The emergence of new data handling technologies and analytics enabled the organization of big data in processes as an innovative aspect in wireless sensor networks (WSNs). Big data paradigm, combined with WSN technology, involves new challenges that are necessary to resolve in parallel. Data aggregation is a rapidly emerging research area. It represents one of the processing challenges of big sensor networks. This paper introduces the big data paradigm, its main dimensions that represent one of the most challenging concepts, and its principle analytic tools which are more and more introduced in the WSNs technology. The paper also presents the big data challenges that must be overcome to efficiently manipulate the voluminous data, and proposes a new classification of these challenges based on the necessities and the challenges of WSNs. As the big data aggregation challenge represents the center of our interest, this paper surveys its proposed strategies in WSNs.

The present study deals with the biostratigraphic and geochemical analysis of the Cenomanian-Turonian deposits of the Thénièt El Manchar district in the Bellezma-Batna Range, and their vertical fluctuations. A 180 m-thick profile is described in this area. This reference section encompasses the ‘Marnes de Smail’ Formation, subdivided into four lithostratigraphic units (IA, IB, IC, and ID respectively) and dated of the Cenomanian (ammonites and coral), and the base of the ‘Dolomies de l’Oued Skhoun’ Formation (unit IIA), dated of the Lower Turonian (planktonic foraminifers). Both qualitative and quantitative analysis of foraminifers (planktonic and/or benthonic), ostracodes and of geochemical indices, lead us to reconstitute the evolution of both palaeoenvironmental and palaeobathymetrical changes during this time interval. Subsequently units IA, IB, IC and the lower part of unit ID (all Cenomanian) are displaying agglutinated benthonic foraminifers and complete ostracode shells, as evidence of a shelfal environment and weak hydrodynamism. Within these deposits microfaunal assemblages display a low-to-medium species diversity and a relatively high specimen abundance, supporting evidence of normal trophic conditions and water oxygenation. The upper part of unit ID (topmost Cenomanian), and unit IIA (basal Turonian) are documenting an environmental setting into deeper conditions, supported by the standard event succession already recorded in northern Africa, namely: the abundance of planktonic foraminifers, the occurrence of ‘filaments’ and the sudden reduction of ostracofauna. Furthermore the total carbonate isotope fluctuations (δ¹³C and δ¹⁸O) are documenting isotopic anomalies related to palaeoenvironmental changes. The δ¹³C results, coupled with those of TOC, are evidencing a low primary productivity while the δ¹⁸O data are supporting a temperature rise as the main potential drive of the onset of OAE2. These paleoenvironmental assertions are consistent with the regional paleogeographic context and are highlighting tethysian features.

The present study deals with the biostratigraphic and geochemical analysis of the Cenomanian-Turonian deposits of the Thénièt El Manchar district in the Bellezma-Batna Range, and their vertical fluctuations. A 180 m-thick profile is described in this area. This reference section encompasses the ‘Marnes de Smail’ Formation, subdivided into four lithostratigraphic units (IA, IB, IC, and ID respectively) and dated of the Cenomanian (ammonites and coral), and the base of the ‘Dolomies de l’Oued Skhoun’ Formation (unit IIA), dated of the Lower Turonian (planktonic foraminifers). Both qualitative and quantitative analysis of foraminifers (planktonic and/or benthonic), ostracodes and of geochemical indices, lead us to reconstitute the evolution of both palaeoenvironmental and palaeobathymetrical changes during this time interval. Subsequently units IA, IB, IC and the lower part of unit ID (all Cenomanian) are displaying agglutinated benthonic foraminifers and complete ostracode shells, as evidence of a shelfal environment and weak hydrodynamism. Within these deposits microfaunal assemblages display a low-to-medium species diversity and a relatively high specimen abundance, supporting evidence of normal trophic conditions and water oxygenation. The upper part of unit ID (topmost Cenomanian), and unit IIA (basal Turonian) are documenting an environmental setting into deeper conditions, supported by the standard event succession already recorded in northern Africa, namely: the abundance of planktonic foraminifers, the occurrence of ‘filaments’ and the sudden reduction of ostracofauna. Furthermore the total carbonate isotope fluctuations (δ¹³C and δ¹⁸O) are documenting isotopic anomalies related to palaeoenvironmental changes. The δ¹³C results, coupled with those of TOC, are evidencing a low primary productivity while the δ¹⁸O data are supporting a temperature rise as the main potential drive of the onset of OAE2. These paleoenvironmental assertions are consistent with the regional paleogeographic context and are highlighting tethysian features.

The present study deals with the biostratigraphic and geochemical analysis of the Cenomanian-Turonian deposits of the Thénièt El Manchar district in the Bellezma-Batna Range, and their vertical fluctuations. A 180 m-thick profile is described in this area. This reference section encompasses the ‘Marnes de Smail’ Formation, subdivided into four lithostratigraphic units (IA, IB, IC, and ID respectively) and dated of the Cenomanian (ammonites and coral), and the base of the ‘Dolomies de l’Oued Skhoun’ Formation (unit IIA), dated of the Lower Turonian (planktonic foraminifers). Both qualitative and quantitative analysis of foraminifers (planktonic and/or benthonic), ostracodes and of geochemical indices, lead us to reconstitute the evolution of both palaeoenvironmental and palaeobathymetrical changes during this time interval. Subsequently units IA, IB, IC and the lower part of unit ID (all Cenomanian) are displaying agglutinated benthonic foraminifers and complete ostracode shells, as evidence of a shelfal environment and weak hydrodynamism. Within these deposits microfaunal assemblages display a low-to-medium species diversity and a relatively high specimen abundance, supporting evidence of normal trophic conditions and water oxygenation. The upper part of unit ID (topmost Cenomanian), and unit IIA (basal Turonian) are documenting an environmental setting into deeper conditions, supported by the standard event succession already recorded in northern Africa, namely: the abundance of planktonic foraminifers, the occurrence of ‘filaments’ and the sudden reduction of ostracofauna. Furthermore the total carbonate isotope fluctuations (δ¹³C and δ¹⁸O) are documenting isotopic anomalies related to palaeoenvironmental changes. The δ¹³C results, coupled with those of TOC, are evidencing a low primary productivity while the δ¹⁸O data are supporting a temperature rise as the main potential drive of the onset of OAE2. These paleoenvironmental assertions are consistent with the regional paleogeographic context and are highlighting tethysian features.

The present study deals with the biostratigraphic and geochemical analysis of the Cenomanian-Turonian deposits of the Thénièt El Manchar district in the Bellezma-Batna Range, and their vertical fluctuations. A 180 m-thick profile is described in this area. This reference section encompasses the ‘Marnes de Smail’ Formation, subdivided into four lithostratigraphic units (IA, IB, IC, and ID respectively) and dated of the Cenomanian (ammonites and coral), and the base of the ‘Dolomies de l’Oued Skhoun’ Formation (unit IIA), dated of the Lower Turonian (planktonic foraminifers). Both qualitative and quantitative analysis of foraminifers (planktonic and/or benthonic), ostracodes and of geochemical indices, lead us to reconstitute the evolution of both palaeoenvironmental and palaeobathymetrical changes during this time interval. Subsequently units IA, IB, IC and the lower part of unit ID (all Cenomanian) are displaying agglutinated benthonic foraminifers and complete ostracode shells, as evidence of a shelfal environment and weak hydrodynamism. Within these deposits microfaunal assemblages display a low-to-medium species diversity and a relatively high specimen abundance, supporting evidence of normal trophic conditions and water oxygenation. The upper part of unit ID (topmost Cenomanian), and unit IIA (basal Turonian) are documenting an environmental setting into deeper conditions, supported by the standard event succession already recorded in northern Africa, namely: the abundance of planktonic foraminifers, the occurrence of ‘filaments’ and the sudden reduction of ostracofauna. Furthermore the total carbonate isotope fluctuations (δ¹³C and δ¹⁸O) are documenting isotopic anomalies related to palaeoenvironmental changes. The δ¹³C results, coupled with those of TOC, are evidencing a low primary productivity while the δ¹⁸O data are supporting a temperature rise as the main potential drive of the onset of OAE2. These paleoenvironmental assertions are consistent with the regional paleogeographic context and are highlighting tethysian features.

The present study deals with the biostratigraphic and geochemical analysis of the Cenomanian-Turonian deposits of the Thénièt El Manchar district in the Bellezma-Batna Range, and their vertical fluctuations. A 180 m-thick profile is described in this area. This reference section encompasses the ‘Marnes de Smail’ Formation, subdivided into four lithostratigraphic units (IA, IB, IC, and ID respectively) and dated of the Cenomanian (ammonites and coral), and the base of the ‘Dolomies de l’Oued Skhoun’ Formation (unit IIA), dated of the Lower Turonian (planktonic foraminifers). Both qualitative and quantitative analysis of foraminifers (planktonic and/or benthonic), ostracodes and of geochemical indices, lead us to reconstitute the evolution of both palaeoenvironmental and palaeobathymetrical changes during this time interval. Subsequently units IA, IB, IC and the lower part of unit ID (all Cenomanian) are displaying agglutinated benthonic foraminifers and complete ostracode shells, as evidence of a shelfal environment and weak hydrodynamism. Within these deposits microfaunal assemblages display a low-to-medium species diversity and a relatively high specimen abundance, supporting evidence of normal trophic conditions and water oxygenation. The upper part of unit ID (topmost Cenomanian), and unit IIA (basal Turonian) are documenting an environmental setting into deeper conditions, supported by the standard event succession already recorded in northern Africa, namely: the abundance of planktonic foraminifers, the occurrence of ‘filaments’ and the sudden reduction of ostracofauna. Furthermore the total carbonate isotope fluctuations (δ¹³C and δ¹⁸O) are documenting isotopic anomalies related to palaeoenvironmental changes. The δ¹³C results, coupled with those of TOC, are evidencing a low primary productivity while the δ¹⁸O data are supporting a temperature rise as the main potential drive of the onset of OAE2. These paleoenvironmental assertions are consistent with the regional paleogeographic context and are highlighting tethysian features.