3503 , ð* ¬=@? ' < b ? Ë È ¸Áp pjg o Û ú,jg o c z ? ð ËÛ ú Æ&- v Ö* ]...
TRANSCRIPT
501
2014 2 12
1
ADD
[1]
2
GN = 6.67384(80)×10 11 m3 (kg s2 ) PDG2013 10 4
universality
charge
1 [2]
r
1
11
20 [3]
10 10
V = GN
Mmr
1+ e r( )
233
502
>1
10
20
3
(ADD: Alkani-Hamed DimopoulosDvali) [1]
1ADD
1mm
ADD
r
>1
1mm ADD
TeV
d = 2 5
= 0.1mm
1
5
2[4]
ADD
1TeV
E4+dpl = 1032 19d m
d1
2+d
TeV
2 [4]
=E4+d
pl
TeV
2d
1
×1032d
19m
ADD
LHC
MD > 2.3TeV ( d = 2
) 5
< 92 m [5] 2007
< 44 m
MD > 3.2TeV d = 2 [6]
TeV
3
d = 2
VADD =GN
Mmr
(r > )
GNd Mm
r1+d(r < )
234
503
3 ADD [4]
mm
TeV
4
BNL RHIC PHENIX
100
1999 25
4 CCD
4 PHENIX Optical Alignment System [7]
50nm [7]
1
CCD
ADD
2003
10
5 Target
Attractor
5
2003
235
504
6 Attractor Source Mass
10nN
1nm
6 2003
Attractor Attractor
6
Attractor
5 Newton
1
Newton-Icm
3-4
Newton-I 7
1 10 6 rad
30
cm
PC
7 Newton Newton-I
Newton-I 8
Attractor
10%
8 Newton-I
236
505
Attractor
20064
Attractor Target
%
Attractor
9
cm
statement [8]
9 Newton-I
10%
Newton-SCKEK
10 Newton-SC
FPGA
11
45mm 85mm 1%
<10 2 cm
11
[9]
10 Newton-SC
11 Newton-SC
6
Attractor
cm
10 13 [10]
cm
Newton-IIAttractor
237
506
12 Newton-I
4 Attractor
12 Newton-II
Newton-I Attractor
13 Newton-II [9]
13 Newton-IIAttractor
1cm
[9] GAl W
GCu W
Target
7
Newton-I SC II
Newton-SC <10 2
<10 3
0.1%
100
1000 1 10
1mm
Newton-III
100
Newton-III
Newton-IV
cm Target Attractor mmGAl WGCu W
1= 0.9±1.1sta ± 4.8sys( )×10 2
GCu WGN
1= 0.2± 0.9sta ± 2.1sys( )×10 2
238
507
Newton-IV
1 10 8 rad
14 Newton-IVh
Newton-IV 1mm
0.8mm 2.8mm
50
2mm 3mm 5mm
Newton-II
2013 Newton-IVh 14
2013 12
1mm <10 1
[11] 15
2
10% 1%
15 Newton-IVh [11]
10%
Newton-IVh
AttractorAttractor
2014
16 Newton-IVh 2014 collaboration
Newton-IVh
100 10 10%
16
SpokespersonTRIUMF MTV
8Li[12] 2011
239
508
ADD
MTV-G17
geodetic precessionMTV
8Li-18
[13] 19
17 MTV-G
18 MTV-G
19 [14]
19 (preliminary)
8
[15]
[1] N. Arkani-Hamed S. Dimopoulos G. Dvali Phys.
Lett. B 429 (1998) 263-272.
[2] E. Fischbach and C. Talmadge “The Search for
Non-Newtonian Gravity” Springer (1999).
[3] J. O. Dickey et al. Science 265 (1994) 482.
[4] ,
(2011).
[5] ATLAS Collaboration Phys. Lett. B 705 (2011)
294-312.
[6] D. J. Kapner et al. Phys. Rev. Lett. 98 (2007)
021101.
[7] J. Murata et al. NIM A 500 (2003) 309; J. Murata et al. IEEE Nucl. Sci. CR675 (2005).
[8] M. Hata et al. J. Phys. CS 189 (2009) 012019;
K. Ninomiya et al. J. Phys. CS 189 (2009) 012026.
[9] K. Ninomiya et al. J. Phys. CS 453 (2013) 012007.
[10] S. Schlamminger et al. Phys. Rev. Lett. 100 (2008)
41101.
[11] (2014).
[12] J. Murata et al. Hyperfine Interact 225 (2014)
193-196.
[13] S. Tanaka et al. J. Phys. CS 453 (2013) 012018;
(2014).
[14] CODATA2010; M. Hori et al. Nature 476 (2011) 484.
[15] 1 (2013); Newton 7 (2013);
BS X 3
(2013 10 13 )
240