A Recent Study on the Relationship between Global Radiative Forcing and Global Annual Climatic Variability ()
1. Introduction
Worldwide, increasing attention is given to the present and the potential future impacts of climate change. Intergovernmental Panel on Climate Change predicts that it is very likely that extreme weather events will occur more frequently in the future [1] . Climate change is therefore defined as “long-term weather patterns and trends becoming different over an extended period of time” [2] . Global warming is commonly referred to as an increase in the temperature of the lowest layers of Earth’s atmosphere [3] . However, global warming has occurred in the distant past as the result of the natural influences, but the term is most often used to refer to the warming predicted to occur as a result of increased emissions of greenhouse gases. Primary greenhouse gases include water vapor, carbon dioxide (CO2), methane (CH4), nitrous oxide (NO) and ozone (O3) [4] . Carbon dioxide, as well as other greenhouse gases, is a very important factor in the vital cycles which sustain life on this planet. The greenhouse effect is a natural process which makes life on Earth feasible. The greenhouse gases in atmosphere let the energy in and prevent it from escaping, directing it back to Earth’s surface [5] . In fact, there are notably increases in greenhouse gases over the globe of the Earth (e.g. [6] -[12] ). Weather patterns are and will be modified: number of radically hot days will augment; frequency and severity of storms, hurricanes, floods, droughts and forest fires will increase; more intense rainfall will bother some areas, and at the same time water supplies in some regions, particularly in already affected areas arid with deserted climate (e.g. [13] -[24] ). However, there are several scenarios of models for global warming in the future. Unfortunately, it has an uncertainty factor [25] [26] .
The NOAA Annual Greenhouse Gas Index (AGGI) measures the commitment society has already made to living in a changing climate. It is based on the highest quality atmospheric observations from sites around the world. Its uncertainty is very low. The AGGI is a measure of the warming influence supplied by long-lived trace gases and how that influence is changing each year. The AGGI provides a way for the warming influence to be presented as a simple index. However, the Earth’s climate depends on the functioning of a natural “greenhouse effect”. This effect is the result of heat-trapping gases (also known as greenhouse gases), like water vapor, carbon dioxide, ozone, methane and nitrous oxide, which absorb heat radiated from the Earth’s surface and lower atmosphere and then radiate much of the energy back toward the surface. However, human activities have been releasing additional heat-trapping gases, intensifying the natural greenhouse effect, and thereby changing the Earth’s climate. The climate is influenced by a variety of factors, both human-induced and natural. The increase in the carbon dioxide concentration has been the principal factor causing warming over the past 60 years. Its concentration has built up in the Earth’s atmosphere since the beginning of the industrial era in the mid-1700s, primarily due to the burning of the fossil fuels (coal, oil and natural gas) and the clearing of forests. Human activities have also increased the emissions of other greenhouse gases, such as methane and nitrous oxide. Increases in the abundance of atmospheric greenhouse gases since the industrial revolution are largely the result of human activity and are largely responsible for the observed increases in global temperature [1] . However, climate projections have modeled uncertainties that overwhelm the uncertainties in greenhouse gas measurements. We present here an index that is directly proportional to the direct warming influence (also known as global radiative forcing) supplied from these gases. Because it is based on the amounts of long-lived greenhouse gases in the atmosphere, this index contains relatively little uncertainty.
The climate forcing is a “change” in the status quo. IPCC takes the pre-industrial era (arbitrarily chosen as the year 1750) as the baseline. The perturbation to direct climate forcing (also termed “radiative forcing”) that has the largest magnitude and the least scientific uncertainty is the forcing related to changes in long-lived and well mixed greenhouse gases, carbon dioxide (CO2), methane (CH4), nitrous oxide (N2O) and halogenated compounds (mainly CFCs) in particular. Atmospheric global greenhouse gas abundances are used to calculate changes in radiative forcing for the period beginning in 1979 when NOAA’s global air sampling network expanded significantly. The change in annual average total radiative forcing by all the long-lived greenhouse gases since the pre-industrial era (1750) is used to define the NOAA Annual Greenhouse Gas Index (AGGI), which was introduced in 2004 [8] and has been updated annually.
El Nino/Southern Oscillation (ENSO) teleconnection patterns can be thought of as resulting from the inter- annual warming and cooling of equatorial Pacific sea surface temperatures (SSTs) and associated atmospheric circulation changes. The opposing phases of ENSO, the warm El Nino and the cold La Nina, though occurring quasi-periodically with roughly a cycle of 3 - 7 years, have not proved to be highly predictable [27] despite considerable effort. El Nino also tends to cause warmer than average conditions over parts of the tropics and into the extra-tropics [28] . Suggest mechanisms further illustrate the interconnectivity of the atmosphere-ocean system and include higher latitude warming strong enough to enhance the monsoon and overcome the rain suppressing effects of El Nino (e.g. [29] -[35] ).
North Atlantic Oscillation (NAO) whether the major mode of mid or high northern hemisphere variability is better characterized as a regional oscillation. A measure of the NAO is an index generally defined as a pressure difference between a high latitude station representative of the Icelandic low (Reykjavik or Stykkisholmur, Iceland) and a subtropical station (Lisbon or Gibraltar) which represents other centers of action in the Azores surface high pressure system. The phase of the NAO modulates climate in eastern North America and
North Atlantic
, particularly in winter months. The NAO, like ENSO, is an inter-annual oscillation with an irregular pattern of several years [36] -[40] . Many studies have examined the factors involved in forcing variability in the NAO and have found a variety of potential mechanisms within the Earth system: SST [41] -[43] . The variability of climate due to these teleconnection patterns is therefore variable over longer time scales. The present work aims to study the relationship between the GRF and global annual climatic variability of the weather elements and climatic indices over the globe.
2. Data and Methodology
2.1. Data
The NCEP/NCAR Reanalysis project is using a state-of-the-art analysis/forecast system to perform data assimilation, within resolution of 2.5 × 2.5 degree lat/lon grid, using past data from 1948 to 2011. Data used in the present study is annual mean and annual time series of several meteorological elements (air temperature, wind, surface pressure, outgoing long wave radiation, precipitation rate and geopotential height at level 500 hPa, etc.) over the globe of Earth for the period (1948-2011). The data are obtained from the Web site http://www.cdc.noaa.gov/. The data have been provided by the NOAA/OAR/ESRL PSD, Boulder, Colorado, USA [44] . Furthermore, the corresponding annual mean values of NAO index, SOI, El Nino 3.4 and SST have been obtained from the Climate Prediction Centre Web site http://www.cpc.ncep.noaa.gov. However, NCEP data set domain considered in the present work are extended to 90˚N - 90˚S, 180˚W - 180˚E for whole the globe. The global radiatve forcing data of GHG for the period (1979-2011) has been used. However, the annual average total radiative forcing by all the long-lived greenhouse gases since the pre-industrial era (1750) is used to define the NOAA Annual Greenhouse Gas Index (AGGI), which was introduced in 2004 [8] and has been updated annually since.
2.2. Methodology
A. Calculation of Annual Averages
For each grid point in the domain [resolution of 144 × 73 grid points] of the globe of the Earth annual averages for meteorological elements (surface temperature, wind, surface pressure, geopotential height, etc.) have been calculated. Using the NCEP/NCAR reanalysis monthly data sets for the year using of statistical mean average (i.e. (12 months/12) along the period from 1948 to 2011). The annual composite mean comes from the statistical mean for twelve months from January to December for the period of study. However, the interactive plotting and analysis NCEP/NCAR software program has been used for this analysis. The annual values of NAO index, SOI, and El Nino 3.4 have been calculated in the same manner. The global radiative forcing for GHG’s has been calculated according to [45] . The anomaly method has been used.
B. Local Significance and Calculation of Correlation Patterns
For a given year, means of meteorological elements, e.g. geopotential height at level 500 hPa at each grid point correlates with the (Global surface air temperature, Solar index, NAO, SOI and El Nino 3.4). Each grid point correlation is a t-tested for local significance using [46] allowing for temporal autocorrelation according to [47] method. For field significance, the areal extent of locally significant correlations in a correlation map must exceed the areal extent that can be expected by chance. To estimate the correlation, we use the
Monte Carlo
methodology. The field-significance statistic is the area-weighted average absolute correlation of a given correlation map (considering only the locally significant correlations). The field-significance threshold is the 95th percentile of a 1000-member Monte-Carlo population.
C. Radiative Forcing Calculations
To determine the total radiative forcing of the greenhouse gases, we have used IPCC recommended expressions to convert greenhouse gas changes, relative to 1750, to instantaneous radiative forcing (see Table 1). These empirical expressions are derived from atmospheric radiative transfer models and generally have an uncertainty of about 10%. The uncertainties in the global average abundances of the long-lived greenhouse gases are much smaller (<1%, [45] ).
D. Linear Correlation Method
For a linear correlation analysis of the previous global weather elements, climatic indices NAO, SOI, El Nino 3.4 and SST and global radiative forcing datasets during the study period (1948-2011), the methodology of Monte Carlo has been used [47] . Based on this methodology a correlation of +/−0.3 would be significant. These significance levels are local for a resolution of 144 × 73 grid points. One would assume at least 0.05 × (144 × 73) = 526 grids would be significant by chance at the one-sided 95% level (at Web site http://www.ersl.noaa.gov/psd/data/correlation/significance.html). In addition to that linear correlation coefficient according to [48] has been used.
3. Results
3.1. Study the Variability of Global Annual Geopotential Height at Level 500 hPa through the Period (1948-2012)
In fact, the geopotential height at level 500 hPa played a greater role in climate and abnormal weather over the globe. The NCEP/NCAR Reanalysis data assimilation, within resolution of 2.5 × 2.5 degree lat/lon grid, for the globe from 1948 to 2012 has been used. Data used in the present section are annual mean of geopotential height at 500 hPa, global temperature, and solar index, NAO, SOI and El Nino 3.4. Analysis of this data revealed that:
1) Global annual geopotential height anomaly at level 500 hPa time series analysis observed that, it varies from year to year with time and becomes continues above its normal value from year 2000 up to 2012. The trend of variation is a positive trend as shown in Figure 1.
2) An outstanding correlation coefficient between global annual geopotential height and global temperature composites mean reached to (+1) in the tropics meanwhile the correlation decrease towards the north and South Pole. However, there is a positive correlation in the northern polar region; meanwhile there is a negative sign of correlation towards the South Pole through the study period (1948-2012). It is clear from Figure 2(a).
3) Non significant appears between annual geopotential height and solar index in general, see Figure 2(b).
4) Annual geopotential height has a significant negative correlation of (−0.9) with NAO over Iceland. Meanwhile, there is a positive correlation (+0.7) over the north Atlantic region. The tropics have not any significant correlations as clear in Figure 2(c).
5) Annual geopotential height has significant correlations of (0.7) with SOI over the tropics. It has outstanding correlations over all the Atlantic Ocean through the study period (1948-2010) as shown in Figure 2(d).
6) Annual geopotential height has a significant positive correlation reached to (0.7) with El Nino 3.4 over the tropics. Meanwhile, there are significant correlations reached at (+0.7) over the central of the Atlantic Ocean as clear in Figure 2(e). It is noticed that over the
Atlantic Ocean
the signs of correlation contradicting to the signs of correlations with SOI. See Figure 2(d) and Figure 2(e).
Table 1. Expressions for calculating radiative forcing.
[Source IPCC (2001)]. The subscript “o” denotes the unperturbed (1750) abundance; f(M, N) = 0.47ln[1 + 2.01 × 10−5 (MN)0.75 + 5.31 × 10 ? 15 M(MN)1.52]; C is CO2 in ppm; M is CH4 in ppb; N is N2O in ppb; X is CFC in ppb; Co = 278 ppm; Mo = 700 ppb; No = 270 ppb; Xo = 0.
Figure 1. The time series of global annual anomaly in geopotential height 500 hPa and the trend through the period (1948- 2012).
3.2 Study the Relationship between the GRF and Global Annual Weather Elements Variability through the Period (1979-2011)
Through this section, the variability of weather meteorological elements (surface air temperature, 500 hPa air temperature, sea level pressure, geopotential height at level 500 hPa, surface wind, precipitation rate, OLR and SST over the globe has been analyzed through the period of (1948-2012). In addition to that, the greenhouse gases and global radiative forcing has been analyzed. Time series analysis has been used to study the variability between all of these datasets. The results revealed that:
1) For CO2 and surface air temperature and 500 hPa level of temperature anomaly, it is clear that, all of these three parameters have a sharp increase with time through the period (1950-2012) and all of it becomes above its normal value after year 2000 up to 2012 as appears in the Figure 3(a). With the continuing increase of CO2 the geopotential height increases too. Meanwhile, surface air pressure gradually decreases in contradicting to the variability of geopotential height. See Figure 3(a) and Figure 3(b). Precipitation rate increase to become more its normal values on year 1985 up to the year 2012 over the globe likely the variability of CO2 during the same period. Meanwhile the surface wind varies like a wave and not related to CO2 variation through the period of study (1950-2012) as shown in Figure 3(c). Outgoing longwave radiation (OLR) and sea surface temperature (SST) varies and increases with time, typically with the CO2 variability for all the period (1950-2012) over the globe as shown in Figure 3(d).
2) For CH4 and surface air temperature and 500 hPa level of temperature anomaly, it is clear that, CH4 increase sharply through the period of study (1979-2011) and becomes above its normal value since 1992 and do not return to its normal value until 2011. The increasing after year 2000 matches with the increase of temperature as shown in Figure 4(a). CH4 variability after year 2000 coincide with the variability of geopotential height at level 500 hPa and contradicting with variation of sea level pressure in general, see Figure 4(b). It is noticed that, for the period of (1995-2011) the increase in precipitation rate matches with the increase in CH4. In fact the wind variability does not follow the CH4 variability as clear from Figure 4(c). For OLR and SST it is observed that after 1997 they has amounted over its normal values and continues increase to the year 2011. There is a positive increase through the study period for all of these three parameters as shown in Figure 4(d).
3) For N2O and surface air temperature and 500 hPa level of temperature anomaly, it is clear that, all of these three parameters have a sharp increase with time through the period (1979-2011) and all of it becomes above its normal value after year 1999 up to 2011 as appears in the Figure 5(a). It is clear that with the continual increase of N2O the geopotential height increase too. Mean while surface air pressure gradually decreases in contradicting to the variability of geopotential height. See Figure 5(a) and Figure 5(b). Precipitation rate increase to become more its normal values on year 1995 up to the year 2011 over the globe likely the variability of N2O. Meanwhile the surface wind varies like a wave and not related to N2O variation through the period of study (1979-2011) as shown in Figure 5(c). Outgoing longwave radiation (OLR) and sea surface temperature (SST) varies and increases with time, typically with the N2O variability for all the period (1979-2011) over the globe as shown in Figure 5(d).
4) For CFC 12 and surface air temperature and 500 hPa level of temperature anomaly, it is clear that the CFC 12 has become more its normal values since 1991. It decreases with time from the year 2004 up to 2011 as
appears in Figure 6(a). Variably connection of CFC 12 with the geopotential height, surface air pressure, Precipitation rate, surface wind, OLR and SST are not clear through the study period (1979-2011). See Figures 6(b)-(d).
5) For CFC 11 variability, like as CFC 12 no connection appears with weather elements variably over the globe through the period of study (1979-2011). Meanwhile, CFC 11 returned to its normal values from the year 2006 as shown in Figures 7(a)-(d).
6) For 15-MINOR, and surface air temperature and 500 hPa level of temperature anomaly, it is clear that, 15- MINOR became more than its normal values after 1993. All of these three parameters have a sharp increase with time through the period (2001-2011) as appears in Figure 8(a). With the continual increase of 15-MINOR, the geopotential height increase contradicted to surface air pressure almost time of the study period. See Figure 5(b). Precipitation rate increase to became more its normal values from the year 1995 to the year 2011 over the globe
likely the variability of 15-MINOR. Meanwhile the surface wind varies like a wave and not related to 15- MINOR variation through the period of study (1979-2011) as shown in Figure 8(c). Generally, OLR and SST vary and increase with time, typically with the 15-MINOR variability for all the period (1979-2011) over the globe as shown in Figure 8(d).
7) It is noticed that the variability of total GRF and AGGI values is the same with the variability of the
global annual weather elements through the period of study except with surface air pressure and wind. Whereas, the total GRF and AGGI values have become above normal since 1995 with the same manner of the meteorological elements in general. See Figure 9 and Figure 10.
3.3. The Relation between GRF and Climatic Indices NAO, SOI, El Nino 3.4 and SST Variability during the Period (1979-2011)
From the above results it has become clear that the effect of global radiative forcing for greenhouse gases varies from greenhouse gas to another in the annual weather and climatic conditions for the globe. Through this sub-
section the time series trend analysis has been sued to study the relation between GRF, AGGI and for each of greenhouse gases and annual climatic indices NAO, SOI and El Nino 3.4 through the study period. The results revealed that there is a positive trend of the NAO, El Nino 3.4 and total GRF, AGGI and for each of greenhouse gases in general. Meanwhile, the connection between CFC 12 and CFC 11 and climatic indices variability are not clear through the study period, as clear from Figures 11(a)-(h).
(a)(b)(c)(d)(e)(f)(g)(h)
Figure 11. (a) Time series of CO2, NAO, SOI and EL Nino 3.4 anomaly for the globe through the period (1979-2011); (b) Time series of CH4, NAO, SOI and EL Nino 3.4 anomaly for the globe through the period (1979-2011); (c) Time series of N2O, NAO, SOI and EL Nino 3.4 anomaly for the globe through the period (1979-2011); d) Time series of CFC 12, NAO, SOI and EL Nino 3.4 anomaly for the globe through the period (1979-2011); (e) Time series of CFC 11, NAO, SOI and EL Nino 3.4 anomaly for the globe through the period (1979-2011); (f) Time series of 15-MINOR, NAO, SOI and EL Nino 3.4 anomaly for the globe through the period (1979-2011); (g) Time series of total GRF, NAO, SOI and EL Nino 3.4 anomaly for the globe through the period (1979-2011); (h) Time series of AGGI, NAO, SOI and EL Nino 3.4 anomaly for the globe through the period (1979-2011).
3.4 The Correlation Coefficient between the GRF and Weather and Climatic Elements of the Earth through the Period (1979-2011)
Through this section, the annual mean values of weather meteorological elements (surface air temperature, 500 hPa air temperature, sea level pressure, geopotential height at 500 level hPa, surface wind, precipitation rate, OLR, SST, NAO, SOI and El Nino 3.4 over the globe has been correlated with the GHG, S and global radiative forcing has been analyzed through the period of 1979-2011. Anomaly and linear correlation coefficient methods had been used through this analysis. The results revealed that:
1) For CO2, it is clear that there is an outstanding positive correlation coefficient (0.918, 0.840, 0.832, 0.895 and 0.890) between CO2 and surface air temperature, 500 hPa air temperature, geopotential height at level 500 hPa, OLR and SST respectively over the globe through the study period. See Table 2.
2) For CH4, it is clear that there is an outstanding positive correlation coefficient (0.832) between CH4 and precipitation rate and significant correlation (0.707) with surface air temperature over the globe through the study period. See Table 2.
3) For N2O, it is clear that there is an outstanding positive correlation coefficient, (0.843, 0.847 and 0.803) between N2O and surface air temperature, precipitation rate and SST respectively through the study period as observed in Table 2.
4) For CFC 12, it is clear that there is only an outstanding positive correlation coefficient (0.806) between CFC 12 and precipitation ate over the globe. As shown in Table 2.
5) For CFC 11, no clear significant correlation coefficient between CFC 11and meteorological elements and climatic indices over the globe through the study period (1979-2011).
6) For15-MINOR, it is clear that there is an outstanding positive correlation coefficient, (0.843) between 15-MINOR and global precipitation rate. Significant correlation is (0.786) with global surface air temperature. Significant correlation (0.758) with SST has been observed through the study period as shown in Table 2.
7) For total GRF, it is obvious that, there is an outstanding positive correlation coefficient, (0.827 and 0.857) between total GRF and global surface air temperature and precipitation rate respectively over the globe through the period of study (1979-2011). In addition to that, a significant correlation (0.795) with SST observed as it is illustrated in Table 2.
8) For AGGI, it is clear that, there is an outstanding positive correlation coefficient, (0.827 and 0.857) be-
Table 2. Correlation coefficient matrix between the anomaly of global radiative forcing and anomaly of global annual meteorological elements and climatic indices through the period (1979-2011).
tween AGGI and global surface air temperature and precipitation rate respectively over the globe through the period of study (1979-2011). Also a significant correlation (0.795) with SST is observed. Notably, it is approximately typically of total GRF correlation results. It is illustrated in Table 2.
9-There is no significant correlation observed between the global radiative forcing and the climatic indices NAO, SOI and El Nino through the period of study (1979-2011), as it is clear in Table 2.
4. Discussion
The global climate change will have a strong impact on development in coming decades. The greenhouse gas concentration has built up in the Earth’s atmosphere since the beginning of the industrial era in the mid-1700s, primarily due to the burning of fossil fuels (coal, oil and natural gas) and the clearing of forests. Human activities have also increased the emissions of other greenhouse gases, such as methane and nitrous oxide. The absence of strong global action to reduce greenhouse gas emissions will hinder future development over the globe of the Earth. Scenarios of the climatic models have a great degree of uncertainties. The present work aims to uncover the impacts of GRF in climatic variability over the globe of the Earth using of calculating GRF and operational weather and climatic data. However, there are four fold studies in the present studies. First one is the variability of global annual geopotential height at level 500 hPa through the period of (1948-2012). Analysis of the global annual geopotential height anomaly at level 500 hPa observed that, it varies from year to a year with time and becomes continues above its normal value from year 2000 up to 2012. The trend of variation is a positive trend. An outstanding correlation coefficient between global annual geopotential height and global temperature composites mean reached to (+1) in the tropics meanwhile the correlation decrease towards the north and south poles. It has a significant negative correlation of (−0.9) with NAO over Iceland. Meanwhile, there is a positive correlation (+0.7) over the north Atlantic region. In addition to that, it has significant correlations of (+0.7) with SOI over the tropics. It has outstanding correlations over all the
Atlantic Ocean
through the study period (1948-2010). Also, there is a significant positive correlation reached at (+0.7) with El Nino 3.4 over the tropics. Meanwhile, there are significant correlations reached at (+0.7) over the central of the
Atlantic Ocean
. It is noticed that over the
Atlantic Ocean
the signs of correlation contradicting to the signs of correlations with SOI. Through second one, the relationship between the GRF and global annual weather elements variability has been studied. Through this section, the variability of weather meteorological elements (surface air temperature, 500 hPa air temperature , sea level pressure, geopotential height at 500 hPa level, surface wind, precipitation rate, OLR and SST over the globe and GRF gases has been analyzed. For CO2, surface air temperature and 500 hPa level of temperature anomaly, it is clear that, all of these three parameters have a sharp increase with time and all of it becomes above its normal value after year 2000 up to 2012. With the continual increase of CO2 the geopotential height increases too. Meanwhile, surface air pressure gradually decreases in contradicting to the variability of geopotential height. Precipitation rate increase to become more its normal values on year 1985 up to the year 2012 over the globe likely the variability of CO2 during the same period. Meanwhile the surface wind varies like a wave and not related to CO2 variation. Outgoing longwave radiation (OLR) and sea surface temperature (SST) varies and increases with time, typically with the CO2 variability for all the period (1950-2012). For CH4 it is clear that, CH4 increase sharply through the period of study (1979-2011) and becomes above its normal value since 1992 and do not return to its normal value until 2011. The increasing after Year 2000 matches with the increase of temperature. CH4 variability after year 2000 coincide with the variability of geopotential height at level 500 hPa and contradicting with variation of sea level pressure in general. Also, it is noticed that, for the period of (1995-2011) the increase in precipitation rate matches with the increase in CH4. In fact the wind variability does not follow the CH4 variability. For OLR and SST it is observed that after 1997 they have amounted over its normal values and continues increase to the year 2011. For N2O and surface air temperature and 500 hPa level of temperature anomaly, it is clear that, all of these three parameters have a sharp increase with time through the period (1979-2011) and all of it becomes above its normal value after year 1999 up to 2011. With the continued increase of N2O the geopotential height increases too. Global precipitation rate increase to become more its normal values on year 1995 up to year 2011 likely the variability of N2O. Meanwhile the surface wind varies like a wave and not related to N2O variation through the period of study (1979-2011). Outgoing longwave radiation (OLR) and sea surface temperature (SST) varies and increases with time, typically with the N2O variability for all the period (1979-2011). The CFC 12 has become more its normal values since 1991. It decreases with time from the year 2004 up to 2011. Variability of CFC 12 with the geopotential height, surface air pressure, Precipitation rate, surface wind, OLR and SST are not clear through the study period. For CFC 11 variability, like as CFC 12 no connection appears with weather elements variably over the globe through the period of study. CFC 11 returned to its normal values from the year 2006. For 15-MINOR, and surface air temperature and 500 hPa level of temperature anomaly, it is clear that, 15-MINOR became more than its normal values after 1993. All of these three parameters have a sharp increase with time through the period (2001-2011). With the continued increase of 15-MINOR, the geopotential height increase contradicted to surface air pressure almost time of the study period. Precipitation rate increase to became more its normal values on year 1995 up to the year 2011 over the globe likely the variability of 15-MINOR. Meanwhile the surface wind varies like a wave and not related to 15-MINOR variation through the period of study (1979-2011) as shown in Figure 8(c). Generally, OLR and SST vary and increase with time, typically with the 15-MINOR variability for all the period (1979-2011). It is noticed that the variability of total GRF and AGGI values is the same with the variability of the global annual weather elements through the period of study except with surface air pressure and wind. The total GRF and AGGI values has become above normal since 1995 with the same manner of the meteorological elements in general. Third one, the variability of GRF and climatic indices NAO, SOI, El- Nino 3.4 and SST has been studied. It is revealed that there is a positive trend of the NAO, El Nino 3.4 and total GRF, AGGI and for each of greenhouse gases in general. Meanwhile the connection between CFC 12 and CFC 11 and climatic indices variability are not clear. Last one, the correlation coefficient between the GRF and weather and climatic elements of the Earth through the period (1979-2011) has been studied. Through this section, the annual mean values of weather meteorological elements (surface air temperature, 500 hPa air temperature , sea level pressure, geopotential height at 500 hPa level, surface wind, precipitation rate, OLR, SST, NAO, SOI and El Nino 3.4 over the globe has been correlated with the GHGs and global radiative forcing has been analyzed through the period of (1979-2011). Anomaly and linear correlation coefficient methods had been used. It is noticed that:
1) For CO2, an outstanding positive correlation coefficient, (0.918, 0.840, 0.832, 0.895 and 0.890) between CO2 and surface air temperature, 500 hPa air temperature, geopotential height at 500 hPa level, OLR and SST respectively over the globe.
2) For CH4 an outstanding positive correlation coefficient (0.832) between CH4 and precipitation rate and significant correlation (0.707) with surface air temperature over the globe.
3) For N2O, an outstanding positive correlation coefficient, (0.843, 0.847, 0.803) between N2O and surface air temperature, precipitation rate and SST respectively.
4) For CFC 12, it is clear that there is only an outstanding positive correlation coefficient (0.806) between CFC 12 and precipitation ate over the globe.
5) For CFC 11, no clear significant correlation coefficient between CFC 11 and meteorological elements and climatic indices over the globe0.
6) For 15-MINOR, there is an outstanding positive correlation coefficient, (0.843) between 15-MINOR and global precipitation rate. It has a significant correlation (0.786) with global surface air temperature. Significant correlation (0.758) with SST has been observed through the study period.
7) For total GRF, it is obvious that, there is an outstanding positive correlation coefficient, (0.827 and 0.857) between total GRF and global surface air temperature and precipitation rate respectively over the globe. In addition to that, a significant correlation (0.795) with SST observed.
8) For AGGI, it is clear that, there is a significant positive correlation coefficient, (0.827 and 0.857) between AGGI and global surface air temperature and precipitation rate respectively over the globe through the period of study (1979-2011). Also a significant correlation (0.795) with SST is observed. Notably, it is approximately typically of total GRF correlation results.
9) In general, there is no significant correlation observed between the global radiative forcing and the climatic indices NAO, SOI and El Nino through the period of study (1979-2011).
5. Conclusion
Finally, one can conclude that the GRF is impacting on the annual variability of weather and climatic elements on the globe. The present work conducts that the global annual climatic variability of weather elements and global warming is strongly related to the global radiative forcing and human activities. Emissions of GHG must be reduced to eliminate its impacts on the global abnormal extreme weather events to exist and to control the global change of climate. However, using renewable, clean energy sources as a source of power will break the global change of climate and control the weather.
Acknowledgements
It is a pleasure for the authors to thank the Earth System Research Laboratory, Physical Sciences Division, Climate Diagnostics Centre for supporting the data used throughout this study. Plots and images were provided by the NOAA-CIRES Climate Diagnostics Centre,
Boulder
,
Colorado
,
USA
from their Web site at
www.esrl.noaa.gov/psd/. The NOAA annual greenhouse gas index (AGGI) data from NOAA Web site http://www.esrl.noaa.gov/gmd/aggi/. Also, thanks to the Climate Prediction Centre for supporting the NAO, SOI, El Nino 3.4 and SST data which obtained through the Web site www.cpc.ncep.noaa.gov/data/indices/.
NOTES
*Corresponding author.