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1.
O. A. Tarasova C. A. M. Brenninkmeijer S. S. Assonov N. F. Elansky T. Röckmann M. A. Sofiev 《Journal of Atmospheric Chemistry》2007,57(2):135-152
The concentration, radiocarbon (14C) and stable isotope (13C and 18O) content of CO have been determined in air samples collected across Russia (about 8,500 km) and along the Ob river during
the summer of 1999 to study the CO sources and sinks. An instrumented carriage on the Trans-Siberian railway and a boat on
the river Ob were used as atmospheric measurement platforms. In general, CO mixing ratios, CO stable isotope ratios, as well
as the abundances of 14CO over West Siberia were similar to those found at remote northern hemispheric baseline monitoring stations. Identified sources
of CO along the Ob appear to be connected to methane oxidation based on an inferred δ13Csource = −36.8 ± 0.6‰, while the value for δ18Osource = 9.0 ± 1.6‰ identifies it as burning. Thus flaring in the oil and gas production can be supposed to be a source. The extreme
13C depletion and concomitant 18O enrichment for two of the boat samples unambiguously indicates contamination by CO from combustion of natural gas (inferred
values δ13Csource = −40.3‰ and δ18Osource = 17.5‰). For these two samples, that have strongly elevated 14CO concentrations, the industrial area near Tomsk is identified as a source area using meteorological calculations. Along
the Trans-Siberian Railroad background CO was to various degrees contaminated with CO from methane combustion (δ13Csource = −35.7 ± 6.2‰ and δ18Osource = 10.3 ± 1.8‰). The impact of industrial burning was discernable in the vicinity of Perm-Kungur. 相似文献
2.
Stable carbon isotopic composition of ethane and propane over the western North Pacific and eastern Indian Ocean between 31°N
and 26°S was investigated from February through March 2004. The isotopic composition of ethane ranged from −28 to −18‰ and
showed a gradual increase from north to south. Conversely, that of propane was between −31 and −24‰; it showed no systematic
latitudinal variation. Investigation of the ethane/propane ratio indicates that ethane and propane that originated from northern
mid-latitude countries in the eastern part of Eurasia were both transported into the western North Pacific region. However,
the results of the isotopic analyses indicate the contribution of oceanic emission to the atmospheric propane during transport,
although that contribution can not be discerned for ethane. A ship based stationary observation conducted in the western equatorial
North Pacific showed that the isotopic composition of ethane varied from −25 to −19‰ and showed clear systematic diurnal variation:
propane ranged between −32 to −26‰ and no such isotopic diurnal signal was observed. The diurnal variation for ethane is explained
by entrainment of free tropospheric air, whereas the variation for propane was influenced by oceanic emissions as well as
the entrainment. The contribution of oceanic emissions to the atmospheric propane inventory was considered from our isotopic
observation. Isotopic composition of dissolved propane is estimated to be less than −38‰, and the contribution up to 79% was
calculated when the isotopic composition of dissolved propane is assumed to be −40‰. Our study demonstrates that isotopic
analysis can be more useful than ratio-based analysis to improve our present understanding of transport processes, especially
for impact of the oceanic emissions on the atmospheric distribution of low level C2–C5 non-methane hydrocarbons such as propane in the remote marine atmosphere. 相似文献
3.
A. M. El-Asrag S. A. Al-Gamal A. Youssef D. M. Ahmed 《Theoretical and Applied Climatology》2003,74(3-4):191-202
Summary ?By analyzing normalized variables, it was found that the latitudinal secular variations of the rainwater deuterium fractionation
ratio δ2H, oxygen fractionation ratio δ18O, vapor pressure, and surface temperature were almost non-linear, occurred in parallel, and decreased with latitude. The
rate of depletion around the equator is asymmetric and smaller to the south of 45° S than to the north of 45° N. In the east
Mediterranean, the rate of change of δ18O with height was found to be −.2‰ per 100 m and that of δ2H is comparable with the dry lapse rate in the atmosphere.
Analysis of the annual time series of δ2H at Alexandria has indicated that variations show sinusoidal waveform with a major cycle of two years that accounts for 68%
of the total variance. Although the quasi-biannual cycle in the atmosphere has small amplitude in the lower layers of the
atmosphere at East Mediterranean latitudes, the major cycle in annual series of δ2H or δ18O may be linked to the quasi-biannual oscillation in the atmosphere.
It was also found that the first three Empirical Orthogonal Functions (EOF) account for 72% of the seasonal variation of δ2H and share 68% of the seasonal variation of δ18O. Share of variances of monthly EOF in the months of the year indicate that the main underlying factors that cause fractionation
processes for δ2H and δ18O are similar across the east Mediterranean especially in late winter and early spring.
Received May 13, 2002; revised July 8, 2002; accepted August 6, 2002 相似文献
4.
Summary. Mesoscale convective precipitation systems in the Alpine region are studied by analyzing radar and rain gauge data. The data
from weather radars in Austria, France, Germany, and Switzerland are combined into a composite. Availability of radar data
restricts the study mainly to the northern part of the Alpine region. Mesoscale convective systems (MCS) occur often in this
region and are comparable to large systems observed in the USA. Seven precipitation events lasting one to six days from the
years 1992–1996 are examined in detail. They all moved west to east and showed no diurnal preference in formation or dissipation.
They reach sizes of 2 − 6 · 104 km2. MCS with leading-line trailing-stratiform structure tended to be larger and more intense. A 25-year set of rain gauge data
indicates that a giant MCS (covering more than 4 · 104 km2 with more than 30 mm/day) occurs every 6 years in the northern Alpine region. MCS occur more frequently in the southern Alpine
region.
Received February 25, 1999/Revised June 29, 1999 相似文献
5.
Summary The west coast of the Indian peninsula receives very heavy rainfall during the summer Monsoon (June–September) season with
average rainfall over some parts exceeding 250 cm. Heavy rainfall events with rainfall more than 15 cm day−1 at one or more stations along the west coast of India occur frequently and cause considerable damage. A special observational
programme, Arabian Sea Monsoon Experiment, was carried out during the monsoon season of 2002 to study these events. The spatial
and temporal distributions of intense rainfall events, presented here, were used for the planning of this observational campaign.
The present study using daily rainfall data for summer monsoon season of 37 years (1951–1987) shows that the probability of
getting intense rainfall is the maximum between 14° N–16° N and near 19° N. The probability of occurrence of these intense
rainfall events is high from mid June to mid August, with a dip in early July. It has been believed for a long time that offshore
troughs and vortices are responsible for these intense rainfall events. However, analysis of the characteristics of cloud
systems associated with the intense rainfall events during 1985–1988 using very high resolution brightness temperature data
from INSAT-IB satellite shows that the cloud systems during these events are characterized by large spatial scales and high cloud tops.
Further study using daily satellite derived outgoing longwave radiation (OLR) data over a longer period (1975–1998) shows
that, most of these events (about 62%) are associated with systems organized on synoptic and larger scales. We find that most
of the offshore convective systems responsible for intense rainfall along the west coast of India are linked to the atmospheric
conditions over equatorial Indian Ocean. 相似文献
6.
R. García-Herrera D. Barriopedro E. Hernández D. Paredes J. F. Correoso L. Prieto 《Meteorology and Atmospheric Physics》2005,90(3-4):225-243
Summary This paper characterizes Mesoscale Convective Systems (MCSs) during 2001 over Iberia and the Balearic Islands and their meteorological
settings. Enhanced infrared Meteosat imagery has been used to detect their occurrence over the Western Mediterranean region
between June and December 2001 according to satellite-defined criteria based on the MCS physical characteristics.
Twelve MCSs have been identified. The results show that the occurrence of 2001 MCSs is limited to the August–October period,
with September being the most active period. They tend to develop during the late afternoon or early night, with preferred
eastern Iberian coast locations and eastward migrations. A cloud shield area of 50.000 km2 is rarely exceeded. When our results are compared with previous studies, it is possible to assert that though 2001 MCS activity
was moderate, the convective season was substantially less prolonged than usual, with shorter MCS life cycles and higher average
speeds. The average MCS precipitation rate was 3.3 mm·h−1 but a wide range of values varying from scarce precipitation to intense events of 130 mm·24 h−1 (6 September) were collected. The results suggest that, during 2001, MCS rainfall was the principal source of precipitation
in the Mediterranean region during the convective season, but its impact varied according to the location.
Synoptic analysis based on NCEP/NCAR reanalysis show that several common precursors could be identified over the Western Mediterranean
Sea when the 2001 MCSs occurred: a low-level tongue of moist air and precipitable water (PW) exceeding 25 mm through the southern
portion of the Western Mediterranean area, low-level zonal warm advection over 2 °C·24 h−1 towards eastern Iberia, a modest 1000–850 hPa equivalent potential temperature (θe) difference over 20 °C located close to the eastern Iberian coast, a mid level trough (sometimes a cut-off low) over Northern
Africa or Southern Spain and high levels geostrophic vorticity advection exceeding 12·10−10 s−2 over eastern Iberia and Northern Africa. Finally, the results suggest that synoptic, orographic and a warm-air advection
were the most relevant forcing mechanisms during 2001. 相似文献
7.
Jan Esper Lara Klippel Paul J. Krusic Oliver Konter Christoph C. Raible Elena Xoplaki J&#;rg Luterbacher Ulf B&#;ntgen 《Climate Dynamics》2020,54(3):1367-1382
The Mediterranean has been identified as particularly vulnerable to climate change, yet a high-resolution temperature reconstruction extending back into the Medieval Warm Period is still lacking. Here we present such a record from a high-elevation site on Mt. Smolikas in northern Greece, where some of Europe’s oldest trees provide evidence of warm season temperature variability back to 730 CE. The reconstruction is derived from 192 annually resolved, latewood density series from ancient living and relict Pinus heldreichii trees calibrating at r1911–2015 = 0.73 against regional July–September (JAS) temperatures. Although the recent 1985–2014 period was the warmest 30-year interval (JAS Twrt.1961–1990 = + 0.71 °C) since the eleventh century, temperatures during the ninth to tenth centuries were even warmer, including the warmest reconstructed 30-year period from 876–905 (+ 0.78 °C). These differences between warm periods are statistically insignificant though. Several distinct cold episodes punctuate the Little Ice Age, albeit the coldest 30-year period is centered during high medieval times from 997–1026 (− 1.63 °C). Comparison with reconstructions from the Alps and Scandinavia shows that a similar cold episode occurred in central Europe but was absent at northern latitudes. The reconstructions also reveal different millennial-scale temperature trends (NEur = − 0.73 °C/1000 years, CEur = − 0.13 °C, SEur = + 0.23 °C) potentially triggered by latitudinal changes in summer insolation due to orbital forcing. These features, the opposing millennial-scale temperature trends and the medieval multi-decadal cooling recorded in Central Europe and the Mediterranean, are not well captured in state-of-the-art climate model simulations. 相似文献
8.
Summary The possibility of climate change in the Korean Peninsula has been examined in view of the general increase in greenhouse
gases. Analyses include changes in annual temperature and precipitation. These analyses are supplemented with our observations
regarding the apparent decrease of forest areas.
It was found that there was a 0.96 °C (0.42 °C per decade) increase in annual mean temperature between 1974 and 1997. The
increase in large cities was 1.5 °C but only 0.58 °C at rural and marine stations. The difference in the mean temperature
between large cities and rural stations was small from 1974 to 1981. However, the difference increased from 1982 to 1997.
In particular, the warming appears most significant in winter. Prior to 1982, the lowest temperatures were often −18 °C in
central Korea, and since then the lowest temperatures have been only −12∼−14 °C. Recently, the minimum January temperature
has increased at a rate of 1.5 °C per decade. It is estimated that the increase of1 °C in annual mean temperature corresponds
to about a 250 km northward shift of the subtropical zone boundary.
The analysis of data from 1906 to 1997 indicates a trend of increasing annual precipitation, an increase of 182 mm during
the 92-year peirod, with large year-to-year variations. More than half of the annual mean amount, 1,274 mm, occurred from
June to September.
Meteorological data and satellite observations suggest that changes have occurred in the characteristics of the quasi-stationary
fronts that produce summer rain. In recent years scattered local heavy showers usually occur with an inactive showery front,
in comparison with the classical steady rain for more than three weeks. For instance, local heavy rainfall, on 6 August 1998
was in the range of 123–481 mm. The scattered convective storms resulted in flooding with a heavy toll of approx. 500 people.
The northward shift of the inactive showery front over Korea, and of a convergence zone in central China, correlate with the
increase in temperature. It has been suggested that the decrease in forest areas and the change in ground cover also contribute
to the warming of the Korean Peninsula.
Received March 16, 2000 相似文献
9.
Yang Zhao Deliang Chen Jiao Li Dandan Chen Yi Chang Juan Li Rui Qin 《Climate Dynamics》2020,54(5):2713-2730
This study investigates the roles of atmospheric moisture transport under the influence of topography for summer extreme precipitation over North China (NC) during 1979–2016. Based on rain gauge precipitation data and a reanalysis, 38 extreme precipitation days in NC during the 38 years were selected and associated moisture fluxes estimated. The results show that there is a dominant moisture influx of 311.8 kg m−1 s−1 into NC along its southern boundary from tropical oceans, and a secondary influx of 107.9 kg m−1 s−1 across its western boundary carried by mid-latitude westerlies. The outflux across the eastern boundary is 206.9 kg m−1 s−1 and across the northern boundary is 76.0 kg m−1 s−1, giving a net moisture gain over NC of 136.8 kg m−1 s−1. During extreme precipitation days, the moisture flux convergence (MFC) was much larger, exceeding 4 × 10−5 kg m−1 s−1. The MFC maximum core, the pronounced moisture transport, and the striking extreme precipitation zone over NC are all anchored to the east of the steep slopes of the surrounding topography. Moreover, a remarkably high humidity and strong upward motion also occur near steep slopes, indicating the critical role of the adjacent topography on the extreme precipitations. Simulations with and without the topography in NC using the Weather and Research Forecasting model for six selected out of the 38 extreme precipitation days demonstrate that the surrounding topography reinforces the MFC over NC by 16% relative to the case without terrain, primarily through enhanced wind convergence and higher moisture content, as well as stronger vertical motion induced by diabatic heating. The interactions between moisture convergence and topographic settings strengthen the extreme precipitation over NC. 相似文献
10.
Both aerosol and rainwater samples were collected and analyzed for ionic species at a coastal site in Southeast Asia over
a period of 9 months (January–September 2006) covering different monsoons. In general, the occurrence and distribution of
ionic species showed a distinct seasonal variation in response to changes in air mass origins. Real-time physical characterization
of aerosol particles during rain events showed changes in particle number distributions which were used to assess particle
removal processes associated with precipitation, or scavenging. The mean scavenging coefficients for particles in the range
10–500 nm and 500–10 μm were 7.0 × 10−5 ± 2.8 × 10−5 s−1 and 1.9 × 10−4 ± 1.6 × 10−5 s−1, respectively. A critical analysis of the scavenging coefficients obtained from this study suggested that the wet removal
of aerosol particles was greatly influenced by rain intensity, and was particle size-dependent as well. The scavenging ratios,
another parameter used to characterize particle removal processes by precipitation, for NH4
+, Cl−, SO4
2−, and NO3
− were found to be higher than those of Na+, K+, and Ca2+ of oceanic and crustal origins. This enrichment implied that gaseous species NH3, HCl, and HNO3 could also be washed out readily. These additional sources of ions in precipitation presumably counter-balanced the dilution
effect caused by high total precipitation volume in the marine and tropical area. 相似文献
11.
The spectral characteristics of the δ18O isotopic ratio time series of the Quelccaya ice cap summit core are investigated with the multi taper method (MTM), the
singular spectrum analysis (SSA) and the wavelet transform (WT) techniques for the 500 y long 1485–1984 period. The most significant
(at the 99.8% level) cycle according to the MTM F-test has a period centered at 14.4 y while the largest variance explaining
oscillation according to the SSA technique has a period centered at 12.9 y. The stability over time of these periods is investigated
by performing evolutive MTM and SSA on the 500 y long δ18O series with a 100 y wide moving window. It is shown that the cycles with largest amplitude and that the oscillations with
largest extracting variance have corresponding periods aggregated around 13.5 y that are very stable over the period between
1485 and 1984. The WT of the same isotopic time series reveals the existence of a main oscillation around 12 y which are also
very stable in time. The relation between the isotopic data at Quelccaya and the annual sea surface temperature (SST) field
anomalies is then evaluated for the overlapping 1919–1984 period. Significant global correlation and significant coherency
at 12.1 y are found between the isotopic series and the annual global sea surface temperature (GSST) series. Moreover, the
correlation between the low (over 8 y) frequency component of the isotopic time series and the annual SST field point out
significant values in the tropical North Atlantic. This region is characterized by a main SST variability at 12.8 y. The Quelccaya
δ18O isotopic ratio series may therefore be considered as a good recorder of the tropical North Atlantic SSTs. This may be explained
by the following mechanism: the water vapor amount evaporated by the tropical North Atlantic is function of the SST. So is
the water vapor δ18O isotopic ratio. This water vapor is advected during the rainy season by northeast winds and precipitates at the Quelccaya
summit with its tropical North Atlantic isotopic signature. It is also suggested from this described stability of the decadal
time scale variability observed in the Quelccaya isotopic series, that the decadal time scale GSST variability was also stable
during the last five centuries.
Received: 12 February 1997 / Accepted: 9 September 1997 相似文献
12.
T. J. Griffis J. Zhang J. M. Baker N. Kljun K. Billmark 《Boundary-Layer Meteorology》2007,123(2):295-316
In recent years considerable effort has been focused on combining micrometeorological and stable isotope techniques to partition
net fluxes and to study biosphere–atmosphere exchange processes. While much progress has been achieved over the last decade,
some new issues are beginning to emerge as technological advances, such as laser spectroscopy, permit isotopic fluxes to be
measured more easily and continuously in the field. Traditional investigations have quantified the isotopic composition of
biosphere-atmosphere exchange by using the Keeling two-member mixing model (the classic Keeling plot). An alternative method,
based on a new capacity to measure isotopic mixing ratios, is to determine the isotope composition of biosphere–atmosphere
exchange from the ratio of flux measurements. The objective of this study was to critically evaluate these methods for quantifying
the isotopic composition of ecosystem respiration (δR) over a period of three growing seasons (2003–2005) within a heterogeneous landscape consisting of C3 and C4 species. For C4 canopies, the mixing model approach produced δR values that were 4–6‰ lower (isotopically lighter) than the flux-gradient method. The analyses presented here strongly suggest
that differences between flux and concentration footprint functions are the main factor influencing the inequality between
the mixing model and flux-gradient approaches. A mixing model approach, which is based on the concentration footprint, can
have a source area influence more than 20-fold greater than the flux footprint. These results highlight the fact that isotopic
flux partitioning is susceptible to problems arising from combining signals (concentration and fluxes) that represent very
different spatial scales (footprint). This problem is likely to be most pronounced within heterogeneous terrain. However,
even under ideal conditions, the mismatch between concentration and flux footprints could have a detrimental impact on isotopic
flux partitioning where very small differences in isotopic signals must be resolved. 相似文献
13.
We carried out simultaneous measurements of drop size distribution (DSD) and stable oxygen and hydrogen isotopic compositions (??18O and ??D) of rain at the National Atmospheric Research Laboratory (NARL), Gadanki (13.5°N, 79.2°E), southern India, during September?COctober 2006, with the aim of understanding microphysical processes leading to rain formation. The MST radar at NARL was operated continuously during rain events, while rain samples were collected at very short time intervals (<1?h), to capture small changes (>0.2?? and >2??) in their ??18O and ??D. The slope of the local meteoric water line (??D?C??18O line), was 8.07?±?0.47, similar to that of global meteoric water line, confirming that the precipitation occurred under isotopic equilibrium, and was unaffected by some anomalous process; further, the evaporation of rain drops at the cloud base was insignificant. Whenever the isotopic variations were larger during a rain event (>2??) there was a significant negative correlation between the ??18O and DSD. The possible explanation is that larger drops are mostly associated with convective rather than stratiform rain, and 18O (and D) depletion in convective rain is relatively more. Bin-resolved microphysical models incorporating water isotopologues could benefit by considering drop size spectra, which could improve the match with stable isotope observations of precipitation. 相似文献
14.
J. Martinez-FrÍAs A. Delgado M. MillÁN E. Reyes F. Rull D. Travis R. Garcia F. LÓPez-Vera J. A. RodrÍGuez-Losada J. A. Martin-Rubi J. Raya E. Santoyo 《Journal of Atmospheric Chemistry》2005,52(2):185-202
Specific studies about the stable isotope composition (18O/16O and D/H) of atmospheric icy conglomerations are still scarce. The present work offers, for the first time, a very detailed
analysis of oxygen and hydrogen isotopic signatures of unusually large ice conglomerations, or “megacryometeors”, that fell
to the ground in Spain during January 2000. The hydrochemical analysis is based on the bulk isotopic composition and systematic
selective sampling (deuterium isotopic mapping) of eleven selected specimens. δ18O and δD (V-SMOW) of all samples fall into the Meteoric Water Line matching well with typical tropospheric values. The distribution
of the samples on Craig's line suggests either a variation in condensation temperature and/or different residual fractions
of water vapour (Rayleigh processes). Three of the largest megacryometeors exhibited unequivocally distinctive negative values
(δ18O = −17.2%0 and δD = −127 %0 V-SMOW), (δ18O = −15.6%0 and δD = −112%0 V-SMOW) and (δ18O = −14.4%0 and δD = −100%0 V-SMOW), suggesting an atmospheric origin typical of the upper troposphere. Theoretical calculations indicate that the vertical
trajectory of growth was lower than 3.2 km. During the period in which the fall of megacryometeors occurred, anomalous atmospheric
conditions were observed to exist: a substantial lowering of the tropopause with a deep layer of saturated air below, ozone
depression and strong wind shear. Moreover, these large ice conglomerations occurred during non-thunderstorm conditions, suggesting
an alternative process of ice growth was responsible for their formation. 相似文献
15.
Aerosol and rain samples were collected between 48°N and 55°S during the KH-08-2 and MR08-06 cruises conducted over the North
and South Pacific Ocean in 2008 and 2009, to estimate dry and wet deposition fluxes of atmospheric inorganic nitrogen (N).
Inorganic N in aerosols was composed of ~68% NH4+ and ~32% NO3– (median values for all data), with ~81% and ~45% of each species being present on fine mode aerosol, respectively. Concentrations
of NH4+ and NO3− in rainwater ranged from 1.7–55 μmol L−1 and 0.16–18 μmol L−1, respectively, accounting for ~87% by NH4+ and ~13% by NO3− of total inorganic N (median values for all data). A significant correlation (r = 0.74, p < 0.05, n = 10) between NH4+ and methanesulfonic acid (MSA) was found in rainwater samples collected over the South Pacific, whereas no significant correlations
were found between NH4+ and MSA in rainwater collected over the subarctic (r = 0.42, p > 0.1, n = 6) and subtropical (r = 0.33, p > 0.5, n = 6) western North Pacific, suggesting that emissions of ammonia (NH3) by marine biological activity from the ocean could become a significant source of NH4+ over the South Pacific. While NO3− was the dominant inorganic N species in dry deposition, inorganic N supplied to surface waters by wet deposition was predominantly
by NH4+ (42–99% of the wet deposition fluxes for total inorganic N). We estimated mean total (dry + wet) deposition fluxes of atmospheric
total inorganic N in the Pacific Ocean to be 32–64 μmol m−2 d−1, with 66–99% of this by wet deposition, indicating that wet deposition plays a more important role in the supply of atmospheric
inorganic N than dry deposition. 相似文献
16.
Qinghai Lake, China, is located near the northern limit of the East Asian summer monsoon (EASM) and thus is an ideal region for studies of past monsoonal changes. However, isotope records from this region reflect the combined effects of multiple climatic factors, and make climatic interpretations difficult. The authors use multi-proxy records, generated from the same sediment core from Qinghai Lake, to disentangle these multiple effects in isotope records and to infer EASM variability during the late Holocene. Records of leaf wax (C2s) δD, lake carbonate 5180 and the Dunde ice core δ18O all indicate a millennial-scale depletion of mean isotopic values at -1500-1250 years before present. Compared with independent lake temperature and salinity records, the authors suggest that this depletion of long-term mean isotopic values must have resulted from changes in moisture sources in this region. In contrast, the authors attribute high-frequency (centennial timescale) C2s δD and ice core δ18O variability dominantly to a temperature effect. The multiproxy records provide a coherent picture in that many aspects of this regional climate (temperature, dryness, and moisture source) are strongly linked to the EASM variability. 相似文献
17.
A stable oxygen, but not carbon, isotope chronology of Callitris columellaris reflects recent climate change in north-western Australia 总被引:1,自引:0,他引:1
We investigated the dendroclimatic potential of stable carbon (δ13C) and oxygen (δ18O) abundances in tree rings of Callitris columellaris F. Muell. Tree-ring chronologies were constructed from the central Pilbara, north-western Australia and span 1919–1999. Variation
in δ18O was more strongly related to climate than δ13C; ecological and physiological factors may have dampened the climate signal in the δ13C chronology. Tree-ring δ18O was most strongly correlated with relative humidity (RH) and rainfall (r = −0.36 and −0.39) of the wettest months of the summer period, January and February. The correlation with RH reflects its
effect on evaporative enrichment of leaf water. However, tree-ring δ18O may also partly reflect the variability in 18O signatures of rainfall, which are influenced by the amount of rainfall and atmospheric humidity. From the δ18O chronology, we inferred that from 1919 to 1955 summers were relatively dry and warm, but since 1955, summers in the Pilbara
region have become increasingly cooler and more humid. Since 1980, conditions have been the wettest and coolest of the last
80 years. These inferred changes in climate correspond to a measured increase in rainfall since 1980 in north-western Australia
associated with a greater intensity of tropical cyclones. We conclude that δ18O abundances in tree rings of C. columellaris have significant potential for reconstructing the climate of semi-arid Australia, a region for which observational climate
records are sparse. 相似文献
18.
A Simulation Study on the Characteristics of Cloud Microphysics of
Heavy Rainfall in the Meiyu Front 
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下载免费PDF全文 A heavy rainfall in the Meiyu front during 4--5 July 2003 is simulated by use of the non-hydrostatic mesoscale model MM5 (V3--6) with different explicit cloud microphysical parameterization schemes. The characteristics of microphysical process of convective cloud are studied by the model outputs. The
simulation study reveals that: (1) The mesoscale model MM5 with explicit cloud microphysical process is capable of simulating the instant heavy rainfall in the Meiyu front, the rainfall simulation
could be improved significantly as the model resolution is increased, and the Goddard scheme is better than the Reisner or Schultz scheme. (2) The convective cloud in the Meiyu front has a
comprehensive structure composed of solid, liquid and vapor phases of water, the mass density of water vapor is the largest one in the cloud; the next one is graupel, while those of ice, snow, rain
water and the cloud water are almost same. The height at which mass density peaks for different hydrometeors is almost unchangeable during the heavy rainfall period. The mass density variation of rain water, ice, and graupel are consistent with that of ground precipitation, while that of water vapor in the low levels is 1--2 h earlier than the precipitation. (3) The main contribution to the water vapor budget in the atmosphere is the convergence of vapor flux through advection and convection, which provides the main vapor source of the rainfall. Besides the basic process of the auto-conversion of cloud water to rain water, there is an additional cloud microphysical process that is essential to the formation of instant heavy rainfall, the ice-phase crystals are transformed into graupels first and then the increased graupels mix with cloud water and accelerates the conversion of cloud water to rain water. The positive feedback mechanism between latent heat release and convection is the main cause to maintain and develop the heavy precipitation. 相似文献
19.
Diurnal phase of late-night against late-afternoon of stratiform and convective precipitation in summer southern contiguous China 总被引:7,自引:0,他引:7
Using the tropical rainfall measuring mission (TRMM) Precipitation Radar (PR) observations combined with the surface rain
gauge data during 1998–2006, the robust diurnal features of summer stratiform and convective precipitation over the southern
contiguous China are revealed by exploring the diurnal variations of rain rate and precipitation profile. The precipitation
over the southern contiguous China exhibits two distinguishing diurnal phases: late-night (2200–0600 LST) and late-afternoon
(1400–2200 LST), dependent on the location, precipitation type and duration time. Generally, the maximum rain rate and the
highest profile of stratiform precipitation occur in the late-afternoon (late-night) over the southeastern (southwestern)
China, while most of the stratiform short-duration rain rate tends to present late-afternoon peaks over the southern China.
For convective precipitation, the maximum rain rate and the highest profile occur in the late-afternoon over most of the southern
contiguous China, while the convective long-duration rain rate exhibits late-night peaks over the southwestern China. Without
regional dependence, the convective precipitation exhibits much larger amplitude of diurnal variations in both near surface
rain rate and vertical extension compared with stratiform precipitation and the convective rain top rises most rapidly between
noon and afternoon. However, there are two distinctive sub-regions. The diurnal phases of precipitation there are very weakly
dependent on precipitation type and duration time. Over the eastern periphery of the Tibetan Plateau, the maximum rain rate
and the highest profile of either convective or stratiform precipitation occur in the late-night. Over the southeastern coastal
regions, both the near surface rain rate and rain top of convective and stratiform precipitation peak in the late-afternoon. 相似文献
20.
The paper presents the importance of the Nocturnal Boundary Layer in driving the diurnal variability of the atmospheric CO2 mixing ratio and the carbon isotope ratio at ground level from an urban station in India. Our observations are the first
of their kind from this region. The atmospheric CO2 mixing ratio and the carbon isotopic ratio were measured for both the morning (05:30–07:30 IST) and afternoon time (16:00–18:00
IST) air samples at 5 m above ground level in Bangalore city, Karnataka State (12° 58′ N, 77° 38′ E, masl = 920 m) for a 10 day
period during the winter of 2008. We observed a change of ~7% the in CO2 mixing ratio between the morning and afternoon time air samples. A stable isotope analysis of CO2 from morning samples showed a depletion in the carbon isotope ratio by ~2‰ compared to the afternoon samples. Along with
the ground-based measurement of air samples, data of radiosonde measurements were also obtained from the Indian Meteorological
Department to identify the vertical atmospheric structure at different time in a day. We proposed the presence or absence
of the NBL as a controlling factor for the observed variability in the mixing ratio as well as its isotopic composition. Here
we used the Keeling model approach to find out the carbon isotope ratio for the local sources. The local sources have further
been characterized as anthropogenic and biological respiration (in %) using a two-component mixing model. We also used a vertical
mixing model based on the concept of the mixing of isotopically depleted (carbon isotope) “polluted air” (PA) with isotopically
enriched “free atmospheric air” (FA) above. Using this modeling approach, the contribution of FA at ground level is being
estimated for both the morning and afternoon time air samples. 相似文献