Modeling electrostatic patch effects in Casimir force measurements

被引：65

作者：

Behunin, R. O. ^{[1
,2
]}

Intravaia, F. ^{[1
]}

Dalvit, D. A. R. ^{[1
]}

Maia Neto, P. A. ^{[3
]}

Reynaud, S. ^{[4
]}

机构：

[1] Los Alamos Natl Lab, Div Theoret, Los Alamos, NM 87545 USA

[2] Univ Fed Rio de Janeiro, Ctr Nonlinear Studies, BR-21941972 Rio de Janeiro, Brazil

[3] Univ Fed Rio de Janeiro, Inst Fis, BR-21941972 Rio de Janeiro, Brazil

[4] UPMC, CNRS, ENS, Lab Kastler Brossel, F-75252 Paris, France

来源：

PHYSICAL REVIEW A | 2012年 / 85卷 / 01期

关键词：

QUANTITATIVE MEASUREMENT;

D O I：

10.1103/PhysRevA.85.012504

中图分类号：

O43 [光学];

学科分类号：

070207 ; 0803 ;

摘要：

Electrostatic patch potentials give rise to forces between neutral conductors at distances in the micrometer range and must be accounted for in the analysis of Casimir force experiments. In this paper we develop a quasilocal model for describing random potentials on metallic surfaces. In contrast to some previously published results, we find that patches may provide a significant contribution to the measured signal and thus may be a more important systematic effect than was previously anticipated. Additionally, patches may render the experimental data at distances below 1 mu m compatible with theoretical predictions based on the Drude model.

引用

页数：9

共 51 条

[1] Torsion balance experiments: A low-energy frontier of particle physics [J].

Adelberger, E. G. ;

Gundlach, J. H. ;

Heckel, B. R. ;

Hoedl, S. ;

Schlamminger, S. .

PROGRESS IN PARTICLE AND NUCLEAR PHYSICS, VOL 62, NO 1, 2009, 62 (01) :102-134

[2] Tests of the gravitational inverse-square law [J].

Adelberger, EG ;

Heckel, BR ;

Nelson, AE .

ANNUAL REVIEW OF NUCLEAR AND PARTICLE SCIENCE, 2003, 53 :77-121

[3] Short-range fundamental forces [J].

Antoniadis, I. ;

Baessler, S. ;

Buechner, M. ;

Fedorov, V. V. ;

Hoedl, S. ;

Lambrecht, A. ;

Nesvizhevsky, V. V. ;

Pignol, G. ;

Protasov, K. V. ;

Reynaud, S. ;

Sobolev, Yu. .

COMPTES RENDUS PHYSIQUE, 2011, 12 (08) :755-778

[4] An experimental apparatus for measuring the Casimir effect at large distances [J].

Antonini, P. ;

Bimonte, G. ;

Bressi, G. ;

Carugno, G. ;

Galeazzi, G. ;

Messineo, G. ;

Ruoso, G. .

60 YEARS OF THE CASIMIR EFFECT, 2009, 161

[5]

Bordag M., 2009, Advances in the Casimir Effect

[6] Measurement of the Casimir force between parallel metallic surfaces [J].

Bressi, G ;

Carugno, G ;

Onofrio, R ;

Ruoso, G .

PHYSICAL REVIEW LETTERS, 2002, 88 (04) :4

[7] MACROSCOPIC VARIATIONS OF SURFACE-POTENTIALS OF CONDUCTORS [J].

CAMP, JB ;

DARLING, TW ;

BROWN, RE .

JOURNAL OF APPLIED PHYSICS, 1991, 69 (10) :7126-7129

[8] Energy shifts of Rydberg atoms due to patch fields near metal surfaces [J].

Carter, J. D. ;

Martin, J. D. D. .

PHYSICAL REVIEW A, 2011, 83 (03)

[9]

Casimir H., 1948, Proc. K. Ned. Akad. Wet, V51, P793, DOI DOI 10.4236/WJNSE.2015.52007

[10] Nonlinear micromechanical Casimir oscillator [J].

Chan, HB ;

Aksyuk, VA ;

Kleiman, RN ;

Bishop, DJ ;

Capasso, F .

PHYSICAL REVIEW LETTERS, 2001, 87 (21) :211801-1

← 1 2 3 4 5 6 →