Hiwegi Formation

The Hiwegi Formation is a geological formation on Rusinga Island in Kenya preserving fossils dating to the Early Miocene period. The Hiwegi Formation is known for the well preserved plant fossils it preserves, which indicate a tropical forest environment that underwent wet and dry periods. The middle members of the formation in particular indicate a brief period in which conditions were notably dryer with a more open environment compared to older and younger units. Some of the formation's fauna, such as an early ancestor of the modern aye-aye and a chameleon of the genus Calumma, link Miocene East Africa to modern day Madagascar.

Hiwegi Formation
Stratigraphic range: Early Miocene ~Burdigalian PreꞒ Ꞓ O S D C P T J K Pg N ↓
Type	Formation
Unit of	Rusinga Group
Sub-units	Kaswanga Point Member Grit Member Fossil Bed Member Kibanga Member
Underlies	Kulu Formation
Overlies	Rusinga Agglomerate
Thickness	57 m (Waregi Hills)
Lithology
Primary	volcanic tuffs, clastic sediments
Location
Region	Lake Victoria
Country	Kenya

History

 

(right to left) Louis Seymour Bazett Leakey and Mary Douglas Nicol Leakey

The first discovery of fossil material by western researchers was documented in the early 20th century in the form of a British colonial report on the East Africa Protectorate. Excavations for fossils began in the 1930s with the work of Louis Leakey, followed by the British-Kenya Miocene Expedition. A major factor in the exploration of Rusinga Island was the discovery of several specimens originally assigned to the stem-hominoid Proconsul (now regarded as a distinct genus, Ekembo). Further interest for the formation was created due to the presence of ample non-primate fossil mammals, as well as a vast collection of fossil plants.^[1]

Geography

Outcrops of the Hiwegi Formation are found across Rusinga Island, an island at the eastern end of Lake Victoria within Kenyan territory. The island itself is situated close to the mouth of the Winam Gulf. The Hiwegi Formation has outcrops across the islands, in particular in the area north-east of Mbita Point. Additional outcrops are found around the mountain Lugongo in the center of the island, Waregi Hills in the east as well as near Kiahera and Kaswanga on the islands north-western shore.

Geology and Stratigraphy

The Hiwegi Formation is part of the larger Rusinga Group. During the Miocene the sediments now forming Rusinga Island were deposited on the flanks of the Kisingiri Volcano, which had formed in the early Miocene. Two hypotheses seek to explain the volcano's influence on the sediments. Drake et al.^[2] hypothesize that the Hiwegi Formation, alongside the Kiahera and Rusinga Agglomerate were deposited during early eruptions of the Kisingiri Volcano, prior to a period of silence during which the Kulu Formation was deposited and a second period of eruptions later. Bestland et al. (1995)^[3] meanwhile suggest that the Kisingiri Volcano experienced up to three periods of activity, with the strata of the Hiwegi Formation being deposited in the second and third period of volcanic activity. The formation generally underlies the younger Kulu Formation and overlies the Rusinga Agglomerate. However at Waregi Hills, in the east of the island, the formation overlies the Ombonya Beds which are found nowhere else on Rusinga. The sediments in this region are overlain by the Kiangata Agglomerate and the Lunene Lavas.^[1]

The formation is divided into four members.

• Kaswanga Point Member

The oldest member of the Hiwegi Formation, it consists primarily of air-filled tuffs and other units reworked from tuffaceous material. The fact that the member is composed of volcanic material indicates that the nearby Kisingiri Volcano was particularly active at the time the unit was deposited. Besides the tuffs this member also consists of fossil bearing mudstone which yielded fossil leaves in the Kiahera Hill fossil site, the sedimentology of which indicates deposition as part of a debris or mudflow following a volcanic eruption.^[4]

• Grit Member

The Grit Member is the second oldest member of the formation and underlies the Fossil Bed Member. It is primarily composed of tuffaceous sandstones and conglomerates consisting of pebbles in a sandy matrix. The layers of the Member indicate a fluvial or ponded mode of deposition which contrasts with the volcanic deposition of the Kibanga and Kaswanga Point Members. Palaeosols are found intercalated into these sediments. This member, as well as the overlying fossil bed member, were likely deposited in floodplain channels during flashfloods and mudflows. Additionally, they show signs of dryer conditions leading to salt hoppers and mud cracks.^[1]

• Fossil Bed Member

The Fossil Bed Member shows no differences in sedimentology compared to the Grit Member and was distinguished from the former on the basis of fossil material being absent in the older unit.^[5] Due to this lack of distinguishing features, the two groups are put together by Michel et al. (2020).

• Kibanga Member

Overall the Kibanga Member is dominated by airfilled tuffs much like the Kaswanga Point Member and is interbedded with sandstone, conglomerates and palaeosol. The fossil leaf bearing units of the Kibanga Member show a mix of interbedding layers of sandstone and mudstone. The mudstone was likely deposited during periodical wet seasons when ponds formed, followed by dry seasons creating desiccation cracks which are fond atop some of the mudstone layers.^[4]

K–Ar dating suggests a mean age of 17.8 million years for the formation. which correlates with the Burdigalian stage of the Miocene. In accordance with this method, the sediments of the Hiwegi Formation are thought to have been deposited over a short period of time, approximately 500.000 years. However dating of the formation has been met with difficulty due to the loss of certain minerals due to Diagenesis, the absence of other minerals important for dating and the effects of the Kisingiri volcano, which erupted through Precambrian sediments. Using Ar-Ar dating rather than K-Ar dating yields different results, still correlating to the Burdigalian but with a longer timespan dating from 20 to 17 million years ago.^[4]

Paleoenvironment

Early studies on the paleoenvironment of the Hiwegi Formation resulted in a variety of contradicting hypothesis, suggesting environments ranging from tropical rainforest to semi-arid habitats. Later research consistently concluded that these mixed results were caused by imprecise sampling, using fossil material from different parts of Rusinga Island corresponding with different ages and treating them as being contemporary. Subsequently, scientists focused on much narrower regions, resulting in more consistent and precise results that showed a distinct change in environment between the different members of the formation. Among the most in depth works on the paleoenvironment was a publication by Baumgartner and Peppe from 2021. In this publication the authors analysed new material from the R3 (Kibanga Member) and Kiahera Hills localities (Kaswanga Point Member) while comparing the material to prior work and material from the R5 locality (Grit Member).^[4]

• Kaswanga Point Member

 

Kakamega Rainforest in Kenya

The fossils from the Kaswanga Point Member, specifically the Kiahera Hills, consisted mostly of the remains of woody plants with only a single monocot present and no herbaceous plants. This may however be tied to the way the plant material at Kiahera Hills was preserved, as the fossils are fragmentary and are thought to have been deposited following a short transportation related to a volcanic eruption. Thus, Baumgartner and Peppe suggest that herbaceous plants may not have been sturdy enough to withstand transportation. The great sample size nevertheless indicates that herbaceous plants would be uncommon, while gymnosperms and seed ferns may have been absent altogether. All recovered leaves were untoothed and on average mesophyll. Based on the characteristics of the leaves a mean annual temperature of 25 ± 4.9 °C (77.0 ± 8.8 °F) and a mean annual precipitation of 1,812–3,577 mm (71.3–140.8 in) per year were calculated. Analysis via Digital Leaf Physiognomy (DiLP) resulted in temperatures of 34.2 ± 4.0 °C (93.6 ± 7.2 °F) and precipitation of 1,198–3,978 mm (47.2–156.6 in) per year. Both results are indicative of wet and tropical seasonal forest or rainforest. Specific comparison is drawn to the rainforests near Monrovia (Liberia) and Kakamega (Kenya) as well as the seasonal forests found in Abidjan (Côte d’Ivoire).^[4]

• Grit Member

Research conducted by Collinson and colleagues in both 1985 and 2009 indicate a riverine woodland environment for the R117 locality within the Grit Member, basing their results on the fact that only 4.2% of the taxa analysed by them were definitive forest-dwellers. This interpretation is backed up by the presence of fossil seeds assigned to Cissus rusingensis, whose closest living relatives inhabit the same kind of environment suggested by Collinson.^[6]

A study from 2013 analysed fossil plant material collected at the R5 locality close to Kaswanga, north-west Rusinga Island, which was roughly contemporary to the locality studied by Collinson in 1985. Maxbauer and colleagues identify 5 stratigraphic layers within the Grit Member, which indicate the presence of moving water in some of them and signs of dryer conditions in others. The presence of grasses sharing affinities with Typha and Phragmites, known to inhabit wetland environments, as well as the fluvial sediments they were preserved in indicate a floodplain environment that was periodically flooded or at least submerged on occasion. High mean annual temperatures can be inferred from the leaf shapes (generally untoothed), however the authors refrain from calculating any precise temperatures given the limited sample size. The presence of salt hoppers furthermore indicates that the water at the locality at least sometimes evaporated, which in combination with the high temperatures may suggest seasons of low to no rainfall. The authors of the 2013 study do however note that there is no direct correlation between the studied area, which is part of the Grits Member, and the overlying Fossil Bed Member which yielded the majority of fossil vertebrate remains known from the formation. Overall Maxbauer and colleagues argue for a seasonal riparian environment covered in a patchwork of forests and woodlands.^[7]

The 2021 study found that the mean annual temperature was similar to that of the older Kaswanga Point Member, but with notably lower precipitation, 759–1,227 mm (29.9–48.3 in) per year, which makes the Grit Member the driest unit of the Hiwegi Formation. Although monocot diversity was low, Baumgartner and Peppe point out that they were among the most abundant morphotypes present. These results recovered by the 2021 study generally support Maxbauer's previous hypothesis of a riparian woodland environment with episodic dry periods followed by wet periods. This cycle would have created standing bodies of water which were inhabited hy crocodiles and hippos while rhino and primate fossils suggest the presence of both more open and closed environments within the unit.^[4]

• Kibanga Member

A study by Michael et al. analysed fossils from the R3 locality, which corresponds with the youngest member of the formation. Their research concluded that during that time the region was covered by dense, multistoried rainforests.^[8] Baumgartner and Peppe recognize that the vast majority of plant fossils were woody dicots of excellent preservation. Monocots and other herbaceous plants were however more prominent in this member than in older units, with varied flora occurring in patches. Some areas for instance were dominated by reeds or emergent aquatic plants (plants that root in the bodies of water but emerge above the surface). The distribution of woody plants and the patches of monocots is consistent with the tree stumps observed by Michael and colleagues, with areas poor in tree stumps being the same areas that yielded more remains of grasses. Most plant morphotypes from the R3 locality are untoothed and microphyll, resulting in an estimated mean annual temperature of 23.5 ± 4.9 °C (74.3 ± 8.8 °F) and mean annual precipitation of 1,210–2,389 mm (47.6–94.1 in) per year. Calculations using DiLP gave higher temperatures 29.1 ± 4.0 °C (84.4 ± 7.2 °F) and a mean annual precipitation of 1,092–3,627 mm (43.0–142.8 in) per year. These results are somewhat cooler and drier than the estimates for the Kaswanga Point Member and indicate tropical seasonal forests or woodlands to have been present during this stage of the Hiwegi Formation. The environment would have likely shown a patchwork of both densely wooded areas and more open areas containing periodic ponds and reeds. Analysis of the paleosol indicates the presence of distinct dry and wet seasons. Compared to the Kaswanga Point Member the Kibanga Member appears to have also been less diverse and is considered to be most similar to the environments today found in Abidjan (Côte d’Ivoire) and Kibwezi (Kenya).^[4]

Paleofauna

The following fauna list is primarily based on the list published by Michel and colleagues in 2020,^[1] which incorporates prior work by Pickford (1986).^[9]

Color key Taxon Reclassified taxon Taxon falsely reported as present Dubious taxon or junior synonym Ichnotaxon Ootaxon Morphotaxon		Notes Uncertain or tentative taxa are in small text; crossed out taxa are discredited.

Reptiles

Name	Species	Member	Material	Notes	Image
Calumma	Calumma benovskyi[10]		A complete skull.	A species of chameleon of the extant genus Calumna, all modern members of this genus are endemic to Madagascar.	Calumma benovskyi
Varanus	Varanus rusingensis[11]	Grit Member	A partial skeleton	A molluscivorous species of monitor lizards reaching approximately one to two meters in length
Euthecodon	Euthecodon sp.[12][13]		A mandibular fragment	A long-snouted osteolaemine crocodile.
Brochuchus	Brochuchus pigotti[14][12]	Fossil Bed Member	Multiple specimens	A relatively small osteolaemine crocodile.

Birds

Name	Species	Member	Material	Notes	Image
Leakeyornis	Leakeyornis aethiopicus[15]		An incomplete upper and lower jaw and various limb bones.	A small-bodied genus of flamingo.

Mammalia

Afrotheria

Name	Species	Member	Material	Notes	Image
Afrohyrax	Afrohyrax championi[16]	Grit/Fossil Bed Member Kibanga Member[1]	Several fossils including three skulls.	A medium-sized titanohyracid hyrax.	Afrohyrax championi skull
Gomphotheriidae		Grit/Fossil Hill Member Kibanga Member[1]		Identified as Gomphotherium by Williamson & Ashley (1982)[17] and as cf. Archaeobelodon by Tassy (1994).[18]
Hiwegicyon	Hiwegicyon juvenalis[19]		The milk teeth of a juvenile specimen.	A species of elephant shrew with unknown affinities.
Kelba	Kelba quadeemae[20]	Grit/Fossil Bed Member?	The first or second molar	A genus of ptolemaiid mammal, its exact relationship is unknown but recent analysis have placed the group in Afrotheria.
Meroehyrax	Meroehyrax bateae	Grit/Fossil Hill Member[9]		A pliohyracid hyrax.
Miorhynchocyon	Miorhynchocyon clarki[19][3]	Grit/Fossil Hill Member [1]		A species of rhynchocyonine elephant shrew.
Myohyrax	Myohyrax oswaldi[21][19]	Grit/Fossil Hill Member Kibanga Member[1]	A crushed skull.	A type of elephant-shrew originally thought to be a dwarf hyrax. It reached a total length of 200 mm (7.9 in).	Holotype of Myohyrax
Myorycteropus	Myorycteropus africanus[22]	Grit/Fossil Hill Member Kibanga Member[1]		A small species of aardvark approximately half the size of the extant aardvark.	Myorycteropus africanus
Parageogale	Parageogale aletris[1]	Kibanga Member[9]		A genus of tenrec of the Geogalinae.[23]
Prodeinotherium[17]	Prodeinotherium hobleyi	Grit/Fossil Hill Member Kibanga Member [1]		A deinotheriine proboscidean.
Protenrec	Protenrec tricuspis[24][1]	Grit/Fossil Hill Member[9]		A genus of tenrec of the Protenrecinae.

Artiodactyla

Name	Species	Member	Material	Notes	Image
Brachyodus	Brachyodus aequatorialis[25]	Grit/Fossil Bed Member Kibanga Member?[1]		An anthracothere.
Canthumeryx	Canthumeryx sirtensis[26][27]	Grit/Fossil Hill Member Kibanga Member[1]		An early type of giraffe of the subfamily Canthumerycinae.
Diamantohyus	Diamantohyus africanus[25][28]	Grit/Fossil Bed Member Kibanga Member[1]		A suiform belonging to the family Sanitheriidae.
Dorcatherium	Dorcatherium chappuisi Dorcatherium moruorotensis Dorcatherium parvum Dorcatherium pigotti Dorcatherium songhorensis[29][28]	Grit/Fossil Bed Member Kibanga Member[1]		Several species of chevrotain.
Libycochoerus	Libycochoerus anchidens[30][25]	Grit/Fossil Hill Member Kibanga Member[1]		A listriodontine pig closely related to Kubanochoerus. It was previously regarded to be a species of Kubanochoerus.
Kenyasus	Kenyasus rusingensis[25][28]	Grit/Fossil Bed Member Kibanga Member[1]		A species of pig.
Nguruwe	Nguruwe kijivium [25]	Grit/Fossil Hill Member Kibanga Member[1]		A hyotheriine pig.
Propalaeoryx	Propalaeoryx nyanzae[31]	Grit/Fossil Hill Member Kibanga Member[1]		A stem-giraffe.
Sivameryx[1]	Sivameryx africanus[25]	Grit/Fossil Hill Member Kibanga Member[9]		A species of anthracothere.
Walangania	Walangania africanus[28]	Grit/Fossil Hill Member Kibanga Member[1]		A pecoran artiodactyl.

Carnivora

Name	Species	Member	Material	Notes	Image
Asilifelis	Asilifelis coteae[32]	Fossil Bed Member	The fragment of a mandibular ramus.	A small-bodied felid, approximately the size of the smallest living cats.
Afrosmilus	Afrosmilus africanus[33] Afrosmilus turkanae[33]	Grit/Fossil Bed Member Kibanga Member [1]		A genus of barbourofelid.
Cynelos	Cynelos macrodon[34][35][36]	Grit/Fossil Hill Member Kibanga Member[9]	Molars	A large amphicyonid originally described as Hecubides. Subsequent research has generally placed the species in Cynelos however.
Hemicyon	Hemicyon sp.[37][32]			A basal genus of ursid.
Herpestides	Herpestides aequatorialis[38][35]	Grit/Fossil Bed Member[1]		A genus of viverrid.
Kichechia	Kichcechia zamanae[38]	Grit/Fossil Hill Member Kibanga Member[1]	Multiple specimens.	A common species of viverrid of the subfamily Paradoxurinae.
Luogale	Luogale rusingensis[39]	Grit/Fossil Bed Member[1]	A molar and a premolar.

Eulipotyphla

Name	Species	Member	Material	Notes	Image
Amphechinus	Amphechinus rusingensis[40]	Grit/Fossil Bed Member Kibanga Member [1]		A widespread generalist species of hedgehog.
Galerix	Galerix africanus[40]	Grit/Fossil Bed Member[1]		A species of gymnure.
Gymnurechinus	Gymnurechinus leakeyi[40]	Grit/Fossil Hill Member Kibanga Member[1]		A species of hedgehog.

Glires

Name	Species	Member	Material	Notes	Image
Diamantomys	Diamantomys luederitzi[41]	Grit/Fossil Bed Member Kibanga Member[1]		A phiomorph rodent.
Epiphiomys	Epiphiomys coryndoni[42]	Grit/Fossil Bed Member[1]		A thryonomyid rodent, it may be closely related to Lavocatomys.
Kenyalagomys	Kenyalagomys rusingae[43] Kenyalagomys minor[44]	Grit/Fossil Bed Member Kibanga Member[1]		A species of Pika, it is considered synonymous with Austrolagomys by Mein and Pickford.[45]
Kenyamys	Kenyamys mariae[46]	Grit/Fossil Bed Member Kibanga Member[1]		A phiomorph rodent.
Lavocatomys	Lavocatomys aequatorialis[42]	Grit/Fossil Bed Member Kibanga Member[1]		A thryonomyoid rodent possibly related to Epiphiomys. It was previously regarded to be a species of Phiomys andrewsi.
Megapedetes	Megapedetes pentadactylus[47]	Grit/Fossil Bed Member Kibanga Member[1]		An extinct relative of modern springhares.
Nonanomalurus	Nonanomalurus soniae[48]	Kibanga Member[1]		An arboreal rodent of the Anomaluroidea, it was originally a species of Paranomalurus.
Notocricetodon		Grit/Fossil Bed Member[1]		A cricetodontid rodent.
Paranomalurus		Grit/Fossil Bed Member Kibanga Member[1]		A gliding "squirrel" of the family Anomaluridae.
Paraphiomys	Paraphiomys pigotti Paraphiomys renelavocati[49]	Grit/Fossil Bed Member Kibanga Member[1]		A thryonomyid rodent. P. revenlavocati was previously known as Apodecter stromeri.
Proheliophobius	Proheliophobius leakeyi[50]	Grit/Fossil Bed Member?[1]		A possible relative of modern blesmols, named for its similarity to the extant Silvery mole-rat.
Protarsomys	Protarsomys macinnesi[46]	Grit/Fossil Bed Member[1]		A genus of rodent.
Rusingapedetes	Rusingapedetes tsujikawai[51]	Grit/Fossil Bed Member[1]	A complete skull and multiple teeth.	A genus of springhare.
Simonimys	Simonimys genovefae[46]	Grit/Fossil Bed Member Kibanga Member[1]		A kenyamyid rodent.
Vulcanisciurus[41]	Vulcanisciurus africanus[46]	Grit/Fossil Bed Member Kibanga Member[1]		A genus of squirrel.

Hyaenodonta

Name	Species	Member	Material	Notes	Image
Anasinopa	Anasinopa leakeyi[52]	Grit/Fossil Hill Member Kibanga Member[1][53]	One individual and several isolated teeth.	The second largest hyainailourid found on Rusinga Island.[36]
Dissopsalis	Dissopsalis pyroclasticus[53]		A mandible containing the teeth from the fourth premolar to the third molar.	A teratodontine hyaenodont.
Exiguodon	Exiguodon pilgrimi[53]		A mandible containing both rami as well as the neurocranium and the seventh cervical vertebra.	A diminutive hyainailourid originally described as a species of Isohyaenodon. It was recovered from site R 114.
Hyainailouros	Hyainailouros napakensis[36][53]	Kibanga Member[9]		The largest hyainailourid of Rusinga Island.
Isohyaenodon	Isohyaenodon zadoki[53]	Grit/Fossil Hill Member Kibanga Member[9]	Maxilla containing two molars.	Formerly classified under the genus Metapterodon.
Leakitherium	Leakitherium hiwegi[53]	Kibanga Member [9]	A fragment of the left maxilla with the first and second molar as well as unpublished dentition.[53]	A hyaenodont related to Dissopsalis.	Leakitherium hiwegi

Perissodactyla

Name	Species	Member	Material	Notes	Image
Brachypotherium	Brachypotherium sp.[54]	Grit/Fossil Hill Member[9]	Teeth and an astragalus.	An indetermined species of brachypothere rhinoceros.
Butleria/Chalicotherium	Butleria/Chalicotherium rusingensis[55][56]	Grit/Fossil Bed Member Kibanga Member [1]	Multiple specimens including the holotype maxilla.	A small, long-faced species of chalicothere.
Rusingaceros	Rusingaceros leakeyi[1]	Grit/Fossil Hill Member[9]		A genus of rhinoceros originally described as a species of Dicerorhinus.
Turkanatherium[1]		Grit/Fossil Hill Member Kibanga Member[9]		A type of rhinoceros.

Primates

Name	Species	Member	Material	Notes	Image
Dendropithecus	Dendropithecus macinnesi[57]	Grit/Fossil Hill Member Kibanga Member[1]	Multiple specimens	A species of stem-catarrhine of the family Dendropithecidae. It was previously thought to have been a species of Limnopithecus.	Dendropithecus macinnesi
Ekembo[37]	Ekembo heseloni Ekembo helsoni	Grit/Fossil Bed Member Kibanga Member[1]	Multiple well preserved specimens.	Two species of hominoid primates previously assigned to the genus Proconsul. The two species differ in size, with Ekembo helsoni being the smaller of the two.	Ekembo nyanzae
Komba	Komba minor[58] Komba walkeri[59]	Grit/Fossil Hill Member Kibanga Member[9]	Cranial and postcranial remains.	Species of galagos previously referred to Progalagos.[60]
Limnopithecus	Limnopithecus legetet[61]	Grit/Fossil Bed Member[1] Kibanga Member		A widespread species of catarrhine monkey.
Mioeuoticus	Mioeuoticus shipmani[62][60] Mioeuoticus bishopi? [59]	Grit/Fossil Hill Member Kibanga Member[9]	A partial cranium	A species of Loris, its skull had previously been assigned to Progalago. It has been suggested that material of Progalago from Rusinga instead belongs to Mioeuoticus bishopi.
Nyanzapithecus	Nyanzapithecus vancouveringi[63]	Grit/Fossil Hill Member Kibanga Member[1]	Fragmentary remains including maxillae, mandibles and isolated teeth.	A dendropithecid primate.
Progalago	Progalago songhorensis[60]			A species of galago, it has been suggested that the material from Rusinga should instead be transferred into the loris Mioeuoticus bishopi.[59]
Propotto	Propotto leakeyi[64]	Kibanga Member[9]	Several partial mandibles.	An early member of Chiromyiformes and relative of the modern Aye-aye.

References

1. Michel, L.A.; Lehmann, T.; Mcnulty, K.P.; Driese, S.G.; Dunsworth, H.; Fox, D.L.; Harcourt-Smith, W.E.H.; Jenkins, K.; Peppe, D.J. (2020). "Sedimentological and palaeoenvironmental study from Waregi Hill in the Hiwegi Formation (early Miocene) on Rusinga Island, Lake Victoria, Kenya". Sedimentology. 67 (7): 3567–3594. doi:10.1111/sed.12762. S2CID 219743626.
2. Drake, R.E.; Van Couvering, J.A.; Pickford, M.H.; Curtis, G.H.; Harris, J.A. (1988). "New chronology for the Early Miocene mammalian faunas of Kisingiri, Western Kenya". J. Geol. Soc. 145 (3): 479–491. Bibcode:1988JGSoc.145..479D. doi:10.1144/gsjgs.145.3.0479. S2CID 130631267.
3. Bestland, E.A.; Thackray, G.D.; Retallack, G.J. (1995). "Cycles of Doming and Eruption of the Miocene Kisingiri Volcano, Southwest Kenya". J. Geol. 103 (5): 598–607. Bibcode:1995JG....103..598B. doi:10.1086/629779. S2CID 128527288.
4. Baumgartner, A.; Peppe, D.J. (2021). "Paleoenvironmental changes in the Hiwegi Formation (lower Miocene) of Rusinga Island, Lake Victoria, Kenya". Palaeogeography, Palaeoclimatology, Palaeoecology. 574: 110458. Bibcode:2021PPP...57410458B. doi:10.1016/j.palaeo.2021.110458.
5. Van Couvering, J.A. (1972). "Geology of Rusinga Island and Correlation of the Kenya mid-Tertiary fauna". University of Cambridge.
6. Adams, N.F.; Collinson, M.E.; Smith, S.Y.; Bamford, M.K.; Forest, F.; Malakasi, P.; Marone, F.; Sykes, D. (2016). "X-rays and virtual taphonomy resolve the first Cissus (Vitaceae) macrofossils from Africa as early-diverging members of the genus". American Journal of Botany. 103 (9): 1657–1675. doi:10.3732/ajb.1600177. hdl:2027.42/141865. PMID 27647420.
7. Maxbauer, D. P.; Peppe, D.J.; Bamford, M.; McNulty, K.P.; Harcourt-Smith, W.E.H.; Davis, L.E. (2013). "A morphotype catalog and paleoenvironmental interpretations of early Miocene fossil leaves from the Hiwegi Formation, Rusinga Island, Lake Victoria, Kenya". Palaeontologia Electronica. 16 (3): 16–3. doi:10.26879/342.
8. Michel, L.A.; Peppe, D.J.; Lutz, J.A.; Driese, S.G.; Dunsworth, H.M.; Harcourt-Smith, W.E.H.; Horner, W.H.; Lehmann, T.; Nightingale, S.; McNulty, K.P. (2014). "Remnants of an ancient forest provide ecological context for Early Miocene fossil apes" (PDF). Nature Communications. 5 (1): 1–9. Bibcode:2014NatCo...5.3236M. doi:10.1038/ncomms4236. PMID 24549336. S2CID 205322994.
9. Pickford, M. (1986). "Cainozoic paleontological sites of western Kenya". Münchner Geowissenschaftliche Abhandlungen R. A, Geol. Und Paläontologie. 8: 1–151.
10. Čerňanský, A.; Herrel, A.; Kibii, J.M.; Anderson, C.V.; Boistel, R.; Lehmann, T. (2020). "The only complete articulated early Miocene chameleon skull (Rusinga Island, Kenya) suggests an African origin for Madagascar's endemic chameleons". Sci Rep. 10 (109): 109. Bibcode:2020NatSR..10..109C. doi:10.1038/s41598-019-57014-5. PMC 6954250. PMID 31924840.
11. Clos, Lynne M. (1995-06-13). "A New Species of Varanus (Reptilia: Sauria) from the Miocene of Kenya". Journal of Vertebrate Paleontology. 15 (2): 254–267. doi:10.1080/02724634.1995.10011228. ISSN 0272-4634.
12. Cossette, A.P.; Adams, A.J.; Drumheller, S.K.; Nestler, J.H.; Benefit, B.R.; McCrossin, M.L.; Manthi, F.K.; Nyaboke Juma, R.; Brochu, C.A. (2020). "A new crocodylid from the middle Miocene of Kenya and the timing of crocodylian faunal change in the late Cenozoic of Africa". Journal of Paleontology. 94 (6): 1165–1179. doi:10.1017/jpa.2020.60. S2CID 222232657.
13. Storrs, G. W. (2003). Late Miocene-Early Pliocene crocodilian fauna of Lothagam, southwest Turkana Basin, Kenya. In: Lothagam: The Dawn of Humanity in Eastern Africa pp. 137–159. New York. Columbia University Press. ISBN 0-231-11870-8.
14. Conrad, J. L.; Jenkins, K.; Lehmann, T.; Manthi, F. K.; Peppe, D. J.; Nightingale, S.; Cossette, A.; Dunsworth, H. M.; Harcourt-Smith, W. E. H.; Mcnulty, K. P. (2013). "New specimens of "Crocodylus"pigotti(Crocodylidae) from Rusinga Island, Kenya, and generic reallocation of the species". Journal of Vertebrate Paleontology. 33 (3): 629–646. doi:10.1080/02724634.2013.743404. S2CID 86141651.
15. Rich, P. V.; Walker, C.A. (1983). "A New Genus of Miocene Flamingo from East Africa". Ostrich. 54 (2): 95–104. doi:10.1080/00306525.1983.9634452.
16. Pickford, M.; Senut, B. (2018). "Afrohyrax namibensis (Hyracoidea, Mammalia) from the Early Miocene of Elisabethfeld and Fiskus, Sperrgebiet, Namibia" (PDF). Communications of the Geological Survey of Namibia. 18: 93–112.
17. Williamson, R. E.; Ashley, C. C. (1982). "Free Ca2+ and cytoplasmic streaming in the alga Chara". Nature. 296 (5858): 647–651. Bibcode:1982Natur.296..647W. doi:10.1038/296647a0. PMID 7070508. S2CID 4360414.
18. Tassy, P. (1994). "Gaps, parsimony, and early Miocene elephantoids (Mammalia), with a re-evaluation of Gomphotherium annectens (Matsumoto, 1925)". Zoological Journal of the Linnean Society. 112 (1–2): 101–117. doi:10.1111/j.1096-3642.1994.tb00313.x.
19. Grossman, A.; Holroyd, P. A. (2009). "Miosengi butleri, gen. et sp. nov., (Macroscelidea) from the Kalodirr Member, Lothidok Formation, Early Miocene of Kenya". Journal of Vertebrate Paleontology. 29 (3): 957–960. doi:10.1671/039.029.0318. S2CID 86028715.
20. Cote, S.; Werdelin, L.; Seiffert, E.R.; Barry, JC (2007). "Additional material of the enigmatic Early Miocene mammal Kelba and its relationship to the order Ptolemaiida". Proceedings of the National Academy of Sciences. 104 (13): 5510–5515. Bibcode:2007PNAS..104.5510C. doi:10.1073/pnas.0700441104. PMC 1838468. PMID 17372202.
21. Butler, P. M. (1995). "Fossil Macroscelidea". Mammal Review. 25 (1–2): 3–14. doi:10.1111/j.1365-2907.1995.tb00432.x.
22. Lehmann, T. (2009). "Phylogeny and systematics of the Orycteropodidae (Mammalia, Tubulidentata)". Zoological Journal of the Linnean Society. 155 (3): 649–702. doi:10.1111/j.1096-3642.2008.00460.x.
23. Tabuce, R.; Asher, R.J.; Lehmann, T (2008). "Afrotherian mammals: a review of current data": 2–14. {{cite journal}}: Cite journal requires |journal= (help)
24. Butler, P.M.; Hopwood, A.T. (1957). "Insectivora and Chiroptera from the Miocene rocks of Kenya Colony". British Museum.
25. Pickford, M. (2007). "A new suiform (Artiodactyla, Mammalia) from the Early Miocene of East Africa". Comptes Rendus Palevol. 6 (3): 221–229. doi:10.1016/j.crpv.2006.11.002. ISSN 1631-0683.
26. Hamilton, W. R. (1978). "Fossil Giraffes from the Miocene of Africa and a Revision of the Phylogeny of the Giraffoidea". Philosophical Transactions of the Royal Society B: Biological Sciences. 283 (996): 165–229. Bibcode:1978RSPTB.283..165H. doi:10.1098/rstb.1978.0019.
27. Grossman, A.; Solounias, N. (2014). "New fossils of Giraffoidea (Mammalia: Artiodactyla) from the Lothidok Formation (Kalodirr Member, early Miocene, West Turkana, Kenya) contribute to our understanding of early giraffoid diversity" (PDF). Zitteliana: 63–70.
28. Peppe, D.J.; McNulty, K.P.; Cote, S.M.; Peppe, D.J.; Harcourt-Smith, W.E.H.; Dunsworth, H.M.; Van Couvering, J.A. (2009). "Stratigraphic interpretation of the Kulu Formation (Early Miocene, Rusinga Island, Kenya) and its implications for primate evolution". Journal of Human Evolution. 56 (5): 447–461. doi:10.1016/j.jhevol.2009.02.006. PMID 19427023.
29. Pickford, M. (2001). "Africa's smallest ruminant: A new tragulid from the miocene of Kenya and the biostratigraphy of east African tragulidae". Geobios. 34 (4): 437–447. doi:10.1016/s0016-6995(01)80007-3.
30. Orliac, M.J. (2009). "The differentiation of bunodont Listriodontinae (Mammalia, Suidae) of Africa: new data from Kalodirr and Moruorot, Kenya". Zoological Journal of the Linnean Society. 157 (3): 653–678. doi:10.1111/j.1096-3642.2008.00525.x.
31. Pickford, M. (1981). "Preliminary Miocene mammalian biostratigraphy for Western Kenya". Journal of Human Evolution. 10 (1): 73–97. doi:10.1016/s0047-2484(81)80026-7.
32. Werdelin, L. (2011). "A new genus and species of Felidae (Mammalia) from Rusinga Island, Kenya, with notes on early Felidae of Africa" (PDF). Estudios Geológicos. 67 (2): 217–222. doi:10.3989/egeol.40480.185. ISSN 0367-0449.
33. Morales, J.; Salesa, M. J.; Pickford, M.; Soria, D. (2001). "A new tribe, new genus and two new species of Barbourofelinae (Felidae, Carnivora, Mammalia) from the Early Miocene of East Africa and Spain". Earth and Environmental Science Transactions of the Royal Society of Edinburgh. 92 (1): 97–102. doi:10.1017/s0263593300000067. S2CID 85704378.
34. Morlo, M.; Miller, E.R.; Bastl, K.; Abdelgawad, M.K.; Hamdan, M.; El-Barkooky, A.N.; Nagel, D. (2019). "New Amphicyonids (Mammalia, Carnivora) from Moghra, Early Miocene, Egypt". Geodiversitas. 41 (1): 731–745. doi:10.5252/geodiversitas2019v41a21. S2CID 208284245.
35. Miller, E.R. (1999). "Faunal correlation of Wadi Moghara, Egypt: implications for the age ofProhylobates tandyi". Journal of Human Evolution. 36 (5): 519–533. doi:10.1006/jhev.1998.0286. PMID 10222167.
36. Morlo, Michael; Friscia, A.; Miller, E.R.; Locke, E.; Nengo, I. (2021). "Systematics and paleobiology of Carnivora and Hyaenodonta from the lower Miocene of Buluk, Kenya". Acta Palaeontologica Polonica. 66 (2). doi:10.4202/app.00794.2020. S2CID 236655608.
37. McNulty, K.P.; Begun, D.R.; Kelley, J.; Manthi, F.K.; Mbua, E.N. (2015). "A systematic revision of Proconsul with the description of a new genus of early Miocene hominoid". Journal of Human Evolution. 84: 42–61. doi:10.1016/j.jhevol.2015.03.009. hdl:2286/R.I.35702. PMID 25962549.
38. Brent, A.; Werdelin, L.; Grossman, A. (2018). "New Miocene Carnivora (Mammalia) from Moruorot and Kalodirr, Kenya" (PDF). Palaeontologia Electronica. 21. doi:10.26879/778.
39. De Bonis, L.; Peigné, S.; Guy, F.; Likius, A.; Makaye, H.T.; Vignaud, P.; Brunet, M. (2009). "A new mellivorine (Carnivora, Mustelidae) from the Late Miocene of Toros Menalla, Chad". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 252 (1): 33–54. doi:10.1127/0077-7749/2009/0252-0033.
40. Cailleux, F. (2021). "A spiny distribution: new data from Berg Aukas I (middle Miocene, Namibia) on the African dispersal of Erinaceidae (Eulipotyphla, Mammalia)" (PDF). Communications of the Geological Survey of Namibia. 23: 178–185.
41. Winkler, A. J. (1992). "Systematics and biogeography of middle Miocene rodents from the Muruyur Beds, Baringo District, Kenya". Journal of Vertebrate Paleontology. 12 (2): 236–249. doi:10.1080/02724634.1992.10011453. JSTOR 4523444.
42. Holroyd, P. A.; Stevens, N. J. (2009). "Differentiation of Phiomys andrewsi from Lavocatomys aequatorialis (n. gen., n. sp.) (Rodentia: Thryonomyoidea) in the Oligo-Miocene interval on continental Africa". Journal of Vertebrate Paleontology. 29 (4): 1331–1334. doi:10.1671/039.029.0415. S2CID 83753674.
43. Winkler, A. J.; MacLatchy, L.; Mafabi, M. (2005). "Small rodents and a lagomorph from the early Miocene Bukwa locality, eastern Uganda" (PDF). Palaeontologia Electronica. 8 (1).
44. Wessels, W.; Fejfar, O.; Peláez-Campomanes, P. (2003). "Miocene small mammals from Jebel Zelten, Libya Micromamíferos miocenos de Jebel Zelten, Libia". Coloquios de Paleontología. 1: 699–715.
45. Mein, P.; Pickford, M. (2003). "Fossil picas (Ochotonidae, Lagomorpha, Mammalia) from the basal Middle Miocene of Arrisdrift, Namibia". Memoir Geological Survey Namibia. 19: 171–176.
46. Bento Da Costa, L.; Senut, B.; Gommery, D.; Pickford, M. (2019). "Dental remains of Lower Miocene small rodents from Napak (Uganda): Afrocricetodontidae, Myophiomyidae, Kenyamyidae and Sciuridae". Annales de Paléontologie. 105 (2): 155–167. doi:10.1016/j.annpal.2019.04.001. S2CID 181429211.
47. Senut, B. (1997). "Postcranial morphology and springing adaptations in Pedetidae from Arrisdrift, Middle Miocene (Namibia)" (PDF). Palaeontologia Africana. 34: 101–109.
48. M. Pickford; B. Senut; S. Musalizi; E. Musiime (2013). "The osteology of Nonanomalurus soniae, a non-volant arboreal rodent (Mammalia) from the early Miocene of Napak, Uganda". Geo-Pal Uganda. 7: 1–33.
49. Antoñanzas, R.L.; Sen, S. (2005). "New species of Paraphiomys (Rodentia, Thryonomyidae) from the lower Miocene of As‐Sarrar, Saudi Arabia". Palaeontology. 48 (2): 223–233. doi:10.1111/j.1475-4983.2005.00445.x. S2CID 85062705.
50. Faulkes, C.G.; Bennett, F.C.; Cotterill, F.P.D.; Stanley, W.; Mgode, G.F.; Verheyen, F. (2011). "Phylogeography and cryptic diversity of the solitary‐dwelling silvery mole‐rat, genus H eliophobius (family: B athyergidae)". Journal of Zoology. 285 (4): 324–338. doi:10.1111/j.1469-7998.2011.00863.x. hdl:2263/19341.
51. Pickford, M.; Mein, P. (2011). "New Pedetidae (Rodentia: Mammalia) from the Mio-Pliocene of Africa" (PDF). Estudios Geológicos. 67 (2): 455–469. doi:10.3989/egeol.40714.202.
52. Barry, J.C. (1988). "Dissopsalis, a middle and late Miocene proviverrine creodont (Mammalia) from Pakistan and Kenya". Journal of Vertebrate Paleontology. 8 (1): 25–45. doi:10.1080/02724634.1988.10011682.
53. Morales, J.; Pickford, M. (2017). "New hyaenodonts (Ferae, Mammalia) from the Early Miocene of Napak (Uganda), Koru (Kenya) and Grillental (Namibia)". Fossil Imprint. 73 (3–4): 332–359. doi:10.2478/if-2017-0019. hdl:10261/195968. S2CID 31350436.
54. Geraads, D.; Miller, E. (2013). "Brachypotherium minor n. sp., and other Rhinocerotidae from the Early Miocene of Buluk, Northern Kenya". Geodiversitas. 35 (2): 359–375. doi:10.5252/g2013n2a5. S2CID 54606359.
55. Churcher, C.S. (2014). "A vacant niche? The curious distributions of African Perissodactyla" (PDF). Transactions of the Royal Society of South Africa. 69 (1): 1–8. doi:10.1080/0035919X.2013.867909. S2CID 55669479.
56. Coombs, M.C.; Cote, S.M. (2010). "Chalicotheriidae". Cenozoic Mammals of Africa. Oakland: University of California Press. pp. 659–667. ISBN 9780520257214.
57. Andrews, P.; Simons, E. (1977). "A New African Miocene Gibbon-Like Genus, Dendropithecus (Hominoidea, Primates) with Distinctive Postcranial Adaptations: Its Significance to Origin of Hylobatidae". Folia Primatologica. 28 (3): 161–169. doi:10.1159/000155807. ISSN 0015-5713. PMID 914128.
58. McCrossin, M. L. (1992). "New species of bushbaby from the middle Miocene of Maboko Island, Kenya". American Journal of Physical Anthropology. 89 (2): 215–233. doi:10.1002/ajpa.1330890207. PMID 1443095.
59. Harrison, T. (2010). "Later Tertiary Lorisiformes". Cenozoic Mammals of Africa. Oakland: University of California Press. pp. 333–349. ISBN 9780520257214.
60. Kunimatsu, Y.; Tsujikawa, H.; Nakatsukasa, M.; Shimizu, D.; Ogihara, N.; Kikuchi, Y.; Nakano, Y.; Takano, T.; Morimoto, N.; Ishida, H. (2017). "A new species of Mioeuoticus (Lorisiformes, Primates) from the early Middle Miocene of Kenya". Anthropological Science. 125 (2): 59–65. doi:10.1537/ase.170322.
61. Cote, S.; McNulty, K.P.; Stevens, N.J.; Odhiambo Nengo, I. (2016). "A detailed assessment of the maxillary morphology of Limnopithecus evansi with implications for the taxonomy of the genus". Journal of Human Evolution. 94: 83–91. doi:10.1016/j.jhevol.2016.01.004. PMID 27178460.
62. Phillips, E. M.; Walker, A. (2000). "A new species of fossil lorisid from the miocene of east africa". Primates. 41 (4): 367–372. doi:10.1007/bf02557647. PMID 30545200. S2CID 22848547.
63. Kunimatsu, Y. (1992). "A revision of the hypodigm of Nyanzapithecus vancouveringi" (PDF). African Study Monographs. 13 (4): 231–235.
64. Gunnell, G. F.; Boyer, D. M.; Friscia, A. R.; Heritage, S.; Manthi, F. K.; Miller, E. R.; Sallam, H.M.; Simmons, N.B.; Stevens, N.J.; Seiffert, E. R. (2018). "Fossil lemurs from Egypt and Kenya suggest an African origin for Madagascar's aye-aye". Nature Communications. 9 (1): 3193. Bibcode:2018NatCo...9.3193G. doi:10.1038/s41467-018-05648-w. PMC 6104046. PMID 30131571.