字體:小 中 大 |
|
|
|||||||||||||||||||||||||||||||||||||||||||||
| 2025/12/25 01:18:59瀏覽58|回應0|推薦0 | |||||||||||||||||||||||||||||||||||||||||||||
跟著城市嚮導「老臺北胃」,用味道認識臺北很多朋友來臺北, 我怎麼選出這 10 大臺北小吃?在臺北, 一吃就知道:這就是臺灣味燒烤、火鍋很好吃, 不只是好吃,而是有「臺北日常感」臺北的小吃迷人,
吃完之後,你會記得臺北最後一個標準很簡單。 接下來的 10 樣臺北小吃, 第 1 家:饌堂-黑金滷肉飯(雙連店)|一碗就懂臺灣人的日常
如果只能用一道料理, 為什麼第一站,我會選饌堂? 不只是好吃,而是「現在的臺北感」 老臺北胃的帶路小提醒
這不是那種吃完會驚呼「哇!」的料理, 地址:103臺北市大同區雙連街55號1樓 電話:0225501379 第 2 家:富宏牛肉麵|臺北深夜也醒著的一碗熱湯
如果說滷肉飯代表的是臺灣人的日常, 為什麼老臺北胃會帶你來吃富宏? 不分時間,任何時候都適合的一碗麵 老臺北胃的帶路小提醒
這不是精緻料理, 地址:108臺北市萬華區洛陽街67號 電話:0223713028 菜單:https://www.facebook.com/pages/富宏牛肉麵-原建宏牛肉麵/ 第 3 家:士林夜市・吉彖皮蛋涼麵|臺北夏天最有記憶點的一口清爽
如果你在夏天來到臺北, 為什麼在夜市,我會帶你吃涼麵? 皮蛋,是靈魂,也是臺灣味的關鍵 老臺北胃的帶路小提醒
這不是華麗的小吃, 原來臺北的小吃,連氣候都一起考慮進去了。 地址:111臺北市士林區基河路114號 電話:0981014155 菜單:https://www.facebook.com/profile.php?id=100064238763064 第 4 家:胖老闆誠意肉粥|臺北人深夜最踏實的一碗粥
如果你問我, 為什麼這一碗粥,會被叫做「誠意」? 這不是觀光小吃,而是臺北人的生活片段
這些畫面, 老臺北胃的帶路小提醒
這不是為了拍照而存在的小吃, 地址:10491臺北市中山區長春路89-3號 電話:0913806139 第 5 家:圓環邊蚵仔煎|夜市裡最不能缺席的臺灣經典
如果要選一道 為什麼蚵仔煎,這麼能代表臺灣? 圓環邊,吃的是記憶感 老臺北胃的帶路小提醒
蚵仔煎不是細嚼慢嚥的料理, 地址:103臺北市大同區寧夏路46號 電話:0225580198 菜單:https://oystera.com.tw/menu 第 6 家:阿淑清蒸肉圓|第一次吃肉圓,就該從這裡開始
說到臺灣小吃, 清蒸肉圓,和你想像的不一樣 為什麼我會推薦給第一次來臺北的旅客? 老臺北胃的帶路小提醒
這不是夜市裡熱鬧喧囂的料理, 地址:242新北市新莊區復興路一段141號 電話:0229975505 第 7 家:胡記米粉湯|一碗最貼近臺北早晨的味道
如果說前面幾樣小吃, 為什麼米粉湯,這麼「臺北」? 配菜,才是這一碗的靈魂延伸 老臺北胃的帶路小提醒
這不是為了觀光而存在的小吃, 地址:106臺北市大安區大安路一段9號1樓 電話:0227212120 第 8 家:藍家割包|一口咬下的臺灣街頭記憶
如果要選一道 割包,為什麼被叫做「臺灣漢堡」? 藍家割包不是走浮誇路線, 老臺北胃的帶路小提醒
割包不是精緻料理, 地址:100臺北市中正區羅斯福路三段316巷8弄3號 電話:0223682060 菜單:https://instagram.com/lan_jia_gua_bao?utm_medium=copy_link 第 9 家:御品元冰火湯圓|臺北夜晚最溫柔的一碗甜
吃了一整天的臺北小吃, 為什麼叫「冰火」?這碗湯圓的關鍵就在這裡 這是一碗,會讓人慢下來的甜點 老臺北胃的帶路小提醒
這不是為了拍照而存在的甜點, 地址:106臺北市大安區通化街39巷50弄31號 電話:0955861816 菜單:https://instagram.com/lan_jia_gua_bao 第 10 家:頃刻間綠豆沙牛奶專賣店|把臺北的味道,留在最後一口清甜
走到這一站, 綠豆沙牛奶,為什麼這麼「臺灣」? 為什麼我會用它當作最後一站? 老臺北胃的帶路小提醒
這一杯, 地址:111臺北市士林區小北街1號 電話:0228818619 菜單:https://instagram.com/chill_out_moment?igshid=YmMyMTA2M2Y= 如果只有 3 天的自助旅行在臺北,怎麼吃這 10 家?第一次來臺北, 臺北 3 天小吃推薦行程表(老臺北胃版本)
雖然每個小吃的地點都有一點距離,但是你也知道,好吃的小吃,是值得你花一點時間前往品嘗
當你照著這 3 天走完, 老臺北胃帶路|這 10 口,就是我心中的臺北
寫到這裡, 如果你問我,
如果你是第一次來臺北, 士林夜市-吉彖皮蛋涼麵在地人怎麼說? 走完這 10 家, 你可能會發現一件事饌堂-黑金滷肉飯(雙連店)推薦點什麼? 臺北的小吃,其實不急著被你記住。 它們就安靜地存在在街角、夜市、轉彎處,富宏牛肉麵排隊值得嗎? 等你有一天,再回到這座城市。阿淑清蒸肉圓會不會膩? 如果你是第一次來臺北,富宏牛肉麵容易接受嗎? 希望這份「老臺北胃帶路」的清單, 能幫你少一點猶豫、多一點安心。 不用擔心踩雷,胖老闆誠意肉粥口味會太重嗎? 也不用為了排行而奔波,胡記米粉湯不排隊會可惜嗎? 只要照著節奏走, 你就會吃到屬於自己的臺北味道。 而如果你已經來過臺北, 那更希望這篇文章,阿淑清蒸肉圓不排隊會可惜嗎? 能帶你走進那些 你可能錯過、卻一直都在的日常小吃。 因為真正迷人的旅行, 從來不是把清單全部打勾, 而是某一天, 你突然想起那碗飯、那口湯、那杯甜,胖老闆誠意肉粥值得吃嗎? 然後在心裡對自己說一句:御品元冰火湯圓適合第一次吃嗎? 「下次再去臺北,還想再吃一次。」 把這篇文章存起來、分享給一起旅行的人, 或是在規劃行程時,再回來看看。 讓味道,成為你認識臺北的方式。 下一次來臺北, 別急著走遠。 老臺北胃,阿淑清蒸肉圓在地人怎麼說? 會一直在這些地方, 等你再回來。 Still frame image showing the hindfoot of a live Wandering Salamander (Aneides vagrans) from a ventral perspective just before the salamander takes a step forward. This image shows the large digital blood sinuses and the points at which they connect near the distal-most joint. Credit: William P. Goldenberg Wandering salamanders control blood flow in their toes to improve grip and detachment, a finding that may inspire new adhesive and robotic technologies. Wandering salamanders are known for gliding high through the canopies of coastal redwood forests, but how these small amphibians manage to stick their landings and take off with ease remains somewhat of a mystery. A new study in the Journal of Morphology suggests the answer may lie in a surprising mechanism: blood-powered toes. Researchers led by Washington State University discovered that wandering salamanders (Aneides vagrans) can rapidly fill, trap, and drain blood in their toe tips, optimizing attachment, detachment, and overall locomotion in their arboreal environment. The research not only uncovers a previously unknown physiological mechanism in salamanders but also has implications for bioinspired designed. Insights into salamander toe mechanics could ultimately inform the development of adhesives, prosthetics, and even robotic appendages. A Wandering Salamander (Aneides vagrans) clings to a camera lens with a single forelimb after leaping onto the lens during scientific investigation of their jumping, parachuting, and gliding behaviors. Credit: Christian Brown “Gecko-inspired adhesives already allow surfaces to be reused without losing stickiness,” said Christian Brown, lead author of the study and an integrative physiology and neuroscience postdoctoral researcher at WSU. “Understanding salamander toes could lead to similar breakthroughs in attachment technologies.” Discovery sparked by a documentary shoot Salamanders of the Aneides genus have long puzzled scientists with their square-shaped toe tips and bright red blood “lakes” that can be seen just beneath their translucent skin. Historically, these features were thought to aid oxygenation, but no evidence supported that claim. Brown’s interest in the topic traces back to an unexpected observation during the filming of the documentary, “The Americas,” which airs on Feb. 23 on NBC and Peacock. While assisting on set as the resident salamander expert, Brown had the opportunity to observe through the production team’s high-powered camera lenses how the amphibians move around. He noticed something strange. Blood was rushing into the small creatures’ translucent toe tips moments before they took a step. Brown and camera assistant William Goldenberg repeatedly observed the phenomenon. “We looked at each other like, ‘Did you see that?’” Brown said. A Wandering Salamander (Aneides vagrans) stands/clings to a horizontal/vertical surface while a camera and high-powered lens capture the blood activity within the toes. Credit: Christian Brown Though the producers moved on, Brown’s curiosity didn’t. After the shoot, he reached out to Goldenberg and asked if he was interested in using his film equipment to investigate what they had observed in a scientific and repeatable way. Through high-resolution video trials and corroborating analysis in WSU’s Franceschi Microscopy & Imaging Center, Brown, Goldenberg and colleagues at WSU and Gonzaga University uncovered that wandering salamanders can finely control and regulate blood flow to each side of their toe tips. This allows them to adjust pressure asymmetrically, improving grip on irregular surfaces like tree bark. Surprisingly, the blood rushing in before “toe off” appears to help salamanders detach rather than attach. By slightly inflating the toe tip, the salamanders reduce the surface area in contact with the surface they are on, minimizing the energy required to let go. This dexterity is crucial for navigating the uneven and slippery surfaces of the redwood canopy—and for sticking safe landings when parachuting between branches. “If you’re climbing a redwood and have 18 toes gripping bark, being able to detach efficiently without damaging your toe tips makes a huge difference,” Brown said. The implications of the research could extend beyond Aneides vagrans. Similar vascularized structures are found in other salamander species, including aquatic ones, suggesting a universal mechanism for toe stiffness regulation that may serve different purposes depending on the salamander’s environment. Moving forward, Brown and colleagues plan to expand the research to look at how the mechanism works in other salamander species and habitats. “This could redefine our understanding of how salamanders move across diverse habitats,” Brown said. Reference: “Vascular and Osteological Morphology of Expanded Digit Tips Suggests Specialization in the Wandering Salamander (Aneides vagrans)” by Christian E. Brown, William P. Goldenberg, Olivia M. Hinds, Mary Kate O’Donnell and Nancy L. Staub, 8 January 2025, Journal of Morphology. DOI: 10.1002/jmor.70026 A study reveals significant declines in moth populations across all life stages in a subtropical urban setting, underscoring the impact of urbanization on insect biodiversity and suggesting practical conservation measures. Insects of all stripes are in the midst of a vanishing act, a catastrophic sleight-of-hand occurring so rapidly that scientists can’t keep up. Things get even trickier when you consider that insects have a complex life cycle with eggs, larvae, pupae, and adults. Are they all disappearing at equal rates, or are some faster than others? Few people have checked. In a new study, researchers presented the results of a year-long survey in which they monitored the abundance of adult and larval moths in an urban, sub-tropical environment. It’s the first time researchers have analyzed multiple life stages to assess the severity of ongoing insect declines. It’s also one of only a few studies that have tackled the problem in lower latitudes, where extreme temperatures are pushing animals to their limit. “Subtropical and tropical environments have the greatest insect abundance and diversity and are areas seeing the greatest expansion of cities worldwide,” said lead author Michael Belitz, who conducted the research while working at the Florida Museum of Natural History. “The urban heat island effect in these areas may be especially detrimental to insects.” Urban Heat and Its Effects Regardless of where they’re located, modern cities have a heat problem. In natural or rural environments, a significant portion of the sun’s light is harmlessly reflected back into space. But asphalt and concrete absorb more light, transforming it into heat. During the day, this can make cities up to 7 degrees Fahrenheit warmer than surrounding areas, creating bubbles of dangerously high temperatures called heat islands. In lower latitudes, where temperatures are already high, this heat trap can have disastrous consequences for those trapped inside. “There’s no doubt that insect declines are a real phenomenon. The harder question to answer is where these declines are happening fastest. Is it different in tropical compared to temperate regions?” said co-author Robert Guralnick, curator of biodiversity informatics at the Florida Museum of Natural History. Moths are declining at an alarming rate in urban areas due to a combination of habitat loss and pollution. Credit: Florida Museum of Natural History. Base map from OpenStreetMap, open database license. To find out, the team devised a survey in which they collected moths from several sites with varying levels of development in Alachua County, Florida. Catching adult moths was easy; all team members needed was a light source to lure them in. Caterpillars, on the other hand, are not drawn to artificial light and spend most of their time in the tree canopy, making them hard to find. But moth larvae are a critical component of natural and urban ecosystems, and Belitz was reluctant to leave them out. “Caterpillars are an important food source for breeding birds,” he said. “Even if birds are seed eaters as adults, they feed their young caterpillars.” Although caterpillars spend most of their time out of reach, there’s at least one way to estimate their abundance: their poop! Larvae continuously excrete the digested remnants of decimated leaves in the form of pellets, which drop to the forest floor. Belitz put out funnels attached to collection jars beneath trees at each site. By weighing the amount of poop that fell inside each week, he calculated rough estimates of how many caterpillars there were. Findings from the Study By the end of the year, they’d collected more than 35,000 moths, which they categorized as macro- or micro-moths. The first group includes well-known species like luna and io moths, which have comparatively large wings and are able to travel great distances. Micro moths — in this case, considered to be anything 10 millimeters or less in length — included the innumerable leaf-rollers, plant-borers, and grass moths, with cloak-like wings and colors that come in a mind-boggling variety of beiges and browns. The distinction between large and small is important. Larger moths are better equipped to navigate fragmented habitats and are more likely to escape from a heat dome if it becomes too hot. Micro-moths are restricted to smaller areas, which may make them more vulnerable to temperature swings. Large io moths were once common throughout eastern North America but have since declined in number due in part to urbanization. Credit: Andrei Sourakov The results showed a strong pattern of decline among moths of all sizes and life stages from rural to urban areas. A closer look at the macromoths alone revealed that, contrary to expectations, larger macromoths fared worse than those that were smaller. This runs counter to a previous study conducted in Belgium, which showed the opposite pattern. Belitz suspects the difference in average temperature between temperate Europe and subtropical Florida is the culprit. Large moths must expend more energy to keep cool than those that are small. Similar patterns have been seen in other insects, Belitz said. “Generally, in arthropods, urbanization selects for smaller body size because there’s less metabolic stress.” They also found that moths with a varied diet were better suited to city life than those with refined palates. Some caterpillars feed on a single species of plant and are among the first to disappear when an area is developed. Moths whose larvae can get by with several different plant species are more resilient in the face of urbanization. Most worringly of all, the team took samples only from protected areas yet still observed marked declines. “You might think that you’re looking at a natural environment when you walk into a city park, because it looks intact,” Guralnick said. “The truth is, what you see is a completely different community than those that exist in places like wildlife management areas.” Alachua County is also relatively undeveloped compared with other parts of Florida. The domino-effect of biodiversity loss in a part of the state that maintains hundreds of acres of protected land bodes ill for other cities. “It’s shocking to see how strong these declines are in a city that’s not deeply urbanized,” Guralnick said. “We’re talking town-sized, as opposed to something like New York City.” But all is not lost, Belitz said. Moths and other insects still eke out an existence on the margins of urban areas, and increasing their numbers is, in some ways, as simple as creating the right environment for them, which anyone can do. “Native plants are a really important way to increase biodiversity,” he said. “You can increase the number of pollinators in your yard by growing host plants.” Light pollution in urban environments also disrupts the internal navigation system of many insects. “It creates ecological traps, where moths are drawn to light and then get picked off by bats. Turning out lights at night is a truly actionable thing people can do that has a large, positive effect for insects and other animals.” Reference: “Substantial urbanization-driven declines of larval and adult moths in a subtropical environment” by Michael W. Belitz, Asia Sawyer, Lillian K. Hendrick, Akito Y. Kawahara and Robert P. Guralnick, 25 March 2024, Global Change Biology. DOI: 10.1111/gcb.17241 Scientists have discovered an ancient sponge species, Helicolocellus, in China, dating back 550 million years, offering new insights into sponge evolution and filling a crucial gap in their early fossil record. Reconstructed life position of Helicolocellus on Ediacaran seafloor. Credit: Yuan Xunlai The discovery of the late Ediacaran sponge, Helicolocellus, offers new insights into early sponge evolution, suggesting non-biomineralizing forms existed about 550 million years ago and bridging a critical evolutionary gap between the Ediacaran and Cambrian periods. Prof. Yuan Xunlai and his team at the Nanjing Institute of Geology and Palaeontology, a part of the Chinese Academy of Sciences, have uncovered a crown-group sponge from the late Ediacaran period named Helicolocellus in the Shibantan Biota located in Hubei Province. This fossil biota dates back approximately 550 million years. This finding, which fills an important gap in the early evolution of sponges, was recently published in Nature. Sponges are often considered to be the most basal and primitive metazoan phylum. Early sponge fossils can provide important clues to the origin and early evolution of animals. Molecular clock estimates and controversial biomarker data suggest that sponges should have appeared around 700 million years ago. Enigmatically, however, no unambiguous sponge fossils have been found before the Cambrian Period (about 539 million years ago). Therefore, a 160-million-year gap exists in the sponge fossil record, a period in early sponge evolution known as the “lost years.” Phylogenetic position of Helicolocellus. Helicolocellus is resolved as a stem-group hexactinellid along with other fossil sponges. Credit: Yuan Xunlai Theories on the Absence of Precambrian Sponges Two competing hypotheses have been proposed to explain the absence of Precambrian sponges: One hypothesis holds that, since most extant sponges have siliceous or calcareous spicules, the common ancestor of sponges also had mineralized spicules. Under this hypothesis, the absence of Precambrian sponge fossils can be attributed to poor preservation potential due to the chemical composition of porewaters. The other hypothesis holds that the common ancestor of sponges was non-biomineralizing animals. Only after the emergence of major classes did they independently evolve biomineralized spicules. Therefore, early Precambrian sponges lacked spicules, thus making it difficult for these sponges to be preserved and identified in the fossil record. The newly discovered Helicolocellus shows morphological characteristics similar to those of glass sponges (Hexactinellida), such as a radially symmetric conical body, a discoidal attachment structure, a possible central cavity, and inferred excurrent canals. In addition, the surface of Helicolocellus consists of regular boxes, each of which is divided into four similar but smaller boxes, which in turn are subdivided into even smaller ones. This unique grid pattern is also found in some typical Paleozoic hexactinellids. Their shapes and structures are very similar; however, the grids in Helicolocellus are made of organic matter, whereas the grids in Paleozoic sponge fossils are made of biomineralized spicules. This study suggests that Helicolocellus may represent an early sponge without biomineralized spicules. Holotype of Helicolocellus cantori gen. et sp. nov., NIGP-176531. (a), Photographed under reflected light. (b), Topographic elevation map from laser scanning microscopy. Credit: Yuan Xunlai To further test this interpretation, the researchers constructed a morphological data matrix containing several extant and fossil animals and performed a rigorous phylogenetic analysis. The results show that Helicolocellus belongs to the crown group of sponges and is closely related to the hexactinellids. The discovery of Helicolocellus indicates that non-biomineralizing sponges did exist in the Precambrian. It suggests that modern sponges should not be used as the sole guide for finding Precambrian sponge fossils, as early sponges may not have had biomineralized spicules and may not have had all the features of modern sponges. Moreover, early hexactinellid sponges first laid out the reticulate skeletal blueprint using organic material, and later added siliceous biominerals to the recipe for skeletal formation in the Cambrian. Fossil assemblages on either side of the Ediacaran-Cambrian boundary are extremely disparate. The Ediacaran Period is dominated by the enigmatic and phylogenetically unknown Ediacara Biota, while in the Cambrian, modern marine ecosystems begin to take shape with the emergence of extant animal phyla. The discovery of Helicolocellus bridges the Ediacaran and Cambrian fossil assemblages, indicating that the Ediacara Biota have evolutionary links to Cambrian animals. As one reviewer commented, the discovery of Helicolocellus may be the “Rosetta Stone” for understanding animal evolution. Reference: “A late-Ediacaran crown-group sponge animal” by Xiaopeng Wang, Alexander G. Liu, Zhe Chen, Chengxi Wu, Yarong Liu, Bin Wan, Ke Pang, Chuanming Zhou, Xunlai Yuan and Shuhai Xiao, 5 June 2024, Nature. DOI: 10.1038/s41586-024-07520-y RE98915RGPOIOKJ 饌堂-黑金滷肉飯(雙連店)值得排隊嗎? 》【台北小吃美食地圖】10大餐廳評比|從燒肉到中餐,最完整的一篇!圓環邊蚵仔煎在地人怎麼說? 》台北小吃餐廳推薦|10間必吃美食實測評比藍家割包會不會太油? 》台北夜市美食巡禮|10家好吃到想回訪 |
|||||||||||||||||||||||||||||||||||||||||||||
| ( 知識學習|政治 ) |























