LOST HORIZONS 2018 CATALOGUE Table Of

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WELCOME TO LOST HORIZONS 2018 CATALOGUE Table of Contents Great Plants/Wonderful People . 15. Nomenclatural Notes . 15. Some History . 16. Availability . .17 . Recycle . 17 Location . 17 Hours . 18 Note on Hardiness . 18. Gift Certificates . 18. Lost Horizons Garden Design, Consultation, and Construction . 19. Understanding the catalogue . 19. References . 20. Catalogue . 21. Perennials . .21 . Acanthus . .21 . Achillea . .21 . Aconitum . 21. Actaea . .22 . Adenophora . 23. Agastache . .23 . Ajuga . 23. Alchemilla . 24. Allium . .24 . Alstroemeria . .25 . Alyssum . 25. Amsonia . 25. Anemone . .26 . Anemonella . .27 . Anemonopsis . 27. Angelica . 28. Anthemis . .28 . Anthericum . .28 . For more info go to www.losthorizons.ca - Page 1 Aquilegia . 29. Arabis . .29 . Aralia . 29. Arenaria . 30. Arisaema . .30 . Arisarum . .31 . Armeria . .31 . Armoracia . .32 . Artemisia . 32. Arum . .32 . Aruncus . .33 . Asarum . .33 . Asclepias . .33 . Asparagus . .34 . Asphodeline . 34. Aster . .34 . Astilbe . .35 . Astilboides . 35. Astragalus . .36 . Astrantia . .36 . Aubrieta . 37. Baptisia . .37 . Begonia . .38 . Bergenia . 38. Bletilla . 38. Boehmeria . .39 . Bolax . .39 . Brunnera . .39 . Buphthalmum . .40 . Cacalia . 40. Caltha . 41. Campanula . 41. For more info go to www.losthorizons.ca - Page 2 Cardamine . .42 . Cardiocrinum . 42. Caryopteris(Perennial) . 43. Cassia . 43. Caulophyllum . .43 . Centaurea . 44. Cephalaria . .44 . Chelone . .44 . Chelonopsis . 45. Chiastophyllum . .45 . Chloranthus . .45 . Chrysanthemum . ..

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Appendix 1. Results for the Species Not in Database
Supporting information for: Pärtel, J., Pärtel, M. & Wäldchen, J. 2021. Plant image identification application demonstrates high accuracy in Northern Europe. AoB PLANTS. Appendix 1. Results for the species not in database Taxa not known to the machine learning model, i.e. those on which the classifier was not trained, could not be recognized. The model is unable to determine whether an image belongs to an unknown taxon it has never seen before and will wrongly identify a known taxon with the highest degree of similarity. Typically, the highest degree of similarity is still so low that no suggestions will be given for the user. Here we extracted the best match information directly from the Flora Incognita server but did not use these species in our analyses since the model’s prediction can only be interpreted in a meaningful way for taxa on which it was actually trained. The five unknown species were only found in the database study. Some of them were garden plants, or had a northern or eastern distribution. (1) Draba incana has an arcotmontane distribution which reach its SW border in Estonia, the most similar species in the Flora Incognita database was Arabis hirsuta. (2) Lychnis chalcedonica originates from continental Eurasia but is used as an ornamental garden plant. In Estonia it sometimes spreads to nature. Flora Incognita is focusing on European natural plants, even if many naturalized ones are included. The most similar species found was Phlox paniculata. (3) Moehringia lateriflora is distributed in Eurasia, reaching in its E border in Estonia. The most similar match was Cardamine californica.
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Dil Limbu.Pmd
Nepal Journal of Science and Technology Vol. 13, No. 2 (2012) 87-96 A Checklist of Angiospermic Flora of Tinjure-Milke-Jaljale, Eastern Nepal Dilkumar Limbu1, Madan Koirala2 and Zhanhuan Shang3 1Central Campus of Technology Tribhuvan University, Hattisar, Dharan 2Central Department of Environmental Science Tribhuvan University, Kirtipur, Kathmandu 3International Centre for Tibetan Plateau Ecosystem Management Lanzhou University, China e-mail:[email protected] Abstract Tinjure–Milke–Jaljale (TMJ) area, the largest Rhododendron arboreum forest in the world, an emerging tourist area and located North-East part of Nepal. A total of 326 species belonging to 83 families and 219 genera of angiospermic plants have been documented from this area. The largest families are Ericaceae (36 species) and Asteraceae (22 genera). Similarly, the largest and dominant genus was Rhododendron (26 species) in the area. There were 178 herbs, 67 shrubs, 62 trees, 15 climbers and other 4 species of sub-alpine and temperate plants. The paper has attempted to list the plants with their habits and habitats. Key words: alpine, angiospermic flora, conservation, rhododendron Tinjure-Milke-Jaljale Introduction determines overall biodiversity and development The area of Tinjure-Milke-Jaljale (TMJ) falls under the activities. With the increasing altitude, temperature middle Himalaya ranging from 1700 m asl to 5000 m asl, is decreased and consequently different climatic and geographically lies between 2706’57" to 27030’28" zones within a sort vertical distance are found. The north latitude and 87019’46" to 87038’14" east precipitation varies from 1000 to 2400 mm, and the 2 longitude. It covers an area of more than 585 km of average is about 1650 mm over the TMJ region.
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Conserving Europe's Threatened Plants
Conserving Europe’s threatened plants Progress towards Target 8 of the Global Strategy for Plant Conservation Conserving Europe’s threatened plants Progress towards Target 8 of the Global Strategy for Plant Conservation By Suzanne Sharrock and Meirion Jones May 2009 Recommended citation: Sharrock, S. and Jones, M., 2009. Conserving Europe’s threatened plants: Progress towards Target 8 of the Global Strategy for Plant Conservation Botanic Gardens Conservation International, Richmond, UK ISBN 978-1-905164-30-1 Published by Botanic Gardens Conservation International Descanso House, 199 Kew Road, Richmond, Surrey, TW9 3BW, UK Design: John Morgan, [email protected] Acknowledgements The work of establishing a consolidated list of threatened Photo credits European plants was first initiated by Hugh Synge who developed the original database on which this report is based. All images are credited to BGCI with the exceptions of: We are most grateful to Hugh for providing this database to page 5, Nikos Krigas; page 8. Christophe Libert; page 10, BGCI and advising on further development of the list. The Pawel Kos; page 12 (upper), Nikos Krigas; page 14: James exacting task of inputting data from national Red Lists was Hitchmough; page 16 (lower), Jože Bavcon; page 17 (upper), carried out by Chris Cockel and without his dedicated work, the Nkos Krigas; page 20 (upper), Anca Sarbu; page 21, Nikos list would not have been completed. Thank you for your efforts Krigas; page 22 (upper) Simon Williams; page 22 (lower), RBG Chris. We are grateful to all the members of the European Kew; page 23 (upper), Jo Packet; page 23 (lower), Sandrine Botanic Gardens Consortium and other colleagues from Europe Godefroid; page 24 (upper) Jože Bavcon; page 24 (lower), Frank who provided essential advice, guidance and supplementary Scumacher; page 25 (upper) Michael Burkart; page 25, (lower) information on the species included in the database.
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Extrapolating Demography with Climate, Proximity and Phylogeny: Approach with Caution
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GENOME EVOLUTION in MONOCOTS a Dissertation
GENOME EVOLUTION IN MONOCOTS A Dissertation Presented to The Faculty of the Graduate School At the University of Missouri In Partial Fulfillment Of the Requirements for the Degree Doctor of Philosophy By Kate L. Hertweck Dr. J. Chris Pires, Dissertation Advisor JULY 2011 The undersigned, appointed by the dean of the Graduate School, have examined the dissertation entitled GENOME EVOLUTION IN MONOCOTS Presented by Kate L. Hertweck A candidate for the degree of Doctor of Philosophy And hereby certify that, in their opinion, it is worthy of acceptance. Dr. J. Chris Pires Dr. Lori Eggert Dr. Candace Galen Dr. Rose‐Marie Muzika ACKNOWLEDGEMENTS I am indebted to many people for their assistance during the course of my graduate education. I would not have derived such a keen understanding of the learning process without the tutelage of Dr. Sandi Abell. Members of the Pires lab provided prolific support in improving lab techniques, computational analysis, greenhouse maintenance, and writing support. Team Monocot, including Dr. Mike Kinney, Dr. Roxi Steele, and Erica Wheeler were particularly helpful, but other lab members working on Brassicaceae (Dr. Zhiyong Xiong, Dr. Maqsood Rehman, Pat Edger, Tatiana Arias, Dustin Mayfield) all provided vital support as well. I am also grateful for the support of a high school student, Cady Anderson, and an undergraduate, Tori Docktor, for their assistance in laboratory procedures. Many people, scientist and otherwise, helped with field collections: Dr. Travis Columbus, Hester Bell, Doug and Judy McGoon, Julie Ketner, Katy Klymus, and William Alexander. Many thanks to Barb Sonderman for taking care of my greenhouse collection of many odd plants brought back from the field.
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University of Copenhagen, 1353 Copenhagen, Denmark
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Rock Garden Quarterly
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By Sonali Padhye, Cathy Whitman, Erik Runkle and Art Cameron
*Cameron 9/21/05 9:07 AM Page 72 variety information Cool Campanula Cooling and daylength can regulate flowering of some campanula species and cultivars. By Sonali Padhye, Cathy Whitman, Erik Runkle and Art Cameron he genus campanula contains more than 300 species, many of which are of Northern origins. Campanula species are com- monly referred to as bellflowers and can add a great splash of blue, white or red to any perennial garden. TMany campanulas such as C. carpatica, C. portenschlagiana and C. poscharskyana thrive in cool temperatures and high light conditions, making them very suitable for the springs and summers in Northern Europe. Therefore, it is not surprising that in Northern Europe campanulas are extremely popular and almost a staple in any perennial garden. Several campanulas, especially many noteworthy cultivars such as C. punctata ‘Cherry Bells’ and campan- ula ‘Kent Belle’ are report- edly adaptable to high heat and humidity. A few cam- panulas, including C. rotun- difolia, are native to the United States and offer great untapped potential to gardeners and plant breed- ers looking for new plant material. Smaller-sized campanulas such as C. carpatica form charming mounds of flowers in small Long days with containers and are impor- Short days Long days supplemental light tant potted flowering crops. Several campanulas suit- Top: Campanula punctata ‘Cherry Bells’ forced at 68° F without vernalization treatment did not flower able for domestic condi- under (from left to right) 9-hour photoperiod, 16-hour photoperiod provided by incandescent lamps and 16-hour photoperiod provided by high-pressure sodium lamps.
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History and Current Status of Systematic Research with Araceae
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