TY - JOUR
T1 - Brownian Motion Penetrating Fractals
T2 - An Application of the Trace Theorem of Besov Spaces
AU - Kumagai, Takashi
N1 - Funding Information:
1Research partly supported by JSPS program.
PY - 2000/1/10
Y1 - 2000/1/10
N2 - For a closed connected set F in Rn, assume that there is a local regular Dirichlet form (a symmetric diffusion process) on F whose domain is included in a Lipschitz space or a Besov space on F. Under some condition for the order of the space and the Newtonian 1-capacity of F, we prove that there exists a symmetric diffusion process on Rn which moves like the process on F and like Brownian motion on Rn outside F. As an application, we will show that when F is a nested fractal or a Sierpinski carpet whose Hausdorff dimension is greater than n-2, we can construct Brownian motion penetrating the fractal. For the proof, we apply the technique developed in the theory of Besov spaces.
AB - For a closed connected set F in Rn, assume that there is a local regular Dirichlet form (a symmetric diffusion process) on F whose domain is included in a Lipschitz space or a Besov space on F. Under some condition for the order of the space and the Newtonian 1-capacity of F, we prove that there exists a symmetric diffusion process on Rn which moves like the process on F and like Brownian motion on Rn outside F. As an application, we will show that when F is a nested fractal or a Sierpinski carpet whose Hausdorff dimension is greater than n-2, we can construct Brownian motion penetrating the fractal. For the proof, we apply the technique developed in the theory of Besov spaces.
KW - Lipschitz space; Besov space; capacity; trace theorem; Dirichlet form; diffusions on fractals
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U2 - 10.1006/jfan.1999.3500
DO - 10.1006/jfan.1999.3500
M3 - Article
AN - SCOPUS:0002217726
SN - 0022-1236
VL - 170
SP - 69
EP - 92
JO - Journal of Functional Analysis
JF - Journal of Functional Analysis
IS - 1
ER -