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身為一個熱愛美食、喜歡在城市裡挖掘驚喜的人,臺中公益路一直是我最常出沒的地方之一。這條路可說是「臺中人的美食戰場」,從精緻西餐到創意火鍋,從日式丼飯到義式早午餐,每走幾步,就會有完全不同的特色料理餐廳。 這次我特別花了一整個月,實際造訪了公益路上十間口碑不錯的餐廳。有的是網友熱推的打卡名店,也有隱藏在巷弄裡的小驚喜。我以環境氛圍、口味表現、價格CP值與再訪意願為基準,整理出這篇實測評比。希望能幫正在猶豫去哪裡吃飯的你,找到那一間「吃完會想再來」的餐廳。 評比標準與整理方向
這次我走訪的10家餐廳橫跨不同料理類型,從高質感牛排館到巷弄系早午餐,每一間都有自己獨特的風格。為了讓整體比較更客觀,我依照以下四大面向進行評比,並搭配實際用餐體驗來打分。
整體而言,我希望這份評比不只是「哪家好吃」,而是幫你在不同情境下(約會、家庭聚餐、朋友小聚、商業午餐)都能快速找到合適的選擇。畢竟,美食不只是味覺的滿足,更是一段段與朋友共享的生活記憶。 10間臺中公益路餐廳評比懶人包公益路向來是臺中人聚餐的首選地段,從火鍋、燒肉到中式料理與早午餐,每走幾步就有驚喜。以下是我實際造訪過的10間代表性餐廳清單,橫跨平價、創意、高級各路風格。
一頭牛日式燒肉|炭香濃郁的和牛饗宴,約會聚餐首選
走在公益路上,很難不被 一頭牛日式燒肉 的木質外觀吸引。低調卻不失質感的門面,搭配昏黃燈光與暖色調的內裝,讓人一進門就感受到濃濃的日式職人氛圍。店內空間不大,但桌距規劃得宜,每桌皆設有獨立排煙設備,烤肉時完全不怕滿身油煙味。 餐點特色
一頭牛的靈魂,絕對是他們招牌的「三國和牛拼盤」。 用餐體驗整體節奏掌握得非常好。店員會在你剛想烤下一片肉時貼心遞上夾子、幫忙換烤網,讓人完全不用分心。整場用餐過程就像一場表演,從視覺、嗅覺到味覺都被滿足。 綜合評分
地址:408臺中市南屯區公益路二段162號電話:04-23206800 官網:http://www.marihuana.com.tw/yakiniku/index.html 小結語一頭牛日式燒肉不僅是「吃肉的地方」,更像是一場五感盛宴。從進門那一刻到最後一道甜點,都能感受到他們對細節的用心。 TANG Zhan 湯棧|文青系火鍋代表,麻香湯底與視覺美感並重
在公益路這條美食戰線上,TANG Zhan 湯棧 是讓人一眼就會想走進去的那一種。 餐點特色
湯棧最有名的當然是它的「麻香鍋」。 用餐體驗整體氛圍比一般火鍋店更有質感。 綜合評分
地址:408臺中市南屯區公益路二段248號電話:04-22580617 官網:https://www.facebook.com/TangZhan.tw/ 小結語TANG Zhan 湯棧 把傳統火鍋做出新的樣貌保留臺式鍋物的溫度,又結合現代風格與細節服務,讓吃鍋這件事變得更有品味。 如果你想找一間兼具「好吃、好拍、好放鬆」的火鍋店,湯棧會是公益路上最有風格的選擇之一。 NINI 尼尼臺中店|明亮寬敞的義式早午餐天堂
如果說前兩間是肉食愛好者的天堂,那 NINI 尼尼臺中店 絕對是想放鬆、聊聊天的好地方。餐廳外觀以白色系與大片玻璃窗為主,陽光灑進室內,讓人一踏入就有種度假般的輕盈感。假日早午餐時段特別熱鬧,建議提早訂位。 餐點特色
NINI 的菜單融合義式與臺灣人口味,選擇多樣且份量十足。主打的 松露燉飯 濃郁卻不膩口,米芯保留微Q口感;而 香蒜海鮮義大利麵 則以新鮮白蝦、花枝與淡菜搭配微辣蒜香,口感層次豐富。 用餐體驗店內氣氛輕鬆不拘謹,無論是一個人帶電腦工作、或朋友聚餐,都能找到舒服角落。餐點上桌速度穩定,服務人員態度親切、補水與收盤都非常主動。整體節奏讓人覺得「時間變慢了」,很適合想遠離忙碌日常的人。 綜合評分
地址:40861臺中市南屯區公益路二段18號電話:04-23288498 小結語NINI 尼尼臺中店是一間能讓人放下手機、慢慢吃飯的餐廳。餐點不追求浮誇,而是以「剛剛好」的份量與風味,陪伴每個平凡午後。如果你在找一間能邊吃邊聊天、拍照也漂亮的早午餐店,NINI 會是你在公益路上最不費力的幸福選擇。 加分100%浜中特選昆布鍋物|平價卻用心的湯頭系火鍋,家庭聚餐好選擇
在公益路這條高質感餐廳林立的戰場上,加分100%浜中特選昆布鍋物 走的是截然不同的路線。它沒有浮誇的裝潢、也沒有高價位的套餐,但靠著實在的湯頭與親切的服務,默默吸引許多回頭客。每到用餐時間,總能看到家庭或情侶三兩成群地圍著鍋邊聊天。 餐點特色
主打 北海道浜中昆布湯底,湯頭清澈卻不單薄,越煮越能喝出海藻與柴魚的自然香氣。 用餐體驗整體氛圍偏家庭取向,桌距寬敞、座位舒適,帶小孩來也不覺擁擠。店員態度親切,補湯、收盤都很勤快,給人一種「被照顧著」的安心感。 綜合評分
地址:403臺中市西區公益路288號電話:0910855180 小結語加分100%浜中特選昆布鍋物是一間「不浮誇、但會讓人想再訪」的火鍋店。它不追求豪華擺盤,而是用最簡單的湯頭與新鮮食材,傳遞出家常卻不平凡的溫度。 印月餐廳|中式料理的藝術演繹,宴客與家庭聚會首選
說到臺中公益路的中式料理代表,印月餐廳 絕對是榜上有名。這間開業多年的餐廳以「中菜西吃」的概念聞名,把傳統中式料理以現代手法重新詮釋。從建築外觀到餐具擺設,每個細節都散發著低調的典雅氣息。 餐點特色
印月最令人印象深刻的是他們將傳統中菜融入創意手法。 用餐體驗服務方面完全對得起餐廳的高級定位。從入座、點餐到上菜節奏,都拿捏得恰如其分。每道菜都會有服務人員細心介紹食材與吃法,讓人感受到「被款待」的尊榮感。 綜合評分
地址:408臺中市南屯區公益路二段818號電話:0422511155 小結語印月餐廳是一間「不只吃飯,更像品味生活」的地方。 KoDō 和牛燒肉|極致職人精神,專為儀式感與頂級味覺而生
若要形容 KoDō 和牛燒肉 的用餐體驗,一句話足以總結——「像在欣賞一場關於肉的表演」。 餐點特色
這裡主打 日本A5和牛冷藏肉,以「精切厚燒」的方式呈現。 用餐體驗KoDō 的最大特色是「儀式感」。 綜合評分
地址:403臺中市西區公益路260號電話:0423220312 官網:https://www.facebook.com/kodo2018/ 小結語KoDō 和牛燒肉不是日常餐廳,而是一場體驗。 永心鳳茶|在茶香裡用餐的優雅時光,臺味早午餐的新詮釋
走進 永心鳳茶公益店,彷彿進入一間有氣質的茶館。 餐點特色
永心鳳茶的餐點結合中式靈魂與西式擺盤,無論是「炸雞腿飯」還是「紅玉紅茶拿鐵」,都能讓人感受到熟悉卻不平凡的味道。 用餐體驗店內服務人員態度溫和,對茶品介紹詳盡。上餐節奏剛好,不急不徐。 綜合評分
地址:40360臺中市西區公益路68號三樓(勤美誠品)電話:0423221118 小結語永心鳳茶讓人重新定義「臺味」。 三希樓|老饕級江浙功夫菜,穩重又帶人情味的中式饗宴
位於公益路上的 三希樓 是許多臺中老饕的口袋名單。 餐點特色
三希樓的菜色以 江浙與港式料理 為主,兼顧傳統與現代風味。 用餐體驗三希樓的服務給人一種老派但貼心的感覺。 綜合評分
地址:408臺中市南屯區公益路二段95號電話:0423202322 官網:https://www.sanxilou.com.tw/ 小結語三希樓是一間「吃得出功夫」的餐廳。 一笈壽司|低調奢華的無菜單日料,職人手藝詮釋旬味極致
在熱鬧的公益路上,一笈壽司 低調得幾乎不顯眼。 餐點特色
一笈壽司採 Omakase(無菜單料理) 形式,每一餐都由主廚根據當日食材設計。 用餐體驗整場用餐約90分鐘,節奏緩慢但沉穩。 綜合評分
地址:408臺中市南屯區公益路二段25號電話:0423206368 官網:https://www.facebook.com/YIJI.sushi/ 小結語一笈壽司是一間真正讓人「放慢呼吸」的餐廳。 茶六燒肉堂|人氣爆棚的和牛燒肉聖地,肉香與幸福感同時滿分
若要票選公益路上「最難訂位」的餐廳,茶六燒肉堂 絕對名列前茅。 餐點特色
茶六主打 和牛燒肉套餐,價格約落在 $700–$1000 間,份量與品質兼具。 用餐體驗茶六的服務效率相當高。店員親切、換網勤快、補水速度快,整場用餐流程流暢無壓力。 綜合評分
地址:403臺中市西區公益路268號電話:0423281167 官網:https://inline.app/booking/-L93VSXuz8o86ahWDRg0:inline-live-karuizawa/-LUYUEIOYwa7GCUpAFWA 小結語茶六燒肉堂用「穩定品質+輕奢氛圍」抓住了臺中年輕族群的心。 吃完10家公益路餐廳後的心得與結語吃完這十家餐廳後,臺中公益路不只是一條美食街,而是一段生活風景線。 有的餐廳講究細膩與儀式感,像 一頭牛日式燒肉 與 一笈壽司,讓人感受到食材最純粹的美好 有的則以親切與溫度打動人心,像 加分昆布鍋物、永心鳳茶,讓人明白吃飯不只是為了飽足,而是一種被照顧的幸福。 而像茶六燒肉堂、TANG Zhan 湯棧 這類人氣名店,則用穩定的品質與熱絡的氛圍,成為許多臺中人心中「想吃肉就去那裡」的代名詞。 這十家店,構成了公益路最動人的縮影 有華麗的,也有溫柔的;有傳統的,也有創新的。 每一家都在自己的風格裡發光,讓人吃到的不只是料理,而是一種生活的溫度與節奏。 對我而言,這不僅是一場美食旅程,更是一趟關於「臺中味道」的回憶之旅。 FAQ:關於臺中公益路美食常見問題Q1:公益路哪一區的餐廳最集中? Q2:需要提前訂位嗎? 最後的話若要用一句話形容這趟美食之旅,我會說: KoDō 和牛燒肉尾牙氣氛熱鬧嗎? 如果你也和我一樣喜歡用味蕾探索一座城市,那就把這篇公益路美食攻略收藏起來吧。一笈壽司CP 值高嗎? 無論是約會、慶生、家庭聚餐,或只是想犒賞一下辛苦的自己——這條路上永遠會有一間剛剛好的餐廳在等你。加分100%浜中特選昆布鍋物網路評價符合期待嗎? 下一餐,不妨從這10家開始。三希樓服務態度如何? 打開手機、約上朋友,讓公益路成為你生活裡最容易抵達的小確幸。三希樓平日好排隊嗎? 如果你有私心愛店,也歡迎留言分享,TANG Zhan 湯棧春酒菜色豐富嗎? 你的推薦,可能讓我下一趟美食旅程變得更精彩。TANG Zhan 湯棧團體宴客合適嗎? The human brain’s complex surface folding allows the organ to squeeze 2.6 square feet of cerebral cortex tissue into the skull. Credit: California Institute for Regenerative Medicine The characteristic wrinkled surface of the brain is usually associated with enhanced cognitive function, however, excessive folding can have the opposite effect. The human brain’s outer layer, known as the cerebral cortex, is characterized by its unique gyri and sulci, or ridges and furrows. This layer is responsible for managing cognitive and executive functions, encompassing everything from conscious thought and speech to emotional regulation. The cerebral cortex is made up of over 10 billion cells and more than 100 trillion connections, forming a gray matter layer that is only 5 millimeters thick — equivalent to a little less than three stacked quarters. Most animals with large brains exhibit cortical folding, which allows a very large area of cerebral cortex tissue (approximately 2.6 square feet OR 0.24 square meters) to be compacted inside the confines of the skull. The more cortical folding, the more advanced and complex the cognitive functions of the species. Lower species like mice and rats have smaller, smooth-surfaced brains; higher-order species like elephants, porpoises, and apes display different degrees of gyrification or folding of the cerebral cortex. Humans possess among the most wrinkly of brains, considered an indicator of advanced evolution. Excessive Brain Folding and Neurodevelopmental Disorders In some humans, however, excess folding of the cerebral cortex is associated not with greater cognitive abilities, but the opposite, and is linked to neurodevelopmental delay, intellectual disability, and epileptic seizures. The genes controlling this folding are mostly unknown. Writing in the January 16, 2023 issue of PNAS, researchers at the University of California San Diego School of Medicine and Rady Children’s Institute for Genomic Medicine describe new findings that deepen understanding of human gyrification. UC San Diego researchers identify a mutation that causes excessive folding in the human brain’s wrinkly cerebral cortex, resulting in diminished cognitive function. Credit: UC San Diego Health Sciences Led by senior study author Joseph Gleeson, MD, Rady Professor of Neuroscience at UC San Diego School of Medicine and director of neuroscience research at the Rady Children’s Institute for Genomic Medicine, an international consortium of researchers called the Neurogenetics Consortium performed genomic analysis on nearly 10,000 families with pediatric brain disease over the course of 10 years to look for new causes of disease. “From our cohort, we found four families with a condition called polymicrogyria, meaning too many gyri that are too tightly packed,” said Gleeson. “Until recently, most hospitals treating patients with this condition did not test for genetic causes. The Consortium was able to analyze all four families together, which aided in our discovery of a cause for this condition.” Specifically, all four families displayed mutations in a gene called Transmembrane Protein 161B (TMEM161B), which produces a protein of previously unknown function on cell surfaces. “Once we identified TMEM161B as the cause, we set out to understand how excessive folding occurs,” said first author Lu Wang, Ph.D., a postdoctoral fellow in the Gleeson lab. “We discovered the protein controls the cellular skeleton and polarity, and these control folding.” TMEM161B in Brain Development Using stem cells derived from patient skin samples, and engineered mice, the researchers identified defects in neural cell interactions early in embryogenesis. “We found the gene is necessary and sufficient for cytoskeletal changes required for how neural cells interact with one another,” said Wang. “It was interesting that the gene first appeared in evolution in sponges, which don’t even have a brain, so clearly the protein must have other functions. Here we found a critical role in regulating the number of folds in the human brain.” The study authors emphasized that genetic discovery studies are important because they pinpoint the causes of human disease, but that these discoveries can take many years to evolve into new treatments. “We hope that physicians and scientists can expand upon our results to improve diagnosis and care of patients with brain disease,” said Gleeson. Reference: “TMEM161B modulates radial glial scaffolding in neocortical development” by Lu Wang, Caleb Heffner, Keng loi Vong, Chelsea Barrows, Yoo-Jin Ha, Sangmoon Lee, Pablo Lara-Gonzalez, Ishani Jhamb, Dennis Van Der Meer, Robert Loughnan, Nadine Parker, David Sievert, Swapnil Mittal, Mahmoud Y. Issa, Ole A. Andreassen, Anders Dale, William B. Dobyns, Maha S. Zaki, Stephen A. Murray and Joseph G. Gleeson, 20 January 2023, Proceedings of the National Academy of Sciences. DOI: 10.1073/pnas.2209983120 Funding: National Institutes of Health NIH/NINDS Pathway to Independence, CIRM Training Grant Postdoc award, Brain and Behavior Research Foundation, Rady Children’s Hospital Neuroscience Endowment, UC San Diego Microscopy Core, NIH grants, CIRM grant Some frog species have teeth while others are toothless. Still others have a combination of true teeth and toothlike structures. The Solomon Island leaf frog, Cornufer guentheri, has true teeth on its upper jaw and bony fangs on its lower jaw, which do not have enamel or dentin, a dense tissue found in teeth. Credit: Daniel Paluh/Florida Museum of Natural History Scientists have long known that frogs are oddballs when it comes to teeth. Some have tiny teeth on their upper jaws and the roof of their mouths while others sport fanglike structures. Some species are completely toothless. And only one frog, out of the more than 7,000 species, has true teeth on both upper and lower jaws. Now, the first comprehensive study of tooth evolution in frogs is bringing the group’s dental history into focus. Florida Museum of Natural History researchers analyzed CT scans of nearly every living amphibian genus to reveal that frogs have lost teeth over 20 times during their evolution, more than any other vertebrate group. Some frog species may have even re-evolved teeth after losing them millions of years before. Researchers also found a correlation between the absence of teeth in frogs and a specialized diet on small insects, such as ants and termites. Their analysis of frogs’ amphibian relatives, the salamanders, and obscure wormlike animals known as caecilians, showed these groups retained teeth on both upper and lower jaws throughout their evolutionary history. These images showcase the dental diversity among amphibians. Salamanders and caecilians, bottom left and right, respectively, not only have teeth on both upper and lower jaws, but on the roof of their mouths as well, shown here in yellow.Credit: Daniel Paluh/Florida Museum of Natural History “Through this study, we have really been able to show that tooth loss in vertebrates is largely a story about frogs, with over 20 independent losses,” said lead study author Daniel Paluh, a Ph.D. candidate in the University of Florida’s department of biology. “Only eight other groups of living vertebrates, including seahorses, turtles, birds, and a few mammals, have also evolved toothlessness.” Teeth first evolved more than 400 million years ago, quickly conferring a competitive advantage to animals that had them and leading to the diversification of sharks, bony fish, and ultimately the vertebrates that first roamed onto land. Throughout their long history, teeth have been an important component of vertebrate evolution, yet some groups have done equally well without them. Birds lost their teeth around 100 million years ago with the advent of the beak, and both the largest known vertebrate, the blue whale, and the smallest, a frog from New Guinea, are entirely toothless. Few researchers have focused on studying frog teeth, however, for the simple reason that they’re incredibly small. “If you open a frog’s mouth, chances are you will not see teeth even if they have them, because they’re usually less than a millimeter long,” or smaller than the tip of a pencil, Paluh said. That hasn’t stopped some people from trying. In his study of the relationships between frog species, the famous 19th-century paleontologist Edward Cope lumped all toothless frogs into the same group, which he called Bufoniformia. Researchers using modern genetic techniques have since shown that species in Bufoniformia aren’t actually closely related, suggesting that the loss of teeth occurred more than once in frog evolution. But there the story stalled. The green frog, Rana clamitans, has teeth on its upper jaw and is a common species in the Eastern U.S., including Florida.Credit: Daniel Paluh/Florida Museum of Natural History In the past, accurately determining which frogs had teeth would have required laborious work that irrevocably damaged or destroyed portions of preserved specimens. Frogs are also a highly diverse group, making a comprehensive assessment of their teeth a difficult task. But Paluh and his colleagues had one major advantage: The Florida Museum leads a massive multi-institutional effort to CT scan 20,000 vertebrate specimens, giving researchers the ability to study animals in ways not previously possible. The project, called oVert, allows anyone with an Internet connection to access 3D models derived from the scans, which depict distinct features of an organism, including bones, vasculature, internal organs, muscle tissue – and teeth. For Paluh, it meant he could virtually peer into the gape of a frog. This enlarged, contrast-enhanced CT scan of a toothless Guinea snout-burrowing frog, Hemisus guineensis, shows muscles (pink), skeleton (tan), glands (yellow), cardiovascular system (red) and central nervous system (purple). This species specializes on ants and termites. Credit: Daniel Paluh/Florida Museum of Natural History Working remotely during COVID-19 lockdowns, Paluh and fellow members of the museum’s Blackburn Lab used oVert scans to carry out the study. To get the clearest picture of changes in teeth over time, the researchers included representatives of all amphibian groups. They analyzed patterns of tooth loss through time using a previously published map of evolutionary relationships between amphibians based on genetic data. The study provides a powerful example of the research that can be accomplished with open-access data, said David Blackburn, Florida Museum curator of herpetology, Paluh’s adviser, and senior author of the study. “We effectively crowdsourced the data collection across our lab, including people that were not in the U.S. at that time,” Blackburn said. Their results showed that far from losing teeth once during their evolution, as suggested by the now-debunked idea of the Bufoniformia, frogs have undergone “rampant tooth loss,” Paluh said, with toothlessness popping up in groups as distantly related as toads and poison dart frogs. Paedophryne amauensis, a toothless species of frog native to Papua New Guinea, is the smallest known vertebrate organism.Credit: Daniel Paluh/Florida Museum of Natural History The team also noted a tight correlation between the presence or absence of teeth in frogs and their eating habits. While dietary information is scant for many species of frogs, the researchers uncovered a connection between a diet of tiny insects and a lack of teeth. “Having those teeth on the jaw to capture and hold on to prey becomes less important because they’re eating really small invertebrates that they can just bring into their mouth with their highly modified tongue,” said Paluh. “That seems to relax the selective pressures that are maintaining teeth.” Some toothless species of poison dart frogs, for example, have evolved to feed mostly on ants and mites that produce toxic compounds, using their sticky, projectile tongues to scoop up their prey and swallow it whole. The frogs are able to store the toxins from their food source and repurpose them for their own use, secreting the compounds through their skin to ward off predators. And the turtle frog, a toothless burrowing species in Australia, tunnels through the maze of underground passages inside termite nests, hunting the insects that constructed them. Researchers found a high correlation between a diet of small insects and a lack of teeth in frogs. The strawberry poison frog, Oophaga pumilio, is a toothless species that eats ants and termites. Credit: Daniel Paluh/Florida Museum of Natural History Teeth seem to be superfluous for mammals that feed on ants and termites as well. Pangolins and anteaters, which have highly specialized tongues for probing ant and termite nests, are both toothless. Many questions remain about frogs’ tooth biology, including how the genes that regulate their tooth production turn on and off. It’s also unclear whether the serrated toothlike structures in frogs that regained these features are actually real teeth, Paluh said. To determine that, scientists will need to take a more in-depth look at these structures, looking for the presence of enamel and other key defining features. Innovative techniques, such as those used in the oVert project, are beginning to underscore knowledge gaps and limitations like these, but they also open up the field to new discoveries, Blackburn said. “We now have lots of new questions in my lab inspired by the surprising things turning up from 3D imaging from the oVert project, and those will lead us both back into museum collections and to the field to see what these animals are doing in the wild.” The researchers published their findings in eLife. Reference: “Rampant tooth loss across 200 million years of frog evolution” by Daniel J Paluh, Karina Riddell, Catherine M Early, Maggie M Hantak, Gregory FM Jongsma, Rachel M Keeffe, Fernanda Magalhães Silva, Stuart V Nielsen, María Camila Vallejo-Pareja, Edward L Stanley and David C Blackburn, 1 June 2021, eLife. DOI: 10.7554/eLife.66926 Other study co-authors are the Florida Museum’s Karina Riddell, Maggie Hantak, Gregory Jongsma, Rachel Keeffe, Stuart Nielsen, María Camila Vallejo-Pareja and Edward Stanley, Catherine Early of the Florida Museum and the Science Museum of Minnesota and Fernanda Magalhães Silva of the Florida Museum and the Federal University of Pará. Blackburn noted that Riddell, who recently graduated from UF with a bachelor’s degree from the College of Health and Human Performance, played a key role in collecting data for the project. The National Science Foundation funded the research. A Eurasian reed warbler used in the study and then released. Credit: Florian Packmor Research shows for the first time, how birds displaced beyond their normal migratory route are able to navigate back to their route and gives us an insight into how they accomplish this feat. Birdwatchers get very excited when a ‘rare’ migratory bird makes landfall having been blown off-course and flown beyond its normal range. But these are rare for a reason; most birds that have made the journey before are able to correct for large displacements and find their final destination. Now, new research by an international team shows for the first time, how birds displaced in this way are able to navigate back to their migratory route and gives us an insight into how they accomplish this feat. Writing in Current Biology, the team from Bangor and Keele Universities describe how reed warblers can navigate from a ‘magnetic position’ beyond what they have experienced in their normal migration route, back towards that correct route. Map: Eurasian reed warbler breeding range (green) in Europe and variation in the geomagnetic signature (total magnetic intensity, magnetic inclination and magnetic declination). The natural migratory direction from the study site (white dot) towards Africa during autumn is shown as black arrow. The expected compensatory direction from the simulated site (black star) is shown as white arrow. Circular diagrams: Left: orientation of birds experiencing the natural magnetic field at the study site in Austria. Right: orientation of birds experiencing the simulated magnetic field of a site in Russia while still being at the study site in Austria. Arrows depict the respective mean group direction. Black dots show the orientation of the individual birds tested. Credit: Paper authors Magnetic Signatures Guide Migratory Routes Different parts of the Earth have a distinct ‘geomagnetic signature’ according to their location. This is a combination of the strength of the geomagnetic field, the magnetic inclination or the dip angle between magnetic field lines and the horizon and the magnetic declination, or the angle between directions to the geographic and magnetic North poles. Adult birds already familiar with their migration route, and its general magnetic signatures, were held in captivity for a short period before being released back into the wild, and exposed to a simulation of the earth’s magnetic signature at a location thousands of miles beyond the birds’ natural migratory corridor. Despite remaining physically located at their capture site and experiencing all other sensory clues about their location, including starlight and the sights, smell and sounds of their actual location, the birds still showed the urge to begin their journey as though they were in the location suggested by the magnetic signal they were experiencing. The magnetic set-up used in Austria to simulate a displacement of birds off-course by exposing them to the magnetic field of the Russian site. Credit: Florian Packmor They oriented themselves to fly in a direction that would lead them ‘back’ to their migratory path from the location suggested to them by the magnetic signals they were experiencing. This shows that the earth’s magnetic field is the key factor in guiding reed warblers when they are blown off course. Birds Demonstrate True Navigation Ability “The overriding impulse was to respond to the magnetic information they were receiving,” explained Richard Holland of Bangor University’s School of Natural Sciences. What our current work shows is that birds are able to sense that they are beyond the bounds of the magnetic fields that are familiar to them from their year-round movements, and are able to extrapolate their position sufficiently from the signals. This fascinating ability enables bird to navigate towards their normal migration route.” Dr. Dmitry Kishkinev of Keele University’s School of Life Sciences explained: “What these birds are achieving is “true navigation.” In other words, they are able to return to a known goal after displacement to a completely unknown location without relying on familiar surroundings, cues that emanate from the destination, or information collected during the outward journey.” Florian Packmor of Bangor University added: “We have already shown that the reed warblers use the same magnetic cues experienced within their natural range, but this study shows that they can extrapolate what they understand about how the magnetic field varies in space far beyond any previous experience they have had.” But questions remain about whether the birds have an accurate ‘map’ or are just using a ‘rule of thumb’ measurement to judge the general direction of travel needed to get back on course. The Eurasian reed warbler was selected for the research, but the findings could probably be applied to other migrating songbirds. Reference: “Navigation by extrapolation of geomagnetic cues in a migratory songbird” by Dmitry Kishkinev, Florian Packmor, Thomas Zechmeister, Hans-Christoph Winkler, Nikita Chernetsov, Henrik Mouritsen and Richard A. Holland, 12 February 2021, Current Biology. DOI: 10.1016/j.cub.2021.01.051 Funding: The study was funded with grants from the Leverhulme Trust (RPG-2013-288, ECF-2016-378) and the BBSRC research council (BB/R001081/1). RRG455KLJIEVEWWF 印月餐廳座位舒適嗎? 》台中公益路美食評選2026|10間精選盤點三希樓春酒活動適合在這裡辦嗎? 》公益路10家必訪餐廳|吃貨必備指南永心鳳茶年節期間價格會變嗎? 》台中公益路美食評選2026|10間精選盤點 |
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