The multidimensional Plateau problem in the spectral class of all manifolds with a fixed boundary

The growing database of exoplanets has shown us the statistical characteristics of various exoplanet populations, providing insight towards their origins. Observational evidence suggests that the process by which gas giants are conceived in the stellar disk may be disparate from that of smaller planets. Using NASA’s Exoplanet Archive, we analyzed the relationships between planet mass and stellar metallicity, as well as planet mass and stellar mass for low-mass exoplanets (MP < 0.13 MJ) orbiting spectral class G, K, and M stars. We performed further uncertainty analysis to confirm that the exponential law relationships found between the planet mass, stellar mass, and the stellar metallicity cannot be fully explained by observation biases alone.

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Computing the shape gradient of stellarator coil complexity with respect to the plasma boundary

Journal of Plasma Physics ◽

10.1017/s0022377821000386 ◽

2021 ◽

Vol 87 (2) ◽

Author(s):

Arthur Carlton-Jones ◽

Elizabeth J. Paul ◽

William Dorland

Keyword(s):

Null Space ◽

Radial Distance ◽

Plasma Boundary ◽

Optimization Approach ◽

Surface Parameters ◽

Fixed Boundary ◽

Plasma Surface ◽

Shape Gradient ◽

Derivative Free ◽

Boundary Optimization

Coil complexity is a critical consideration in stellarator design. The traditional two-step optimization approach, in which the plasma boundary is optimized for physics properties and the coils are subsequently optimized to be consistent with this boundary, can result in plasma shapes which cannot be produced with sufficiently simple coils. To address this challenge, we propose a method to incorporate considerations of coil complexity in the optimization of the plasma boundary. Coil complexity metrics are computed from the current potential solution obtained with the REGCOIL code (Landreman, Nucl. Fusion, vol. 57, 2017, 046003). While such metrics have previously been included in derivative-free fixed-boundary optimization (Drevlak et al., Nucl. Fusion, vol. 59, 2018, 016010), we compute the local sensitivity of these metrics with respect to perturbations of the plasma boundary using the shape gradient (Landreman & Paul, Nucl. Fusion, vol. 58, 2018, 076023). We extend REGCOIL to compute derivatives of these metrics with respect to parameters describing the plasma boundary. In keeping with previous research on winding surface optimization (Paul et al., Nucl. Fusion, vol. 58, 2018, 076015), the shape derivatives are computed with a discrete adjoint method. In contrast with the previous work, derivatives are computed with respect to the plasma surface parameters rather than the winding surface parameters. To further reduce the resolution required to compute the shape gradient, we present a more efficient representation of the plasma surface which uses a single Fourier series to describe the radial distance from a coordinate axis and a spectrally condensed poloidal angle. This representation is advantageous over the standard cylindrical representation used in the VMEC code (Hirshman & Whitson, Phys. Fluids, vol. 26, 1983, pp. 3553–3568), as it provides a uniquely defined poloidal angle, eliminating a null space in the optimization of the plasma surface. In comparison with previous spectral condensation methods (Hirshman & Breslau, Phys. Plasmas, vol. 5, 1998, p. 2664), the modified poloidal angle is obtained algebraically rather than through the solution of a nonlinear optimization problem. The resulting shape gradient highlights features of the plasma boundary that are consistent with simple coils and can be used to couple coil and fixed-boundary optimization.

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On the Levi-flat Plateau problem

Complex Analysis and its Synergies ◽

10.1007/s40627-019-0040-6 ◽

2020 ◽

Vol 6 (1) ◽

Author(s):

Jiří Lebl ◽

Alan Noell ◽

Sivaguru Ravisankar

Keyword(s):

Plateau Problem ◽

Flat Plateau

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Higher differentiability results for solutions to a class of non-autonomous obstacle problems with sub-quadratic growth conditions

Forum Mathematicum ◽

10.1515/forum-2020-0299 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Andrea Gentile

Keyword(s):

Besov Space ◽

Lipschitz Space ◽

Growth Conditions ◽

Obstacle Problems ◽

Quadratic Growth ◽

Regularity Assumption ◽

Lipschitz Regularity ◽

Fixed Boundary ◽

Higher Differentiability ◽

Admissible Functions

Abstract We establish some higher differentiability results of integer and fractional order for solutions to non-autonomous obstacle problems of the form min ⁡ { ∫ Ω f ⁢ ( x , D ⁢ v ⁢ ( x ) ) : v ∈ K ψ ⁢ ( Ω ) } , \min\biggl{\{}\int_{\Omega}f(x,Dv(x)):v\in\mathcal{K}_{\psi}(\Omega)\biggr{\}}, where the function 𝑓 satisfies 𝑝-growth conditions with respect to the gradient variable, for 1 < p < 2 1<p<2 , and K ψ ⁢ ( Ω ) \mathcal{K}_{\psi}(\Omega) is the class of admissible functions v ∈ u 0 + W 0 1 , p ⁢ ( Ω ) v\in u_{0}+W^{1,p}_{0}(\Omega) such that v ≥ ψ v\geq\psi a.e. in Ω, where u 0 ∈ W 1 , p ⁢ ( Ω ) u_{0}\in W^{1,p}(\Omega) is a fixed boundary datum. Here we show that a Sobolev or Besov–Lipschitz regularity assumption on the gradient of the obstacle 𝜓 transfers to the gradient of the solution, provided the partial map x ↦ D ξ ⁢ f ⁢ ( x , ξ ) x\mapsto D_{\xi}f(x,\xi) belongs to a suitable Sobolev or Besov space. The novelty here is that we deal with sub-quadratic growth conditions with respect to the gradient variable, i.e. f ⁢ ( x , ξ ) ≈ a ⁢ ( x ) ⁢ | ξ | p f(x,\xi)\approx a(x)\lvert\xi\rvert^{p} with 1 < p < 2 1<p<2 , and where the map 𝑎 belongs to a Sobolev or Besov–Lipschitz space.

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A new time-delayed periodic boundary condition for discrete element modelling of railway track under moving wheel loads

Granular Matter ◽

10.1007/s10035-021-01123-4 ◽

2021 ◽

Vol 23 (4) ◽

Author(s):

Huiqi Li ◽

Glenn McDowell ◽

John de Bono

Keyword(s):

Boundary Condition ◽

Periodic Boundary Condition ◽

Periodic Boundary ◽

Discrete Element ◽

Contact Forces ◽

Railway Track ◽

Discrete Element Modelling ◽

Fixed Boundary ◽

Element Modelling ◽

New Time

Abstract A new time-delayed periodic boundary condition (PBC) has been proposed for discrete element modelling (DEM) of periodic structures subject to moving loads such as railway track based on a box test which is normally used as an element testing model. The new proposed time-delayed PBC is approached by predicting forces acting on ghost particles with the consideration of different loading phases for adjacent sleepers whereas a normal PBC simply gives the ghost particles the same contact forces as the original particles. By comparing the sleeper in a single sleeper test with a fixed boundary, a normal periodic boundary and the newly proposed time-delayed PBC (TDPBC), the new TDPBC was found to produce the closest settlement to that of the middle sleeper in a three-sleeper test which was assumed to be free of boundary effects. It appears that the new TDPBC can eliminate the boundary effect more effectively than either a fixed boundary or a normal periodic cell. Graphic abstract

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Carbon- and Oxygen-Rich Progenitors of Planetary Nebulae

Symposium - International Astronomical Union ◽

10.1017/s0074180900170962 ◽

1993 ◽

Vol 155 ◽

pp. 243-250 ◽

Cited By ~ 2

Author(s):

H.J. Habing ◽

J.A.D.L. Blommaert

Keyword(s):

Planetary Nebulae ◽

Asymptotic Giant Branch ◽

Spectral Class ◽

Class C

This review concerns stars on the Asymptotic Giant Branch that are about to develop into planetary nebulae (=PNe). They are still termed “stars”, and properly so, and yet they have already, in statu nascendi, the structure of a PN. There are two different kinds: oxygen-rich stars (spectral class: M) and carbon-rich stars (spectral class: C).

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