| 1.
New fossil endocarps of Sambucus (Adoxaceae) from the upper Plioce..
[1812]
|
| 2.
First discovery of Cucubalus (Caryophyllaceae) fossil, and its bio..
[1183]
|
| 3.
A new Drynaria (Polypodiaceae) from the Upper Pliocene of Southwes..
[975]
|
| 4.
云南景谷早中新世翅子树属叶片化石的发现及其古生态和植物地理学意义
[969]
|
| 5.
Quantitative reconstruction of the Late Miocene monsoon climates o..
[918]
|
| 6.
Paleoclimatic estimation reveals a weak winter monsoon in southwes..
[905]
|
| 7.
A new Quercus species from the upper Miocene of southwestern China..
[902]
|
| 8.
Evidence for insect-mediated skeletonization on an extant fern fam..
[871]
|
| 9.
Late Miocene southwestern Chinese floristic diversity shaped by th..
[801]
|
| 10.
Continuous existence of Zanthoxylum (Rutaceae) in Southwest China ..
[766]
|
| 11.
Miocene to Pleistocene floras and climate of the Eastern Himalayan..
[751]
|
| 12.
New Biogeographic insight into Bauhinia s.l. (Leguminosae): integr..
[739]
|
| 13.
A Miocene leaf fossil record of Rosa (R. fortuita n. sp.) from its..
[667]
|
| 14.
Phylogeographic analysis reveals significant spatial genetic struc..
[558]
|
| 15.
Warm-cold colonization: response of oaks to uplift of the Himalaya..
[534]
|
| 16.
Regional constraints on leaf physiognomy and precipitation regress..
[521]
|
| 17.
First occurrence of Cedrelospermum (Ulmaceae) in Asia and its biog..
[497]
|
| 18.
青藏高原--现代生物多样性形成的演化枢纽
[484]
|
| 19.
Late Miocene vegetation dynamics under monsoonal climate in southw..
[476]
|
| 20.
新生代青藏高原生长对东亚水循环及生态系统的影响
[449]
|
| 21.
The intensification of the East Asian winter monsoon contributed t..
[445]
|
| 22.
Vegetation changes across the Eocene-Oligocene transition: Global ..
[439]
|
| 23.
Leaf form-climate relationships on the global stage: an ensemble o..
[424]
|
| 24.
The occurrence of Pinus massoniana Lambert (Pinaceae) from the upp..
[421]
|
| 25.
New U-Pb dates show a Paleogene origin for the modern Asian biodiv..
[413]
|
| 26.
The leaf physiognomy of evergreen and deciduous species exhibits d..
[405]
|
| 27.
Resilience of plant-insect interactions in an oak lineage through ..
[403]
|
| 28.
The oldest Mahonia (Berberidaceae) fossil from East Asia and its b..
[402]
|
| 29.
A new positive relationship between pCO(2) and stomatal frequency ..
[398]
|
| 30.
Fossil seeds of Euryale (Nymphaeaceae) indicate a lake or swamp en..
[394]
|
| 31.
An early Oligocene occurrence of the palaeoendemic genus Dipteroni..
[387]
|
| 32.
A tropical forest of the middle Miocene of Fujian (SE China) revea..
[382]
|
| 33.
Biotic interchange through lowlands of Tibetan Plateau suture zone..
[363]
|
| 34.
Occurrence of Christella (Thelypteridaceae) in Southwest China and..
[359]
|
| 35.
The first megafossil record of Goniophlebium (Polypodiaceae) from ..
[358]
|
| 36.
The first fossil record of ring-cupped oak (Quercus L. subgenus Cy..
[356]
|
| 37.
古近纪/新近纪之交青藏高原陆地生态系统的重大转折
[354]
|
| 38.
Vegetation history of the central Tibetan region during the late O..
[349]
|
| 39.
Fossil infructescence from southwestern China reveals Paleogene es..
[346]
|
| 40.
Artificial neural networks reveal a high-resolution climatic signa..
[341]
|
| 41.
The oldest fossil record of Bauhinia s.s. (Fabaceae) from the Tibe..
[341]
|
| 42.
Large-scale dataset from China gives new insights into leaf margin..
[336]
|
| 43.
A new Tsuga species from the upper Miocene of Yunnan, southwestern..
[334]
|
| 44.
SEQUOIA MAGUANENSIS, A NEW MIOCENE RELATIVE OF THE COAST REDWOOD, ..
[331]
|
| 45.
Organellomic data sets confirm a cryptic consensus on (unrooted) l..
[330]
|
| 46.
Podocarpium (Fabaceae) from the late Eocene of central Tibetan Pla..
[330]
|
| 47.
Late Miocene Palaeocarya (Engelhardieae: Juglandaceae) from Southw..
[326]
|
| 48.
The earliest fossil bamboos of China (middle Miocene, Yunnan) and ..
[323]
|
| 49.
East Asian origins of European holly oaks (Quercus section Ilex Lo..
[317]
|
| 50.
Distribution of Cenozoic plant relicts in China explained by droug..
[314]
|
| 51.
新生代特提斯海区域的气候演变及其驱动因素
[310]
|
| 52.
A Miocene leaf fossil record of Rosa (R-fortuita n. sp.) from its ..
[309]
|
| 53.
Heterogeneous occurrence of evergreen broad-leaved forests in East..
[309]
|
| 54.
Lake geochemistry reveals marked environmental change in Southwest..
[307]
|
| 55.
Late Pliocene temperatures and their spatial variation at the sout..
[304]
|
| 56.
Tibetan Plateau: An evolutionary junction for the history of moder..
[295]
|
| 57.
西藏芒康似勾儿茶叶属(鼠李科)化石及其生物地理学意义
[293]
|
| 58.
Tibetan Plateau palm fossils prove the Kohistan-Ladakh Island Arc ..
[293]
|
| 59.
TESTING THE BIASES IN THE RICH CENOZOIC ANGIOSPERM MACROFOSSIL REC..
[291]
|
| 60.
Variations in Leaf Morphological Traits of Quercus guyavifolia (Fa..
[291]
|
| 61.
Miocene Ulmus fossil fruits from Southwest China and their evoluti..
[291]
|
| 62.
Fire dynamics under monsoonal climate in Yunnan, SW China: past, p..
[290]
|
| 63.
Early Oligocene Itea (Iteaceae) leaves from East Asia and their bi..
[290]
|
| 64.
始新世-渐新世气候转折期的植被变化:全球信号与区域特征
[289]
|
| 65.
A new fossil species of Cryptomeria (Cupressaceae) from the Rupeli..
[288]
|
| 66.
Oligocene Koelreuteria (Sapindaceae) from the Lunpola Basin in cen..
[277]
|
| 67.
Hemitrapa Miki (Lythraceae) from the earliest Oligocene of southea..
[275]
|
| 68.
Bauhinia (Leguminosae) Fossils from the Paleogene of Southwestern ..
[275]
|
| 69.
Oligocene Limnobiophyllum (Araceae) from the central Tibetan Plate..
[274]
|
| 70.
Habitat, climate and potential plant food resources for the late M..
[272]
|
| 71.
The rise and demise of the Paleogene Central Tibetan Valley
[270]
|
| 72.
云南景谷早中新世翅子树属叶片化石的发现及其古生态和植物地理学意义
[269]
|
| 73.
Past East Asian monsoon evolution controlled by paleogeography, no..
[268]
|
| 74.
Miocene Exbucklandia (Hamamelidaceae) from Yunnan, China and its b..
[265]
|
| 75.
植物长刺的秘密
[263]
|
| 76.
Fire dynamics under monsoonal climate in Yunnan, SW China: past, p..
[262]
|
| 77.
Climate evolution and its driving factors in the Tethys Sea region..
[262]
|
| 78.
青藏高原及其周边古近纪综合地层、生物群与古地理演化
[256]
|
| 79.
First fossil of Pterolobium (Leguminosae) from the Middle Miocene ..
[254]
|
| 80.
New fossil record of Cladium (Cyperaceae) from the Middle Miocene ..
[244]
|
| 81.
Biotic interchange through lowlands of Tibetan Plateau suture zone..
[242]
|
| 82.
A new fossil record of Palaeosinomenium (Menispermaceae) from the ..
[242]
|
| 83.
First fossil of Pterolobium (Leguminosae) from the Middle Miocene ..
[240]
|
| 84.
Paleoclimate model-derived thermal lapse rates: Towards increasing..
[239]
|
| 85.
Rubus (Rosaceae) diversity in the late Pliocene of Yunnan, southwe..
[237]
|
| 86.
Hemitrapa Miki (Lythraceae) from the earliest Oligocene of southea..
[233]
|
| 87.
西藏始新世狭叶梅属(Palibinia)的发现及其地质学和生物学意义
[233]
|
| 88.
The Paleogene to Neogene climate evolution and driving factors on ..
[229]
|
| 89.
Early Oligocene vegetation and climate of southwestern China infer..
[226]
|
| 90.
Leaf and infructescence fossils of Alnus (Betulaceae) from the lat..
[225]
|
| 91.
The disappearance of Metasequoia (Cupressaceae) after the middle M..
[223]
|
| 92.
Major turnover of biotas across the Oligocene/Miocene boundary on ..
[222]
|
| 93.
The relationship between leaf physiognomy and climate based on a l..
[221]
|
| 94.
吉隆盆地中中新世以来孢粉组合及古环境演化
[220]
|
| 95.
The relationship between leaf physiognomy and climate based on a l..
[217]
|
| 96.
No high Tibetan Plateau until the Neogene
[215]
|
| 97.
Fossil leaves of Buxus (Buxaceae) from the Upper Pliocene of Yunna..
[209]
|
| 98.
The morphology of phytoliths for tropical pteridophytes in southwe..
[209]
|
| 99.
A primitive honey bee from the Middle Miocene deposits of southeas..
[208]
|
| 100.
Understanding the evolution of biodiversity in Asia
[208]
|
