Southern hemispheric data (1978-1998) on four halons are reported. Halon-de
rived bromine increased by a factor of 10 from 0.6-0.7 parts per trillion (
ppt) in 1978 to more than 7 ppt in early 1998, currently growing at 3% yr(-
1). In 1997 the mixing ratios were 4.0 (CBrClF2, H-1211)? 2.1 (CBrF3, H-130
1), 0.4 (CBrF2CBrF2, H-2402), and 0.04 ppt (CBr2F2, H-1202), contributing s
imilar to 60, 30, 10 and 1% respectively to halon-derived bromine (40% of b
ackground tropospheric bromine). The halons exhibit different growth patter
ns: CBrClF2 continues linearly (0.20 ppt yr(-1)), CBrF3 slows significantly
(0.03 ppt yr(-1), early 1998), CBrF2CBrF2 stops and CBr2F2 increases (17%
yr(-1) in early 1998). CBr2F2 shows a photochemically driven annual cycle.
CBrClF2 and CBrF3 emissions (1963-2100) have been estimated from past and f
uture production figures, in developed and developing countries, and from r
elease estimates from the various halon banks. Mixing ratios have been calc
ulated from a two-dimensional model incorporating seasonal transport and ha
lon photochemistry and a latitudinal source function. The model-derived atm
ospheric lifetimes are 17 (CBrCIF2), 62 (CBrF3), 20 (CBrF2CBrF2), and 2.9 (
CBr2F2) years. Calculated and measured mixing ratios of CBrF3 agree reasona
bly but not for CBrCIF2 in recent years. The model has been used to derive
independently halon emissions that are consistent with the observed atmosph
eric trends. The continued growth of CBrCIF2 in the background atmosphere c
ould be due to enhanced production and emission in the Peoples' Republic of
China, which may also explain the recent acceleration in growth of CBr2F2,
a by-product of CBrClF2 manufacture. The recent atmospheric growth of CBr2
F2 may also be due to increased direct usage. The expected long-term recove
ry of stratospheric ozone could be delayed if the current halon growth cont
inues into the next decade.