Russel, J., Noble, M. T., Prance, J. R., Rojas, X., Salmon, T., Saunders, J., Smith, R., Thompson, M. D., Tsepelin, V., West, S. M., Whitehead, L., Zhang, K., and Zmeev, D. E.

Subjects
Condensed Matter - Other Condensed Matter, Physics - Instrumentation and Detectors
Abstract

We report the results of radioactivity assays and heat leak calculations for a range of common cryogenic materials, considered for use in the QUEST-DMC superfluid 3He dark matter detector. The bolometer, instrumented with nanomechanical resonators, will be sensitive to energy deposits from dark matter interactions. Events from radioactive decays and cosmic rays constitute a significant background and must be precisely modelled, using a combination of material screening and Monte Carlo simulations. However, the results presented here are of wider interest for experiments and quantum devices sensitive to minute heat leaks and spurious events, thus we present heat leak per unit mass or surface area for every material studied. This can inform material choices for other experiments, especially if underground operation is considered where the radiogenic backgrounds will dominate even at shallow depths.

Published
2024
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3. A-B transition in superfluid $^3$He and cosmological phase transitions

Author

Hindmarsh, Mark, Sauls, J. A., Zhang, Kuang, Autti, S., Haley, Richard P., Heikkinen, Petri J., Huber, Stephan J., Levitin, Lev V., Lopez-Eiguren, Asier, Mayer, Adam J., Rummukainen, Kari, Saunders, John, and Zmeev, Dmitry

Subjects
Condensed Matter - Superconductivity, Astrophysics - Cosmology and Nongalactic Astrophysics, High Energy Physics - Phenomenology
Abstract

First order phase transitions in the very early universe are a prediction of many extensions of the Standard Model of particle physics and could provide the departure from equilibrium needed for a dynamical explanation of the baryon asymmetry of the Universe. They could also produce gravitational waves of a frequency observable by future space-based detectors such as the Laser Interferometer Space Antenna (LISA). All calculations of the gravitational wave power spectrum rely on a relativistic version of the classical nucleation theory of Cahn-Hilliard and Langer, due to Coleman and Linde. The high purity and precise control of pressure and temperature achievable in the laboratory made the first-order A to B transition of superfluid $^3$He an ideal for test of classical nucleation theory. As Leggett and others have noted the theory fails dramatically. The lifetime of the metastable A phase is measurable, typically of order minutes to hours, far faster than classical nucleation theory predicts. If the nucleation of B phase from the supercooled A phase is due to a new, rapid intrinsic mechanism that would have implications for first-order cosmological phase transitions as well as predictions for gravitational wave (GW) production in the early universe. Here we discuss studies of the AB phase transition dynamics in $^3$He, both experimental and theoretical, and show how the computational technology for cosmological phase transition can be used to simulate the dynamics of the A-B transition, support the experimental investigations of the A-B transition in the QUEST-DMC collaboration with the goal of identifying and quantifying the mechanism(s) responsible for nucleation of stable phases in ultra-pure metastable quantum phases., Comment: 34 pp, 4 figures. Based on a talk given at Quantum Fluids and Solids 2023, Manchester, U.K, on behalf of the QUEST-DMC collaboration

Published
2024
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4. Nanofluidic platform for studying the first-order phase transitions in superfluid helium-3

Author

Heikkinen, Petri J., Eng, Nathan, Levitin, Lev V., Rojas, Xavier, Singh, Angadjit, Autti, Samuli, Haley, Richard P., Hindmarsh, Mark, Zmeev, Dmitry E., Parpia, Jeevak M., Casey, Andrew, and Saunders, John

Subjects
Condensed Matter - Superconductivity, Astrophysics - Cosmology and Nongalactic Astrophysics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics, Physics - Instrumentation and Detectors
Abstract

The symmetry-breaking first-order phase transition between superfluid phases $^3$He-A and $^3$He-B can be triggered extrinsically by ionising radiation or heterogeneous nucleation arising from the details of the sample cell construction. However, the role of potential homogeneous intrinsic nucleation mechanisms remains elusive. Discovering and resolving the intrinsic processes may have cosmological consequences, since an analogous first-order phase transition, and the production of gravitational waves, has been predicted for the very early stages of the expanding Universe in many extensions of the Standard Model of particle physics. Here we introduce a new approach for probing the phase transition in superfluid $^3$He. The setup consists of a novel stepped-height nanofluidic sample container with close to atomically smooth walls. The $^3$He is confined in five tiny nanofabricated volumes and assayed non-invasively by NMR. Tuning of the state of $^3$He by confinement is used to isolate each of these five volumes so that the phase transitions in them can occur independently and free from any obvious sources of heterogeneous nucleation. The small volumes also ensure that the transitions triggered by ionising radiation are strongly suppressed. Here we present the preliminary measurements using this setup, showing both strong supercooling of $^3$He-A and superheating of $^3$He-B, with stochastic processes dominating the phase transitions between the two. The objective is to study the nucleation as a function of temperature and pressure over the full phase diagram, to both better test the proposed extrinsic mechanisms and seek potential parallel intrinsic mechanisms., Comment: 18 pages, 6 figures, part of the Proceedings of the International Conference on Quantum Fluids and Solids 2023. This is a copy of the version of record of this article, first published in Journal of Low Temperature Physics, available online at Publisher's website: https://doi.org/10.1007/s10909-024-03146-6

Published
2024
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5. Long nanomechanical resonators with circular cross-section

Author

Autti, Samuli, Casey, Andrew, Connelly, Marie, Darvishi, Neda, Franchini, Paolo, Gorman, James, Haley, Richard P., Heikkinen, Petri J., Kemp, Ashlea, Leason, Elizabeth, March-Russell, John, Monroe, Jocelyn, Noble, Theo, Pickett, George R., Prance, Jonathan R., Rojas, Xavier, Salmon, Tineke, Saunders, John, Slater, Jack, Smith, Robert, Thompson, Michael D., West, Stephen M., Whitehead, Luke, Zavjalov, Vladislav V., Zhang, Kuang, and Zmeev, Dmitry E.

Subjects
Physics - Instrumentation and Detectors, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Fabrication of superconducting nanomechanical resonators for quantum research, detectors and devices traditionally relies on a lithographic process, resulting in oscillators with sharp edges and a suspended length limited to a few 100 micrometres. We report a low-investment top-down approach to fabricating NbTi nanowire resonators with suspended lengths up to several millimetres and diameters down to 100 nanometres. The nanowires possess high critical currents and fields, making them a natural choice for magnetomotive actuation and sensing. This fabrication technique is independent of the substrate material, dimensions and layout and can readily be adapted to fabricate nanowire resonators from any metal or alloy with suitable ductility and yield strength. Our work thus opens access to a new class of nanomechanical devices with applications including microscopic and mesoscopic investigations of quantum fluids, detecting dark matter and fundamental materials research in one-dimensional superconductors in vacuum., Comment: 19 pages, 4 figures

Published
2023

6. QUEST-DMC superfluid $^3$He detector for sub-GeV dark matter

Author

Autti, S., Casey, A., Eng, N., Darvishi, N., Franchini, P., Haley, R. P., Heikkinen, P. J., Jennings, A., Kemp, A., Leason, E., Levitin, L. V., Monroe, J., March-Russel, J., Noble, M. T., Prance, J. R., Rojas, X., Salmon, T., Saunders, J., Smith, R., Thompson, M. D., Tsepelin, V., West, S. M., Whitehead, L., Zavjalov, V. V., and Zmeev, D. E.

Subjects
High Energy Physics - Experiment, Astrophysics - Cosmology and Nongalactic Astrophysics, Condensed Matter - Other Condensed Matter, High Energy Physics - Phenomenology
Abstract

The focus of dark matter searches to date has been on Weakly Interacting Massive Particles (WIMPs) in the GeV/$c^2$-TeV/$c^2$ mass range. The direct, indirect and collider searches in this mass range have been extensive but ultimately unsuccessful, providing a strong motivation for widening the search outside this range. Here we describe a new concept for a dark matter experiment, employing superfluid $^3$He as a detector for dark matter that is close to the mass of the proton, of order 1 GeV/$c^2$. The QUEST-DMC detector concept is based on quasiparticle detection in a bolometer cell by a nanomechanical resonator. In this paper we develop the energy measurement methodology and detector response model, simulate candidate dark matter signals and expected background interactions, and calculate the sensitivity of such a detector. We project that such a detector can reach sub-eV nuclear recoil energy threshold, opening up new windows on the parameter space of both spin-dependent and spin-independent interactions of light dark matter candidates., Comment: 17 pages, 8 figures, 2 tables. Published in EPJ-C

Published
2023
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7. QUEST-DMC superfluid 3He detector for sub-GeV dark matter

Author

Autti, S., Casey, A., Eng, N., Darvishi, N., Franchini, P., Haley, R. P., Heikkinen, P. J., Jennings, A., Kemp, A., Leason, E., Levitin, L. V., Monroe, J., March-Russel, J., Noble, M. T., Prance, J. R., Rojas, X., Salmon, T., Saunders, J., Smith, R., Thompson, M. D., Tsepelin, V., West, S. M., Whitehead, L., Zavjalov, V. V., and Zmeev, D. E.

Published
2024
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8. Rotating quantum wave turbulence

Author

Mäkinen, J. T., Autti, S., Heikkinen, P. J., Hosio, J. J., Hänninen, R., L'vov, V. S., Walmsley, P. M., Zavjalov, V. V., and Eltsov, V. B.

Subjects
Physics - Fluid Dynamics, Condensed Matter - Other Condensed Matter
Abstract

Rotating turbulence is ubiquitous in nature. Previous works suggest that such turbulence could be described as an ensemble of interacting inertial waves across a wide range of length scales. For turbulence in macroscopic quantum condensates, the nature of the transition between the quasiclassical dynamics at large scales and the corresponding dynamics at small scales, where the quantization of vorticity is essential, remains an outstanding unresolved question. Here we expand the paradigm of wave-driven turbulence to rotating quantum fluids where the spectrum of waves extends to microscopic scales as Kelvin waves on quantized vortices. We excite inertial waves at the largest scale by periodic modulation of the angular velocity and observe dissipation-independent transfer of energy to smaller scales and the eventual onset of the elusive Kelvin-wave cascade at the lowest temperatures. We further find that energy is pumped to the system through a boundary layer distinct from the classical Ekman layer and support our observations with numerical simulations. Our experiments demonstrate a new regime of turbulent motion in quantum fluids where the role of vortex reconnections can be neglected, thus stripping the transition between the classical and the quantum regimes of turbulence down to its bare bones., Comment: 21 pages, 11 figures

Published
2022
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9. Nonlinear two-level dynamics of quantum time crystals

Author

Autti, Samuli, Heikkinen, Petri J, Nissinen, Jaakko, Mäkinen, Jere T, Volovik, Grigori E, Zavjalov, Vladislav V, and Eltsov, Vladimir B

Subjects
Quantum Physics, Condensed Matter - Other Condensed Matter
Abstract

A time crystal is a macroscopic quantum system in periodic motion in its ground state, stable only if isolated from energy exchange with the environment. For this reason, coupling separate time crystals is challenging, and time crystals in a dynamic environment have yet not been studied. In our experiments, two coupled time crystals made of spin-wave quasiparticles (magnons) form a macroscopic two-level system. The two levels evolve in time as determined intrinsically by a nonlinear feedback. Magnons move from the ground level to the excited level driven by the Landau-Zener effect, combined with Rabi population oscillations. We thus demonstrate how to arrange spontaneous dynamics between interacting time crystals. Our experiments allow access to every aspect and detail of the interaction in a single run of the experiment, inviting technological exploitation-- potentially even at room temperature., Comment: 14 pages, 5 figures

Published
2021
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11. Vortex-mediated relaxation of magnon BEC into light Higgs quasiparticles

Author

Autti, S., Heikkinen, P. J., Laine, S. M., Mäkinen, J. T., Thuneberg, E. V., Zavjalov, V. V., and Eltsov, V. B.

Subjects
Condensed Matter - Other Condensed Matter
Abstract

A magnon Bose-Einstein condensate in superfluid $^3$He is a fine instrument for studying the surrounding macroscopic quantum system. At zero temperature, the BEC is subject to a few, distinct forms of decay into other collective excitations, owing to momentum and energy conservation in a quantum vacuum. We study the vortex-Higgs mechanism: the vortices relax the requirement for momentum conservation, allowing the optical magnons of the BEC to transform into light Higgs quasiparticles. This observation expands the spectrum of possible interactions between magnetic quasiparticles in $^3$He-B, opens pathways for hunting down elusive phenomena such as the Kelvin wave cascade or bound Majorana fermions, and lays groundwork for building magnon-based quantum devices., Comment: 9 pages, 3 figures

Published
2021
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12. AC Josephson effect between two superfluid time crystals

Author

Autti, Samuli, Heikkinen, Petri J., Mäkinen, Jere T., Volovik, Grigori E., Zavjalov, Vladislav V., and Eltsov, Vladimir B.

Subjects
Condensed Matter - Other Condensed Matter, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Quantum time crystals are systems characterised by spontaneously emerging periodic order in the time domain. A range of such phases has been reported. The concept has even been discussed in popular literature, and deservedly so: while the first speculation on a phase of broken time translation symmetry did not use the name "time crystal", it was later adopted from 1980's popular culture. For the physics community, however, the ultimate qualification of a new concept is its ability to provide predictions and insight. Confirming that time crystals manifest the basic dynamics of quantum mechanics is a necessary step in that direction. We study two adjacent quantum time crystals experimentally. The time crystals, realised by two magnon condensates in superfluid $^3$He-B, exchange magnons leading to opposite-phase oscillations in their populations -- AC Josephson effect -- while the defining periodic motion remains phase coherent throughout the experiment., Comment: 7 pages, 2 figures

Published
2020
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13. Fragility of surface states in topological superfluid $^3$He

Author

Heikkinen, P. J., Casey, A., Levitin, L. V., Rojas, X., Vorontsov, A., Sharma, P., Zhelev, N., Parpia, J. M., and Saunders, J.

Subjects
Condensed Matter - Superconductivity
Abstract

Topological superfluid $^3$He, with unconventional spin-triplet p-wave pairing, provides a model system for topological superconductors, which have attracted significant interest through potential applications in topologically protected quantum computing. In topological insulators and quantum Hall systems, the surface/edge states, arising from bulk-surface correspondence and the momentum space topology of the band structure, are robust. Here we demonstrate that in topological superconductors the surface Andreev bound states, which depend on the momentum space topology of the emergent order parameter, are fragile with respect to the details of surface scattering. We confine superfluid $^3$He within a cavity of height comparable to the Cooper pair diameter. We precisely determine the superfluid transition temperature $T_{\mathrm{c}}$ and the suppression of the superfluid energy gap, for different scattering conditions tuned in situ, and compare to the predictions of quasi-classical theory. We discover that surface magnetic scattering leads to unexpectedly large suppression of $T_{\mathrm{c}}$, corresponding to an increased density of low energy bound states., Comment: Main text: 10 pages + 4 figures; Supplementary information: 33 pages, 14 figures

Published
2019
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16. Propagation of self-localised Q-ball solitons in the $^3$He universe

Author

Autti, S., Heikkinen, P. J., Volovik, G. E., Zavjalov, V. V., and Eltsov, V. B.

Subjects
Condensed Matter - Other Condensed Matter, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology
Abstract

In relativistic quantum field theories, compact objects of interacting bosons can become stable owing to conservation of an additive quantum number $Q$. Discovering such $Q$-balls propagating in the Universe would confirm supersymmetric extensions of the standard model and may shed light on the mysteries of dark matter, but no unambiguous experimental evidence exists. We report observation of a propagating long-lived $Q$-ball in superfluid $^3$He, where the role of $Q$-ball is played by a Bose-Einstein condensate of magnon quasiparticles. We achieve accurate representation of the $Q$-ball Hamiltonian using the influence of the number of magnons, corresponding to the charge $Q$, on the orbital structure of the superfluid $^3$He order parameter. This realisation supports multiple coexisting $Q$-balls which in future allows studies of $Q$-ball dynamics, interactions, and collisions., Comment: 10 pages, 7 figures

Published
2017
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18. QUEST-DMC: Background Modelling and Resulting Heat Deposit for a Superfluid Helium-3 Bolometer

Author

Autti, S., primary, Casey, A., additional, Eng, N., additional, Darvishi, N., additional, Franchini, P., additional, Haley, R. P., additional, Heikkinen, P. J., additional, Kemp, A., additional, Leason, E., additional, Levitin, L. V., additional, Monroe, J., additional, March-Russel, J., additional, Noble, M. T., additional, Prance, J. R., additional, Rojas, X., additional, Salmon, T., additional, Saunders, J., additional, Smith, R., additional, Thompson, M. D., additional, Tsepelin, V., additional, West, S. M., additional, Whitehead, L., additional, Zhang, K., additional, and Zmeev, D. E., additional

Published
2024
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19. Measurements of anisotropic mass of magnons confined in a harmonic trap in superfluid $^3$He-B

Author

Zavjalov, V. V., Autti, S., Eltsov, V. B., and Heikkinen, P. J.

Subjects
Condensed Matter - Other Condensed Matter
Abstract

We can pump magnons to a nearly harmonic magneto-textural trap in superfluid $^3$He-B. Using the NMR spectroscopy of levels in the trap we have measured the anisotropic magnon mass and related values of the spin-wave velocities. Based on our measurements we provide values of the Fermi-liquid parameter $F^a_1$., Comment: 6 pages, 8 figures

Published
2016
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27. Vortex-mediated relaxation of magnon BEC into light Higgs quasiparticles

Author

Autti, S. (S.), Heikkinen, P. J. (P. J.), Laine, S. M. (S. M.), Mäkinen, J. T. (J. T.), Thuneberg, E. V. (E. V.), Zavjalov, V. V. (V. V.), Eltsov, V. B. (V. B.), Autti, S. (S.), Heikkinen, P. J. (P. J.), Laine, S. M. (S. M.), Mäkinen, J. T. (J. T.), Thuneberg, E. V. (E. V.), Zavjalov, V. V. (V. V.), and Eltsov, V. B. (V. B.)

Abstract

A magnon Bose-Einstein condensate (BEC) in superfluid ³He is a fine instrument for studying the surrounding macroscopic quantum system. At zero temperature, the BEC is subject to a few distinct forms of decay into other collective excitations, owing to momentum and energy conservation in a quantum vacuum. We study the vortex-Higgs mechanism: The vortices relax the requirement for momentum conservation, allowing the optical magnons of the BEC to transform into light Higgs quasiparticles. This facilitates a direct measurement of the dimensions of the B-phase double-core vortex, providing experimental access to elusive phenomena, such as the Kelvin wave cascade and core-bound Majorana fermions. Our paper expands the spectrum of possible interactions between magnetic quasiparticles in ³He -B and lays the groundwork for building magnon-based quantum devices.

Published
2021

32. SEISMIC ORE EXPLORATION IN THE OUTOKUMPU AREA, EASTERN FINLAND: CONSTRAINTS FROM SEISMIC FORWARD MODELLING AND GEOMETRICAL CONSIDERATIONS.

Author

Komminaho, Kari, Koivisto, Emilia, Heikkinen, Pekka J., Tuomi, Hilkka, Junno, Niina, and Kukkonen, Ilmo

Subjects
SEISMIC prospecting, ORE deposits, GEOMETRIC modeling, SULFIDE minerals, ACOUSTIC properties of rocks
Abstract

The main goals of the work presented here were (1) to utilize seismic forward modelling to gain a better understanding of the seismic signature of the Outokumpu assemblage rocks and associated Outokumpu-type semimassive to massive sulphide Cu-Co-Zn-Ni-Ag-Au deposits, and (2) to develop tailored seismic reflection data processing schemes and analyses for aiding seismic ore exploration in the Outokumpu area. Seismic reflection profile OKU1 at the southwestern end of the Outokumpu area was chosen as the main focus of the seismic forward modelling and processing efforts, because OKU1 is located close to the 2.5-km-deep Outokumpu Deep Drill Hole, which provides direct lithological control for the observed reflectivity and well-documented acoustic properties of the Outokumpu rocks to be used in forward modelling. The forward modelling results show that within mica schist hosting them, the Outokumpu assemblage rocks (and black schist enveloping them) form internally strongly reflective packages typically characterized by numerous diffraction hyperbolas in the stacked sections. These reflectivity characteristics can be used to target the potentially ore-bearing Outokumpu assemblage rocks at depth, and the seismic reflection data provide a good basis for setting regional exploration targets in the Outokumpu area. Based on the results of this study, it seems also possible that the Outokumpu-type sulphide mineralizations could even be directly observed as high-amplitude anomalies in the seismic reflection sections, if the dimensions and orientation are optimal. A careful crookedline data processing sequence should be able to preserve the direct signals, if present in the measured seismic reflection data, except for very shallow signals that are more likely to be distorted by the crooked-line effects. However, the crooked-line effects can also potentially produce high-amplitude anomalies, and care is required when interpreting the high-amplitude anomalies in the light of ore exploration. In addition to seismic reflection profile OKU1, forward modelling results are also presented for the Kylylahti mine area at the northwestern side of the Outokumpu area, where the complex 3D geometry - especially the occasionally near-vertical orientation of the Outokumpu assemblage rock units - poses a challenge for surface seismic data acquisition. Finally, seismic reflection profile V7 is used as an example of another strongly reflective unit present in the Outokumpu area in addition to the Outokumpu assemblage rocks, i.e., the Archaean basement and overlying Proterozoic supracrustal rocks, and how the true orientation of the reflectors obtained from a 2D seismic reflection section can be analysed with the help of surface geological data. [ABSTRACT FROM AUTHOR]

Published
2016

33. DEVELOPMENT OF MINING CAMP EXPLORATION AND TECHNOLOGIES FOR THE OUTOKUMPU BROWNFIELD REGION.

Author

Aatos, Soile, Heikkinen, Pekka J., and Kukkonen, Ilmo

Subjects
MINING camps, BROWNFIELDS, ORE deposits, STRUCTURAL geology, GEOLOGICAL modeling
Abstract

This article introduces the objectives and main achievements of the project Developing Mining Camp Exploration Concepts and Technologies - Brownfield Exploration (2013-2016), funded by the Tekes Green Mining programme and jointly conducted by the Geological Survey of Finland and the University of Helsinki. The project focused on developing deep exploration concepts and technologies for previously explored and exploited mining camps in crystalline bedrock areas. The Outokumpu Cu-Co-Zn-Ni- Ag-Au ore belt (Outokumpu Belt), situated in the Outokumpu brownfield region (Outokumpu Mining Camp area), North Karelia, Eastern Finland, and having an exploration and mining history extending back over a century, was chosen as the domain of the study. The project defined the Outokumpu Mining Camp (OMC) area, comprising the Outokumpu Belt, Miihkali Basin and Kylylahti mine area as the main research sub-areas, to demonstrate the development of the deep exploration concept by using state-of-the-art applications in deep geophysical data acquisition and modelling. The project surveyed the bedrock and ore potential of the OMC to the depth of 2 km, and to 5 km in cases, using seismic reflection data, audiomagnetotellurics, the airborne Z-axis tipper electromagnetic method, and electromagnetic and potential field methods (gravity and magnetic). The project compiled and further developed quantitative deep geophysical interpretations and common earth models of the subsurface of the OMC based on its petrophysical, elastic, electric, density and magnetic properties in concordance with interpretations of regional to target scale structural and bedrock geology in order to trace deep existing conductive, dense, reflective and magnetic zones implying anomalies related to Outokumpu assemblage rocks having mineral potential. By combining coeval geophysical and geological modelling, the deep exploration concept for Outokumpu-type mineral deposits was improved in an iterative multidisciplinary approach involving geophysics, structural and bedrock geology and geochemistry. The project produced digital geo-referenced, visually or computationally integrated earth models, in the form of surfaces, profiles and 3D objects. [ABSTRACT FROM AUTHOR]

Published
2016

34. Propagation of self-localized Q-ball solitons in the -3Heuniverse.

Author

Autti, S., Heikkinen, P. J., Volovik, G. E., Zavjalov, V. V., and Eltsov, V. B.

Subjects
*SOLITONS, *QUANTUM field theory, *QUANTUM numbers
Abstract

In relativistic quantum field theories, compact objects of interacting bosons can become stable owing to conservation of an additive quantum number Q. Discovering such Q balls propagating in the universe would confirm supersymmetric extensions of the standard model and may shed light on the mysteries of dark matter, but no unambiguous experimental evidence exists. We have created long-lived Q-ball solitons in superfluid -3He, where the role of the Q ball is played by a Bose-Einstein condensate of magnon quasiparticles. The principal qualitative attribute of a Q ball is observed experimentally: its propagation in space together with the self-created potential trap. Additionally, we show that this system allows for a quantitatively accurate representation of the Q-ball Hamiltonian. Our Q ball belongs to the class of the Friedberg-Lee-Sirlin Q balls with an additional neutral field ζ , which is provided by the orbital part of the Nambu-Goldstone mode. Multiple Q balls can be created in the experiment, and we have observed collisions between them. This set of features makes the magnon condensates in superfluid -3He a versatile platform for studies of Q-ball dynamics and interactions in three spatial dimensions. [ABSTRACT FROM AUTHOR]

Published
2018
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