Some characterizations of BMO and Lipschitz spaces in the Schr\"odinger setting
Abstract
We consider the Schr\"odinger operator L=-+V on Rd, d≥3, where the nonnegative potential V belongs to the reverse H\"older class RHs for some s≥ d/2. A real-valued function f∈ L1loc( Rd) belongs to the (BMO) space BMO,θ( Rd) with 0<θ<∞ if equation* \|f\|BMO,θ :=B(x0,r)(1+r(x0))-θ(1|B(x0,r)|∫B(x0,r)|f(x)-fB|\,dx), equation* where the supremum is taken over all balls B(x0,r)⊂ Rd, (·) is the critical radius function in the Schr\"odinger context and equation* fB:=1|B(x0,r)|∫B(x0,r)f(y)\,dy. equation* A real-valued function f∈ L1loc( Rd) belongs to the (Lipschitz) space Lipβ,θ( Rd) with 0<β<1 and 0<θ<∞ if equation* \|f\|Lipβ,θ :=B(x0,r)(1+r(x0))-θ (1|B(x0,r)|1+β/d∫B(x0,r)|f(x)-fB|\,dx). equation* It can be easily seen that BMO,θ( Rd) (or Lipβ,θ( Rd)) is a function space which is larger than the classical BMO (or Lipschitz) space. In this paper, we give some new characterizations of BMO and Lipschitz spaces associated with the Schr\"odinger operator L. We extend some previous works of Bongioanni--Harboure--Salinas and Liu--Sheng to the weighted case. The classes of weights considered here are larger than the classical Muckenhoupt classes.
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