The rock tombs of Meir, Part 5, The tomb-chapels A, No. 1 (That of Ni-ʻAnkh-Pepi the Black) A, No. 2 (That of Pepi ʻOnkh with the 'good name' of Ḥeny the Black), A, No. 4 (That of Ḥepi the Black), D, No. 1 (That of Pepi), E, Nos. 1-4 (Those of Meniu, Nenki, PepiʻOnkh and Tjetu)

Includes index.Electronic reproduction.xi, [62] p., [66] leaves of plates ill. (some col.), fold., geneal. tables, plan 32 c

The rock tombs of Meir, Part 6, The tomb-chapels of Ukhḥopte son of Iam (A, No. 3), Senbi son Ukhḥopte son of Senbi (B, No. 3), and Ukhḥopte son Ukhḥopte and Ḥeny-Ḥery-Ib (C, No. 1)

Includes index.Electronic reproduction.xi, 38 p., [36] leaves of plates ill. (some col.), fold., geneal. tables, plan 32 c

The mastaba of Khentika, called Ikhekhi

Includes index.Electronic reproduction.78 p., [43] leaves of plates ill., plans 31 c

The Analytical Repository Source-Term (AREST) model: Description and documentation

The geologic repository system consists of several components, one of which is the engineered barrier system. The engineered barrier system interfaces with natural barriers that constitute the setting of the repository. A model that simulates the releases from the engineered barrier system into the natural barriers of the geosphere, called a source-term model, is an important component of any model for assessing the overall performance of the geologic repository system. The Analytical Repository Source-Term (AREST) model being developed is one such model. This report describes the current state of development of the AREST model and the code in which the model is implemented. The AREST model consists of three component models and five process models that describe the post-emplacement environment of a waste package. All of these components are combined within a probabilistic framework. The component models are a waste package containment (WPC) model that simulates the corrosion and degradation processes which eventually result in waste package containment failure; a waste package release (WPR) model that calculates the rates of radionuclide release from the failed waste package; and an engineered system release (ESR) model that controls the flow of information among all AREST components and process models and combines release output from the WPR model with failure times from the WPC model to produce estimates of total release. 167 refs., 40 figs., 12 tabs