130 research outputs found
Accretion disks in Algols: progenitors and evolution
There are only a few Algols with measured accretion disk parameters. These
measurements provide additional constraints for tracing the origin of
individual systems, narrowing down the initial parameter space. We investigate
the origin and evolution of 6 Algol systems with accretion disks to find the
initial parameters and evolutionary constraints for them. With a modified
binary evolution code, series of close binary evolution are calculated to
obtain the best match for observed individual systems. Initial parameters for 6
Algol systems with accretion disks were determined matching both the present
system parameters and the observed disk characteristics. When RLOF starts
during core hydrogen burning of the donor, the disk lifetime was found to be
short. The disk luminosity is comparable to the luminosity of the gainer during
a large fraction of the disk lifetime.Comment: 8 pages, 6 figures , accepted by A&
Mass loss out of close binaries
In a liberal evolutionary scenario, mass can escape from a binary during eras
of fast mass transfer. We calculate the mass lost by binaries with a B-type
primary at birth where mass transfer starts during hydrogen core burning of the
donor. We simulate the distribution of mass-ratios and orbital periods for
those interacting binaries. The amount of time the binary shows Algol
characteristics within different values of mass-ratio and orbital period has
been fixed from conservative and liberal evolutionary calculations. We use
these data to simulate the distribution of mass-ratios and orbital periods of
Algols with the conservative as well as the liberal model. We compare
mass-ratios and orbital periods of Algols obtained by conservative evolution
with those obtained by our liberal model. Since binaries with a late B-type
primary evolve almost conservatively, the overall distribution of mass-ratios
will only yield a few Algols more with high mass-ratios than conservative
calculations do. Whereas the simulated distribution of orbital periods of
Algols fits the observations well, the simulated distribution of mass-ratios
produces always too few systems with large values.Comment: 6 pages, 6 figures, accepted for publication in A&A; accepted versio
Spin-up and hot spots can drive mass out of a binary
The observed distribution of periods and mass ratios of Algols with a B type
primary at birth was updated. Conservative evolution fails to produce the large
fraction with a high mass ratio: i.e. q in [0.4-0.6]. Interacting binaries thus
have to lose mass before or during Algolism. During RLOF mass is transferred
continuously from donor to gainer. The gainer spins up; sometimes up to
critical velocity. Equatorial material on the gainer is therefore less bound to
the system. The material coming from the donor through the first Langrangian
point impinges violently on the surface of the gainer or the edge of the
accretion disc, creating a hot spot in the area of impact. The sum of
rotational energy (fast rotation) and radiative energy (hot spot) depends on
the mass-loss rate. The sum of both energies on a test mass located in the
impact area equals exactly its binding energy at some critical value. As long
as the mass transfer rate is smaller than this value the gainer accepts all the
mass coming from the donor: RLOF happens conservatively. But as soon as the
critical rate is exceeded the gainer will acquire no more than the critical
value and RLOF runs into its liberal era. Low mass binaries never achieve
mass-loss rates larger than the critical value. Intermediate mass binaries
evolve mainly conservatively but mass will be blown away from the system during
the short era of rapid mass transfer soon after RLOF-ignition. Binaries with
9+5.4 solar masses (P in [2-4] d) evolve almost always conservatively. Only
during some 20,000 years the gainer is not capable of grasping all the material
that comes from the donor. During this short lapse of time a significant
fraction of the mass of the system is blown into interstellar space. The mass
ratio bin [0.4-0.6] is now much better represented.Comment: 12 pages, 7 figures, accepted for publication in A&A; accepted
versio
Mass loss out of close binaries. II
Liberal evolution of interacting binaries has been proposed previously by
several authors in order to meet various observed binary characteristics better
than conservative evolution does. Since Algols are eclipsing binaries the
distribution of their orbital periods is precisely known. The distribution of
their mass ratios contains however more uncertainties. We try to reproduce
these two distributions theoretically using a liberal scenario in which the
gainer star can lose mass into interstellar space as a consequence of its rapid
rotation and the energy of a hot spot. In a recent paper (Van Rensbergen et al.
2010, A&A) we calculated the liberal evolution of binaries with a B-type
primary at birth where mass transfer starts during core hydrogen burning of the
donor. In this paper we include the cases where mass transfer starts during
hydrogen shell burning and it is our aim to reproduce the observed
distributions of the system parameters of Algol-type semi-detached systems. Our
calculations reveal the amount of time that an Algol binary lives with a well
defined value of mass ratio and orbital period. We use these data to simulate
the distribution of mass ratios and orbital periods of Algols. Binaries with a
late B-type initial primary hardly lose any mass whereas those with an early B
primary evolve in a non-conservative way. Conservative binary evolution
predicts only ~ 12 % of Algols with a mass ratio q above 0.4. This value is
raised up to ~ 17 % using our scenario of liberal evolution, which is still far
below the ~ 45 % that is observed. Observed orbital periods of Algol binaries
larger than one day are faithfully reproduced by our liberal scenario. Mass
ratios are reproduced better than with conservative evolution, but the
resemblance is still poor.Comment: 11 pages, 6 figures, accepted for publication in A&A; accepted
versio
On the origin and evolutionary state of RZ Cas, KO Aql and S Equ
Aims. Determination of the present evolutionary state and the restrictions on
the initial mass ratios of RZ Cas, KO Aql and S Equ. Methods. Comparison of
mass gaining stars with evolutionary models of single stars with the same mass
and subsequent comparison with accretion tracks from simultaneous conservative
binary evolution. Results. The gainers are in an early main sequence stage (Xc
greater than 0.5), with KO Aql being almost unevolved (assuming quasi-thermal
equilibrium). The initial donor/gainer mass ratios Mdi/Mgi must be larger than
three to obtain the present mass and luminosity of the gainers.Comment: 4 pages, 2 figures, accepted for publication in A&A; accepted versio
Where do the elderly die? The impact of nursing home utilisation on the place of death. Observations from a mortality cohort study in Flanders
BACKGROUND: Most of the research concerning place of death focuses on terminally ill patients (cancer patients) while the determinants of place of death of the elderly of the general population are not intensively studied. Studies showed the influence of gender, age, social-economical status and living arrangements on the place of death, but a facet not taken into account so far is the influence of the availability of nursing homes. METHODS: We conducted a survey of deaths, between January 1999 and December 2000 in a small densely populated area in Belgium, with a high availability of nursing homes (within 5 to 10 km of the place of residence of every elderly). We determined the incidence of total mortality (of subjects >60 years) from local official death registers that we consulted via the priest or the mortician of the local parish, to ask where the decedent had died and whether the deceased had lived in a nursing home. We compared the distribution of the places of death between parishes with a nursing home and with parishes without nursing home. RESULTS: 240 women and 217 men died during the two years study period. Only 22% died at home, while the majority (78%) died in an institutional setting, either a hospital (50%) or a nursing home (28%). Place of death was influenced by individual factors (age and gender) and the availability of a nursing home in the 'own' parish. The chance of in-hospital death was 65% higher for men (95% Confidence Interval [CI]: 14 to 138%; p = 0.008) and decreased by 4% (CI: -5.1% to -2.5%; p < 0.0001) for each year increase in age. Independent of gender and age, the chance of in-hospital death was 41% (CI: -60% to -13%; p = 0.008) lower in locations with a nursing home. CONCLUSION: Demographic, but especially social-contextual factors determine where elderly will end their life. The majority of elderly in Flanders die in an institution. Age, gender and living situation are predictors of the place of death but the embedment of a nursing home in the local community seems to be a key predictor
Geological and morphological setting of 2778 methane seeps in the Dnepr paleo-delta, northwestern Black Sea
The Dnepr paleo-delta area in the NW Black Sea is characterized by an abundant presence of methane seeps. During the expeditions of May–June 2003 and 2004 within the EU-funded CRIMEA project, detailed multibeam, seismic and hydro-acoustic water-column investigations were carried out to study the relation between the spatial distribution of methane seeps, sea-floor morphology and sub-surface structures.2778 new methane seeps were detected on echosounding records in an area of 1540 km2. All seeps are located in the transition zone between the continental shelf and slope, in water depths of 66 to 825 m. The integration of the different geophysical datasets clearly indicates that methane seeps are not randomly distributed in this area, but are concentrated in specific locations.The depth limit for the majority of the detected seeps is 725 m water depth, which corresponds more or less with the stability limit for pure methane hydrate at the ambient bottom temperature (8.9 °C) in this part of the Black Sea. This suggests that, where gas hydrates are stable, they play the role of buffer for the upward migration of methane gas and thus prevent seepage of methane bubbles into the water column.Higher up on the margin, gas seeps are widespread, but accurate mapping illustrates that seeps occur preferentially in association with particular morphological and sub-surface features. On the shelf, the highest concentration of seeps is found in elongated depressions (pockmarks) above the margins of filled channels. On the continental slope where no pockmarks have been observed, seepage occurs along crests of sedimentary ridges. There, seepage is focussed by a parallel-stratified sediment cover that thins out towards the ridge crests. On the slope, seepage also appears in the vicinity of canyons (bottom, flanks and margins) or near the scarps of submarine landslides where mass-wasting breaches the fine-grained sediment cover that acts as a stratigraphic seal. The seismic data show the presence of a distinct “gas front,” which has been used to map the depth of the free gas within the sea-floor sediments. The depth of this gas front is variable and locally domes up to the sea floor. Where the gas front approaches the seafloor, gas bubbles were detected in the water column. A regional map of the sub-surface depth of the gas front emphasises this “gas front-versus-seep” relationship.The integration of all data sets indicates that the spatial distribution of methane seeps in the Dnepr paleo-delta is mainly controlled by the gas-hydrate stability zone as well as by stratigraphic and sedimentary factors
Geological and morphological setting of 2778 methane seeps in the Dnepr paleo-delta, northwestern Black Sea
The Dnepr paleo-delta area in the NW Black Sea is characterized by an abundant presence of methane seeps. During the expeditions of May–June 2003 and 2004 within the EU-funded CRIMEA project, detailed multibeam, seismic and hydro-acoustic water-column investigations were carried out to study the relation between the spatial distribution of methane seeps, sea-floor morphology and sub-surface structures.2778 new methane seeps were detected on echosounding records in an area of 1540 km2. All seeps are located in the transition zone between the continental shelf and slope, in water depths of 66 to 825 m. The integration of the different geophysical datasets clearly indicates that methane seeps are not randomly distributed in this area, but are concentrated in specific locations.The depth limit for the majority of the detected seeps is 725 m water depth, which corresponds more or less with the stability limit for pure methane hydrate at the ambient bottom temperature (8.9 °C) in this part of the Black Sea. This suggests that, where gas hydrates are stable, they play the role of buffer for the upward migration of methane gas and thus prevent seepage of methane bubbles into the water column.Higher up on the margin, gas seeps are widespread, but accurate mapping illustrates that seeps occur preferentially in association with particular morphological and sub-surface features. On the shelf, the highest concentration of seeps is found in elongated depressions (pockmarks) above the margins of filled channels. On the continental slope where no pockmarks have been observed, seepage occurs along crests of sedimentary ridges. There, seepage is focussed by a parallel-stratified sediment cover that thins out towards the ridge crests. On the slope, seepage also appears in the vicinity of canyons (bottom, flanks and margins) or near the scarps of submarine landslides where mass-wasting breaches the fine-grained sediment cover that acts as a stratigraphic seal. The seismic data show the presence of a distinct “gas front,” which has been used to map the depth of the free gas within the sea-floor sediments. The depth of this gas front is variable and locally domes up to the sea floor. Where the gas front approaches the seafloor, gas bubbles were detected in the water column. A regional map of the sub-surface depth of the gas front emphasises this “gas front-versus-seep” relationship.The integration of all data sets indicates that the spatial distribution of methane seeps in the Dnepr paleo-delta is mainly controlled by the gas-hydrate stability zone as well as by stratigraphic and sedimentary factors
Gas chimneys from source to surface: imaging and modelling in the Connemara Field, Porcupine Basin
The Porcupine basin is a north-south trending graben of Jurassic age filled with Mesozoic and Tertiary sediments lying unconformably on upper Palaeozoic rocks. The basin formed as a result of an early abortive northeasterly arm of the Mid-Atlantic spreading ridge. It continues to be a subsiding basin at present time. The Connemara field is located in the northern part of the basin. Structurally, it lies at the confluence of two principal fault systems: a N-S fault regime characteristic of the main Porcupine basin, and the E-W and NE-SW trends of reactivated Caledonian faults. It can be imaged as a broad, tilted block faulted structure trending northeast-southwest, bounded by major faults to the east and west. Between these faults appears a structure broadly synclinal in section, dipping southwest, with an axis parallel to the trend of the major faults, filled of mesozoic sediments, and partly closed by the base of the Cretaceous unconformity. Hydrocarbons were found at the end of the 70sĹ in three reservoirs within the middle Jurassic in the synclinal structure. Tight 2D and 3D seismic coverage over the Connemara field showed the presence of vertical paths of fluid and/or gas migrating upward in the formation. Most of these chimneys stop at the Plio-Pleistocene boundary, about 0.1 msec TWT below the seafloor. None of them reaches the present-day surface. They are mostly located above the structural high corresponding to the tilted fault block (horst), and are found along a south-north trend starting above the N-S fault bounding the horst to the west. Some isolated chimneys were also detected in the western part of the field. Detailed interpretation of chosen seismic cross-sections throughout the field, constrained by well-logs and core analysis allowed to propose a scenario for the genesis of these features. Some of the oil generated in the middle Jurassic source rocks, further south of the Porcupine basin, migrated updip to the north where it has either become entrapped within Jurassic reservoir layers, or percolated up fault planes to shallower layers where fluid and gas could escape through the more permeable upper Cretaceous and Tertiary sandstones. Another interesting feature is the abundance of pockmarks throughout the entire field. More than 1100 were mapped from 2D survey seismic profiles. They are known to form through the eruption of methane gas trapped in the sediments. They are proposed to be the expression at the surface of the fluid and gas that migrated from deeper parts of the basin, first through fault planes, then through the formation using more or less energetic ways (shock waves, percolation, diffusion)
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