BSEB 10th, 12th compartmental result 2025 declared at results.biharboardonline.com: Check direct link here
Bihar Board announces Class 10, 12 compartment and special exam results 2025
BSEB 10th, 12th compartmental result 2025: The Bihar School Examination Board (BSEB) has officially declared the results for the Class 10 and Class 12 Compartmental and Special Examinations 2025.
The announcement was made by BSEB Chairman Anand Kishor on the official website results.biharboardonline.com. Students who appeared for these exams can now check and download their results online. The exams were held for students who either failed in one or two subjects or opted to improve their scores.
Overall, the results reveal varying pass percentages across different categories. The Class 12 compartment exam recorded a pass percentage of 61.13%, while the special exam for Class 12 stood at 55.31%.
For Class 10, the special exam pass percentage was 52.20%, whereas the compartment exam pass percentage was significantly lower at 32.93%. These figures give an insight into the performance of students across both classes in the supplementary assessments.
Performance of science toppers in compartment exams
Among the students who appeared for the compartment exams, several science stream toppers have emerged.
by Taboola
by Taboola
Sponsored Links
Sponsored Links
Promoted Links
Promoted Links
You May Like
Runwal Raaya 3, 4, 5 Bed at ₹10.99 Cr* | Royal Living Where the Sky Touches Your Dreams
Runwal Realty
Get Offer
Undo
These students showed remarkable improvement and dedication in their retake examinations. While the overall pass percentage reflects a moderate success rate, the science toppers' results highlight their ability to overcome earlier setbacks and secure good marks. Their success stories are inspiring examples of perseverance and hard work in the face of academic challenges.
How to check BSEB 10th and 12th compartmental results online
Students can follow these simple steps to access their results online:
Step 1: Visit the official Bihar Board result websites: biharboardonline.bihar.gov.in or results.biharboardonline.com
Step 2: Click on the 'Compartmental Examination' section on the homepage
Step 3: Select either 'Bihar Board 10th Compartment Result 2025' or 'Bihar Board 12th Step Compartment Result 2025'
Step 4: Enter your Roll Code and Roll Number in the provided fields
Step 5: Click the 'Submit' button to view your result
Step 6: Download and save a copy of the result for future reference
Direct link to check the BSEB 10th and 12th compartmental result 2025
Details mentioned on the marksheet
The online marksheet contains crucial information for each student, including their name, roll number, and roll code.
It also displays subject-wise marks, maximum marks, division, and the final result status (Pass/Fail). The list of subjects taken by the student is also clearly mentioned. Students are advised to download their digital marksheets and keep them safely until they receive the physical mark sheets from their respective schools.
Exam Type
Pass Percentage
Class 12 Special Exam
55.31%
Class 12 Compartment
61.13%
Class 10 Special Exam
52.20%
Class 10 Compartment
32.93%
Students who have successfully cleared the compartment or special exams can now proceed with higher education admissions or other academic plans. For any queries or discrepancies, candidates are encouraged to contact BSEB officials through the board's helpline or official email.
The Bihar School Examination Board's timely announcement of these results provides relief to many students and their families, ensuring that their academic journey can continue without unnecessary delays.
Ready to empower your child for the AI era? Join our program now! Hurry, only a few seats left.
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Time of India
an hour ago
- Time of India
Can crocodiles and alligators make babies? Scientists finally reveal the truth
Can crocodiles and alligators make babies? Scientists finally reveal the truth Alligators and crocodiles, two of the most ancient and powerful reptiles on Earth, have fascinated humans for centuries with their fearsome appearances and shared traits. Both belong to the order Crocodylia, exhibit similar body structures, and are apex predators dominating swamps, rivers, and wetlands. Their evolutionary lineage stretches back over 80 million years, leading many to wonder: can these two closely related creatures mate and produce offspring? Despite their surface similarities, the answer isn't as straightforward as it seems. Here, you can explore the deep genetic divides, evolutionary divergence, and reproductive barriers that reveal why a crocodile-alligator hybrid is biologically implausible. Why crocodiles and alligators are family—but not that close While alligators and crocodiles share the same order, Crocodylia, they diverge at the family level. Alligators belong to the family Alligatoridae, which includes alligators and caimans, whereas crocodiles are part of the Crocodylidae family. This taxonomic separation indicates significant evolutionary divergence, leading to distinct genetic makeups and physiological differences. Why alligators and crocodiles can't crossbreed The evolutionary paths of alligators and crocodiles split approximately 90 million years ago. by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like Buy Brass Idols - Handmade Brass Statues for Home & Gifting Luxeartisanship Buy Now Undo This extensive period allowed for substantial genetic drift and the development of unique adaptations suited to their environments. Such a prolonged separation has resulted in considerable genetic incompatibility, making interbreeding highly improbable. Genetic incompatibility: The barrier to hybridization For two species to produce viable offspring, their genetic material must be compatible. In the case of alligators and crocodiles, their DNA sequences have diverged to the extent that successful fertilization and embryo development are virtually impossible. Even in controlled environments where both species coexist, there is no documented evidence of hybrid offspring. Behavioral and reproductive differences Beyond genetic factors, behavioral and reproductive differences further hinder the possibility of interbreeding. Alligators and crocodiles have distinct mating rituals, nesting behaviors, and breeding seasons. These differences reduce the likelihood of mating attempts, even in shared habitats like the Florida Everglades. Instances of hybridization in other crocodilian species While alligators and crocodiles cannot interbreed, hybridization has been observed among certain crocodile species. For example, the American crocodile (Crocodylus acutus) and the Cuban crocodile (Crocodylus rhombifer) have produced hybrid offspring in overlapping territories. These instances are exceptions rather than the norm and are limited to species within the same genus.
Time of India
14 hours ago
- Time of India
Shubhanshu Shukla set to script history as India's second astronaut in space
India's Shubhanshu Shukla is set for his maiden space flight as part of Axiom Space 's fourth commercial mission to the International Space Station, which is scheduled for lift-off onboard SpaceX's Falcon-9 rocket from the Kennedy Space Centre in Florida on June 8. The launch of the Dragon spacecraft will take place not earlier than 6:41 pm IST from NASA's spaceport in Florida, making Shukla only the second Indian to travel to space four decades after Rakesh Sharma's iconic spaceflight onboard Russia's Soyuz spacecraft in 1984. Besides Shukla, the mission pilot for the Axiom-4 mission, the other crew include Slawosz Uznanski-Wisniewski from Poland and Tibor Kapu from Hungary, marking both European nation's first travel to the International Space Station in history and the second government-sponsored human spaceflight mission in over 40 years. by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like Gain expertise in Deep Learning & NLP with AI & ML BITS Pilani WILP Apply Now Undo Veteran US astronaut Peggy Whitson will be the commander of the Axiom-4 mission. "I am really, really excited to go into microgravity and experience spaceflight on my own," Shukla, who goes by the nickname 'Shuks', said at a press conference in January. Live Events Once docked, the astronauts plan to spend up to 14 days aboard the orbiting laboratory, conducting science, outreach, and commercial activities. The Ax-4 astronauts will perform around 60 scientific studies and activities representing 31 countries during their 14-day stay at the ISS . Shukla is set to conduct exclusive food and nutrition-related experiments developed under a collaboration between the Indian Space Research Organisation (ISRO) and the Department of Biotechnology (DBT), with support from NASA. The experiments aim to pioneer space nutrition and self-sustaining life support systems vital for future long-duration space travel. ISRO has lined up a set of seven experiments for Shukla, who will also participate in five joint studies planned by NASA for its human research program. It has drawn up plans to focus on India-centric food for carrying out experiments on the ISS, including sprouting methi (Fenugreek) and moong (green gram) in microgravity conditions. Shukla will also expose the seeds to the macrobiotic conditions and bring them back to earth where they will be cultivated in plants not just once but over generations. In January, Shukla said he also planned to capture his experiences on board the ISS through pictures and videos which can be shared with all the "'Bharatvaasis' back home." "I want them to share this thrilling experience through my eyes, for I truly believe that, even as an individual travelling to space, this is the journey of 1.4 billion people," he said. Shukla said he planned to take certain items from different parts of the country with him to the ISS during the 14-day mission and even expressed hope to serve Indian food to astronauts in the orbital laboratory. He said the experience on the Axiom Mission 4 would be very well utilised on the Gaganyaan mission which is planned for 2027. ISRO is spending Rs 550 crore on the Axiom-4 mission.
Time of India
21 hours ago
- Time of India
‘Gold arrived on our planet as Earth was forming 4.5 billion years ago — it holds an extraordinary history'
Jun Korenaga Jun Korenaga is Professor of Earth and Planetary Sciences at Yale University . He tells Srijana Mitra Das at TE about how gold got to Earth: It's a little surprising to connect to Jun Korenaga , not least because the scientist is sitting against the backdrop of a planetary surface that could be — but doesn't have to be — Mars. Speaking with purple rock and feathery clouds in a sunless sky behind him, Korenaga explains the origins of gold — and Earth. 'My work focuses on estimating early Earth's history. In the last few years, I've worked on the Hadean Eon which was about 4.5 billion years ago — this is the most mysterious part of our planet's history because we don't have a rock record for it. I work on the theoretical side and try to reconstruct what early Earth looked like.' Gold is part of early Earth's story, although in unexpected ways. A symbol of stability now, gold had quite a dramatic past. Supernovae or cataclysmic stellar explosions and star collisions occurred in the universe. The extreme pressure of such imploding stars was so high, subatomic protons and electrons got pushed into their core — these formed neutrons. Rapid neutron capture by iron then created heavy elements like uranium, lead, silver and gold. Interestingly, this process occurred very, very swiftly — and then, these elements were expelled into space. by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like News For Jack Nicholson, 87, He Has Been Confirmed To Be... Reportingly Undo (Photos: Getty images) Thus, metals like gold and platinum arrived on Earth while our planet was still forming. Korenaga explains, 'About 4.5 billion years ago, Earth was hit by a Mars-sized rock and the moon formed as the debris from this collision went into an Earth-orbiting disk. More bombardment followed — there were plenty of leftover rocks orbiting the sun as well and several fell on young Earth. The landing of these objects is known as 'late accretion', comprising about the last 1% of planetary growth. In this period, some of the rocks which fell on Earth had metallic components like gold.' Importantly, gold and platinum are among highly siderophile elements (HSEs) — these are metals with an extremely strong affinity for iron. Korenaga smiles slightly and says, 'Now, if Earth was created with no funny twists in its story, we actually wouldn't have any gold on our planet's surface because, sticking to iron, this was heavy and should have gone straight down into the core which we cannot access. But we do have gold on the surface, which shows that part of Earth's mantle can retain metallic components.' Korenaga's research, conducted with Simone Marchi , posits the notion that there is a thin or 'transient' part of the mantle where shallow areas melt away and a deeper region stays solid. This part could hold falling metallic components and reach them to the mantle. In the simulations the scientists conducted, as a rock crashed onto Earth, it hit a localised liquid magma ocean where heavy metals sank to the bottom. As these reached the partially molten area underneath, the metal would start sinking further down — then, the molten mantle solidified, capturing the metal there. But how did this re-emerge to the part of Earth's surface humans could access? As Korenaga says, 'The part of the mantle which contains this metallic component is heavier and more chemically dense than the rest — to bring it up, you have to offset that density by being hotter than normal as hotter materials usually have lower density. Thus, thermal currents from Earth's core outweighed that compositional density and made these materials move up from the solid mantle to Earth's surface.' This process is called 'mantle convection', when hot mantle material rises as colder material sinks. Earth's mantle is almost totally solid — yet, over long geologic periods, it acts like a pliable material which can mix and move things within it. Those include the HSEs — like gold — which came to Earth from massive collisions billions of years ago and then reached the planet's surface through these enormous, yet intricate internal processes. Is gold found on other planets as well? Korenaga says, 'Gold is found on the moon — but its abundance there is much lower than on Earth. It is found on Mars too. Of course, we don't have direct samples from Mars but we have so-called Martian meteorites. These are found on Earth but because of their isotopic features, they are traced back to Mars. Analysing these rocks shows us the presence of highly siderophile elements there — again though, the abundance of these, like gold and platinum, is much lower than on Earth.' Do siderophiles contain a larger story of the formation of our solar system — and universe? Korenaga comments, 'We understand planetary formation in terms of silicate rocks and iron which makes up most of the core. Iron is a major element while silicate rocks are made of silicon, oxygen, magnesium, iron, etc. Highly siderophile elements exist in very small abundances — their presence by itself doesn't drive any major planetary formation processes but they stick with iron and by measuring such trace elements, we can study more details of planetary formation.' These abundances thus help us decipher the paths planets once took. The Golden Moon: This too has gold on it THE GOLDEN MOON: This too has gold on it Given its incredible history — arriving on Earth 4.5 billion years ago, seeping deep into its mantle, pushed to the top by extraordinary forces operating from within our planet — how should we think of gold the next time we see it? Korenaga replies, 'Gold is, of course, widely available as jewellery and other items from shops but when we look at it, we should actually think about its extraordinary origins — we shouldn't take gold for granted. Its presence helps us understand crucial details of the very existence of this metallic Earth and the formation of its unique atmosphere which is 78% nitrogen and 21% oxygen — why did our planet develop in this way? A simple everyday item like gold can hold big answers to that.' Korenaga concludes by remarking, 'Of course, my work explains why Earth's mantle has some amount of gold or platinum at the surface level but for humans to access pure gold, you need a concentrated form in a mine,' He adds, with a scientist's exactness, 'It is extremely inefficient otherwise to extract gold from rocks — but to understand the formation of gold mines, you need deeper knowledge about very local processes. And that is another story.'
